\kalafifiwflall M@®flfi@@fl @are @fifilfizafifi©m am] Expemdfitwe Sfiwwey WI 33:5“ ncidence, Utilization, 239 and Costs Associated With ”it, Acute Respiratory Conditions United States, 1980 Series C, Analytical Report No. 4 III" Health Care Fi nnnnnn 9 Public Health Service Administration National Center for Office of R eeeeee h Health Statistics and Demonstrations I..- National Medical Care Utilization and Expendture Survey The National Medical Care Utilization and Expenditure Survey (NMCUES) is a unique source of detailed national estimates on the utilization of and expenditures for various types of medical care. NMCUES is designed to be directly responsive to the continuing need for statistical information on health care expenditures associated with health services utilization for the entire US. population. NMCUES will produce comparable estimates over time for evaluation of the impact of legislation and programs on health status, costs, utilization, and illness-related behavior in the medical care delivery system. In addition to national estimates for the civilian noninstitutionalized population, it will also provide separate estimates for the Medicaid-eligible populations in four States. The first cycle of NMCUES, which covers calendar year 1980, was designed and conducted as a collaborative effort between the National Center for Health Statistics, Public Health Service, and the Office of Research and Demonstra- tions, Health Care Financing Administration. Data were ob— tained from three survey components. The first was a national household survey and the second was a survey of Medicaid enrollees in four States (California, Michigan, Texas, and New York). Both of these components involved five interviews over a period of 15 months to obtain information on medical care utilization and expenditures and other health-related infor- mation. The third component was an administrative records survey that verified the eligibility status of respondents for the Medicare and Medicaid programs and supplemented the household data with claims data for the Medicare and Medicaid populations. Data collection was accomplished by Research Triangle Institute, Research Triangle Park, N.C., and its subcontrac- tors, the National Opinion Research Center of the University of Chicago, Ill., and SysteMetrics, Inc., Berkeley, Calif, under Contract No. 233—79—2032. Co—Project Officers for the Survey were Robert R. Fuchsberg of the National Center for Health Statistics (NCHS) and Allen Dobson of the Health Care Financing Administration (HCFA). Robert A. Wright of NCHS and Larry Corder of HCFA also had major responsibilities. Daniel G. Horvitz of Research Triangle Institute was the Project Director primar- ily responsible for data collection, along with Associate Project Directors Esther Fleishman of the National Opinion Research Center, Robert H. Thomton of Research Triangle Institute, and James S. Lubalin of SysteMetrics, Inc. Barbara Moser of Research Triangle Institute was the Project Director primar- ily responsible for data processing. For sale by the Superintendent of Documents, US. Government Printing Office Washington. DC. 20402 Incidence, Utilization, and Costs Associated With Acute Respiratory Conditions United States, 1980 Series C, Analytical Report No. 4 II"l Illl i US. DEPARTMENT OF HEALTH AND HUMAN SERVICES Published by Public Health Service National Center for Health Statistics September 1986 rufirmx .,. -.>»,,_ ., K ~_,~ , _._ ‘l‘impvp‘ny Copyright Information All material appearing in this report is in the public domain and may be reproduced or copied without permission; citation as to source, however, is appreciated. Suggested Citation Harlan, W. R., Murt, H. A., Thomas, J. W., et al.: Incidence, utilization, and costs associated with acute respiratory conditions, United States, 1980. National Medical Care Utilization and Expenditure Survey. Series C, Analytical Report No. 4. DHHS Pub. No. 86—20404. National Center for Health Statistics, Public Health Service. Washington. US. Government Printing Office, Sept. 1986. Library of Congress Cataloging-in-Publication Data Incidence, utilization, and costs associated with acute respiratory conditions. (Series C, Analytical report; no. 4) (DHHS publication ; no. (PHS) 86—20404 Written by: William R. Harlan and others. Bibliography: p. Supt. of Docs. no.2 HE22.26/424. 1. Respiratory organs—Diseases—United States—Statis- tics. 2. Medical care, Cost of—United States—Statistics. 3. Medical care—United States—Utilization—Statistics. 4. Health Surveys—United States. I. Harlan, William R., 1930— . II. National Center for Health Statistics (US) III. Series: National medical care utilization and expenditure survey. Series C, Analytical report ; no. 4. IV. Series: DHHS publication ; no. (PHS) 86—20404. [DNLM2 1. Respiratory Tract Infections—economics—United States. 2. Respiratory Tract lnfections—occurrence—United States. WF 140 I37] RA645.R4I53 1986 338.4’33621'962 86—600045 ISBN 0—8406—0339-X Contents Executive Summary ........................................................ 1 Introduction ............................................................. 3 Sources and Limitations of Data .................................................. 7 The National Medical Care Utilization and Expenditure Survey ............................... 7 Public Use Tapes ....................................................... 7 Limitations of the Data ..................................................... 7 Findings ............................................................... 10 Incidence ............................................................ 10 Disability ............................................................ 12 Indirect Costs ......................................................... 12 Ambulatory Visits and Treatment ............................................... 13 Hospital Admissions and Surgical Procedures ........................................ 14 Direct Costs .......................................................... 15 Discussion ............................................................. 19 References ............................................................. 22 List of Detailed Tables ....................................................... 23 Appendixes I. Sample Design, Data Collection, and Processing ....................................... 41 II. Data Modifications to Public Use Files ............................................ 47 Ill. Analytical Strategies ...................................................... 49 IV. Sampling Errors ........................................................ 55 V. Definition of Terms ....................................................... 61 List of Text Tables A. Incidence rate of acute respiratory conditions for all persons and persons with any health condition, by condition group: United States, 1980 ...................................................... 10 B. Percent distribution of persons by number of episodes of acute respiratory conditions, according to selected characteristics: United States, 1980 .............................................. 11 C. Mean days of condition-related disability for persons with acute respiratory conditions, by type of disability and condition group: United States, 1980 .................................................. 12 D. Estimated value of productivity lost as a result of morbidity for persons with acute respiratory conditions, by employment and condition group: United States, 1980 ........................................... 13 E. Mean ambulatory care visits for persons with acute respiratory conditions and percent distribution by reason for visit, according to condition group: United States, 1980 ...................................... 13 F. Percent of persons with acute respiratory conditions who had a hospital admission, by reason for admission and condition group: United States, 1980 ............................................. 14 G. Rate of condition-related surgical procedures for persons with acute respiratory conditions, rate of tonsillectomy and/or adenoidectomy procedures, and charges for procedures, by condition group and selected characteristics: United States, 1980 .............................................................. 15 H. Condition-related charges for persons with acute respiratory conditions and percent distribution by type of service, according to condition group: United States, 1980 ...................................... 16 J. Total charges for all persons and for persons with acute respiratory conditions and percent distribution by type of health service, according to condition group: United States, 1980 .................................. 16 K. Per capita condition-related charges for persons with acute respiratory conditions and percent of charges paid out of pocket, by type of health service and condition group: United States, 1980 ....................... 17 iii List of Figures 1. Incidence of colds, influenza, and lower respiratory conditions, by week: National Medical Care Utilization and Expenditure Survey, 1980 ................................................... 2. Incidence of nasopharyngitis and otitis media, by week: National Medical Care Utilization and Expenditure Survey, 1980 .......................................................... Symbols - — — Data not available Category not applicable - Quantity zero 0.0 Quantity more than zero but less than 0.05 T Sample size is less than 50 :t Sample size is less than 25 NOTE: Data estimates in tables may not add to totals because of rounding. Incidence, Utilization, and Costs Associated With Acute Respiratory Conditions By William Fl. Harlan, Hillary A. Murt, J. William Thomas, James M. Lepkowski, and Kenneth E. Guire, University of Michigan, P. Ellen Parsons, National Center for Health Statistics (formerly of the University of Michigan), and S. E. Berki and J. Richard Landis, University of Michigan Executive Summary Acute respiratory conditions are common causes of health disturbance in the general population. They are generally self-limiting, although occasionally recurrent, and seldomresult in large health care costs for each episode of illness. The National Medical Care Utilization and Expenditure Survey (NMCUES), conducted during 1980, provided an opportunity to assess the effect of acute respiratory conditions on utilization of medical services and on functional capability as well as the cost of related medical care. Acute respiratory conditions were reported by survey respondents and separated into five subgroups: colds, influenza, nasopharyngitis, otitis media, and lower respiratory infections. Allergic condi- tions and chronic respiratory disorders (tuberculosis, chronic obstructive pulmonary disease, and pneumo- conioses) were excluded. The subgroupings of acute respiratory conditions appear to separate the disorders in a manner consistent with the epidemiologic character- istics of each condition. About one-half (50.4 percent) of the U.S. civilian noninstitutionalized population had one or more acute respiratory conditions during 1980. The highest rates for upper respiratory conditions (colds, influenza, nasopharyngitis, and otitis media) were reported for those under 18 years of age, and rates were lower in succes- sively older groups. Lower respiratory infection rates were higher in the youngest and oldest groups. Despite a high incidence in the general population, most symptomatic episodes of colds, influenza, and nasopharyngitis did not result in ambulatory care visits or hospital admissions. Otitis media and lower respiratory infections were more often associated with medical visits. Acute respiratory conditions were associated with lower disability levels than the average for the U.S. civilian noninstitutionalized population during 1980 (5.9 restricted-activity days for acute respiratory conditions, compared with an overall average of 13 .8 restricted—activ- ity days). Persons with upper respiratory conditions (colds, influenza, otitis media, and nasopharyngitis) av- eraged 2.3 to 5.4 restricted—activity days, but persons with lower respiratory infections experienced an average of 8.2 restricted—activity days. Indirect costs attributed to acute respiratory conditions in 1980 were $7.7 billion for employed persons and $698 million for homemakers, for a total of $8.4 billion, about the same as total direct costs ($8.3 billion). These indirect costs were several times larger than the annual indirect costs esti- mated for either cardiovascular diseases or musculo- skeletal diseases, two common chronic or recurrent con- dition groups. The high indirect costs reflect the high frequency of episodes in the general population during 1980 and the greater likelihood of associated bed-disabil- ity and work-loss days than for other conditions. Despite the frequency of acute respiratory conditions, only a small proportion (15 percent) of the ambulatory visits made by people who had such episodes were specif— ically related to these conditions. Ambulatory visits for colds, influenza, and nasopharyngitis were infrequent, but lower respiratory infections and otitis media com— monly resulted in ambulatory visits. Medical attention specifically attributable to acute respiratory conditions was more common for younger age groups and less common for successively older age groups. However, ambulatory visits for all causes were greater for the older groups; therefore, acute respiratory conditions com- prised a lesser proportion of their total visits. Although women reported more episodes of acute respiratory con- ditions than men did, they less frequently sought medical care for these conditions. Acute respiratory conditions were infrequently reported as a cause for hospitalization. Lower respiratory infections were an exception and led to hospital care for 12 percent of persons reporting this condition. The most common surgical procedure reported by persons with acute respiratory conditions was tonsil- lectomy and/or adenoidectomy, and this procedure was almost exclusively performed on persons under 19 years of age. Total charges for acute respiratory conditions in 1980 amounted to $8.3 billion, or about 5 percent of the total charges for all health services to the U.S. civilian noninstitutionalized population. Charges for physician services and prescribed medications made up a greater proportion of charges for acute respiratory conditions than for all conditions in the general population. This reflects the predominance of ambulatory care for these conditions. Surgical procedures related to acute respira- tory conditions were performed relatively infrequently (5.0 per 1,000 population), and about one-half of these procedures were tonsillectomy and/or adenoidectomy (2.7 per 1,000 population). The total charges for relevant surgical procedures were $2.1 billion. Charges associated with lower respiratory infections comprised 42 percent of the total charges for all acute respiratory conditions. Per capita charges for acute respiratory conditions averaged $74 for those reporting one or more episodes, but the condition charges varied greatly, ranging from $20 for influenza to $408 for lower respiratory infections. Approximately 30 percent of per capita charges were paid out of pocket. Charges specifically related to upper respiratory conditions comprised a greater proportion of per capita charges for all care among young people (15 percent) than among persons 65 years of age and over (2 percent). Lower respiratory infections differed from this pattern, having the highest per capita charges and total charges and only a minimal age differential. Despite the low costs per person, acute respiratory diseases have considerable impact on total health costs because they are common and frequently result in bed disability and work loss. These disorders are responsible for a major proportion of health expenditures for children and young adults. From middle age through retirement, the proportion of health expenditures related to acute respiratory conditions declines, and chronic disorders assume greater economic and health importance. NOTES: The authors are grateful for the support received during all stages of the preparation of this document, both from colleagues at the University of Michigan and from the staff of the National Center for Health Statistics. At the University of Michigan, Sharon Stehouwer contributed greatly to initial analyses of the NMCUES data and to identification and correction of several problems encountered in the data base. Drs. Catherine McLaughlin, Richard Lichtenstein, and Leon Wyszewianski provided valuable conceptual help. Quality secretarial support in the preparation of the many tables included in the report came from Jan Feldman. Carolyn Parker. and Johanna Haaxma- Jurek. At the Institute for Social Research, University of Michigan. Nan Collier developed software for calculating sampling errors, and Judy Connors performed many of the analyses for generating sampling errors for national estimates, Continual support was received from the National Center for Health Statistics. The project officer, Dr. Mary Grace Kovar, Special Assistant for Data Policy and Analysis, was instrumental in providing focus to the project. The authors are indebted to Robert J, Casady, Chief of the Statistical Methods Staff, for writing the major section in Appendix l in which the NMCUES survey design and estimation methodology are described. When potential errors in the data were identified during our analyses, Roben Wright and Michelle Chyba quickly solved the problems. Editors in the Publications Branch pro- vided valuable assistance during all stages ofthe report, especially preparation ofthc detailed tables. Introduction Acute respiratory conditions are common causes of visits for health services and are often associated with work-loss and disability days. The economic importance of these medical problems is generally underestimated because they are an accepted part of life. they are usually self-limiting and of short duration, and the unit costs for care, whether self administered or medically dis- pensed, are relatively small. However, in the aggregate. this group of diseases represents an important and sizable cause of morbidity and results in considerable economic loss. The impact of these diseases has been difficult to document because of variable patterns of seeking care. paucity of residual morbidity, and the orientation of most economic studies toward the high-cost aspects of medical care. such as hospitalization and surgery. Lack of information has also obscured potential age, race, and sex differences in care—seeking patterns and expenditures. which remain poorly defined within the general population. Data regarding the incidence of and service utilization patterns for respiratory conditions could have implications for setting prevention and treat— ment priorities and for health care financing. The Na- tional Medical Care Utilization and Expenditure Survey (NMCUES) of 1980 provides a unique opportunity to quantify the health and economic impact of acute respira- tory conditions. The impact of acute, primarily infectious, respiratory conditions on health service utilization and economic costs is examined in this report. Chronic respiratory diseases (e.g., chronic obstructive pulmonary disease, pneumoconioses, and tuberculosis) and allergic diseases (e.g., bronchial asthma) have health implications and service patterns that differ considerably from those of acute conditions and are not analyzed in this report. Acute respiratory conditions are usually grouped into a single category in health service utilization studies, but this may obscure important differences among disease subgroups with respect to care patterns and cost. No validated standardized criteria exist for separating these conditions by etiologic agent or symptom complex. Therefore, physician and patient discrimination of dis- ease entities based on symptomatology has been consid- ered imprecise, and the differences among conditions in morbidity and costs have been thought to be too trivial to justify more discrete differentiation. However, preventive medical and cost-containment strategies might differ among the entities, and data specific to diseases would be useful. In this report, the costs of care for the general category of acute respiratory conditions are compared with other health costs, and this broad category is differentiated into five symptomatic subgroups: colds, nasopharyngitis, influenza, otitis media, and lower res- piratory infections. The incidence, disability, service utilization, and direct and indirect costs for each subgroup are compared. Acute respiratory conditions and the subgroups were defined using modified codes of the Ninth Revision of the International Classification of Diseases (World Health Organization, 1977). Acute respiratory conditions ( general category)— This includes all of the specific subgroups listed below. A person may have reported more than one of the diag— noses listed below. Specific exclusions are tuberculosis, International Classification of Diseases (ICD) code 901 1; chronic obstructive pulmonary disease. 492, 496; chronic bronchitis, 491; bronchial asthma, 493; allergic rhinitis, 477; and pneumoconioses related to external agents, 500— 505. . Colds and nonspecific upper respiratory conditions— This is the subgroup of diagnoses coded as ICD numbers 079, 460—465, 475, 478.2, and 478.6. 0 Nasopharyngitis—This subgroup comprises diag— noses coded as ICD numbers 472, 473, 474, and 475. The category of chronic nasopharyngitis, 472, was included, because it was interpreted as recurrent or prolonged acute infection of the upper respiratory passages. This diagnosis, reported mostly in younger persons and in those having tonsillectomy and/or adenoidectomy, was felt to be closely related to acute infectious processes. 0 Influenza—This is reported as ICD code 487. The success in differentiating this condition from colds and other nonspecific respiratory symptom com- plexes is documented below. 0 Otitis media and related complications—This sub- group comprises ICD codes 381—386. 0 Lower respiratory infections—Included in this cate- gory are ICD codes 466, 480-486, 490. and 510— 515. Chronic infectious processes are specifically excluded. The diagnoses in the NMCUES data file were provided by the survey respondents, recorded by the interviewer, and reduced to numeric codes by trained coders. Respond- ent-provided diagnoses could represent self-diagnosis (if the condition was not attended by a health provider) or the diagnosis reported by a health provider and subsequently interpreted by the respondent, interview- er, and coder. To clarify the imprecision attending this course of reporting and to determine whether the general category could be separated into subgroups, the five subgroups were examined by various features known to characterize the disease entities. The acute respiratory subgroups have different sea- sonal variations. Seasonal incidence rates for each acute respiratory subgroup as reported by NMCUES respon- dents are plotted in Figures 1 and 2. According to NMCUES data, the occurrence of influenza during 1980 peaked in January and February, with a secondary peak in December. Influenza incidence was also monitored by the Centers for Disease Control (CDC). Calendar year 1980 comprises the latter half of CDC’S 1980 res- piratory disease reporting period and the first half of the 1981 period. The pattern of influenza found in NMCUES corresponds with culture-confirmed peak periods reported by CDC. A significant number of excess deaths (43,800) were attributed to pneumonia and in- fluenza during the first 16 weeks of 1980, January to April (Centers for Disease Control, 1984), and this level exceeded the epidemic threshold. The epidemic threshold was also exceeded for a 13-week period beginning December 13, 1980, but only 2 weeks of this period (weeks 51 and 52) are included in NMCUES. The trough during weeks 1640 (late April through September) are also in line with CDC-reported influenza incidence. The seasonal pattern for colds was quite different, particularly for weeks 12—46 (March through November), although this diagnostic category, like influenza, had a peak in weeks 1—8 (January and February). Nasopharyngitis had a different seasonal pattern from those of influenza and colds, with high levels in week 1, a peak in weeks 4—16, and a secondary increase in weeks 40—51. Otitis media reported in NMCUES had little seasonal variation, although it was somewhat higher in weeks 5—9. Lower respiratory infections (Figure 1) had higher rates during periods corresponding to higher influenza rates but also had high rates from March through May and no trough during the summer. The correspondence between peaks of influenza and pneumonia is well recognized and is assumed to reflect secondary bacterial complication in persons experiencing influenza infection. Seasonal incidence patterns are evi— dence that these acute respiratory disease subgroups were differentiated along patterns corresponding with the known behavior ofthe diseases. An additional check on the accuracy of reported diagnoses is the distribution of demographic characteris- tics of those reporting disease. The age, sex, and race distributions for these diseases, included in Table 1, are similar to those reported for acute respiratory condi- tions (Gwaltney, 1985). Otitis media is characteristically a disease of children (birth to 12 years of age), with no striking sex or racial differences; this is concordant with the data from NMCUES. Lower respiratory infec- tions are more common in children and older adults, and this was found in NMCUES. Influenza affects both adults and children, but colds are more common in children. Nasopharyngitis is a category that combines several codes for infections of the pharynx and nasal and sinus areas. Although all of these infections are assumed to be acute and self-limiting or recurrent acute diseases, a significant portion were coded under the rubric “chronic nasopharyngitis.“ When the characteristics of persons assigned this code were compared with those of persons having acute diagnoses within the category, no significant differences were found. Thus, it is assumed that the “chronic nasopharyngitis” codes represent either recur- rent acute manifestations of infectious disease or continu- ing manifestations of an acute episode, as commonly occurs with sinusitis. No direct evidence can be provided to verify this assumption. However, to avoid excluding the large number of persons with this code, their records were merged with others that have diagnoses involving the same anatomical area. Despite these internal and external validations of the ability to specify diagnostic subgroups within the general category of acute respiratory conditions, one should keep in mind that the diagnoses are reported by household informants. Some imprecision in specifica- tion should be expected because standard diagnostic criteria were not applied by the physician or by the survey respondent. 140- Condition group O Colds D Influenza 120- A Lower respiratory conditions / I —-—-—-" 100 ~ R1 O O f, ' o \ “g’ o g» 80- (A . l 3 o ' l a ‘ . I :3 ° ' \ ° C g . - , lfi\ E 0 °. ' . \ Z 0 .. . o . .I \ 40-fi . . . \ ' 0 Ce D A / AA M Ella A“ ‘° 20- . A Afi \ A AA AA \ \‘A 0 r fi 1 r l I I I 1 T l T l 4 8 1 2 16 20 24 28 32 36 4O 44 48 52 Week Figure 1 Incidence of colds, influenza, and lower respiratory conditions, by week: National Medical Care Utilization and Expenditure Survey, 1980 l 40 44 l l l 28 32 36 I r l 16 20 24 60 50 ~ 40 52 Figure of nasopharyngitis and otitis meda, by week: National Medical Care Utiization and Expenditure Survey, 1980 Incidence Sources and Limitations of Data The National Medical Care Utilization and Expenditure Survey Data for this study come from the public use files of the National Medical Care Utilization and Expenditure Survey (NMCUES), a national household survey con- ducted from early 1980 through early 1981. Specific details concerning the sample design and data collection are outlined in Appendix I. From February 1980 through April 1981, data on 17,123 persons in 6,798 families were collected at ap- proximately 3—month intervals. A total of five interviews, two personal interviews followed by two telephone inter- views and a final personal interview. were conducted. At the conclusion of the first interview, survey partici- pants were provided with a specially designed calendar diary for recording data about medical events and costs in preparation for subsequent rounds of interviewing. Prior to each interview but the first, respondents were sent a summary sheet showing all medical events and costs reported in previous interviews. Public Use Tapes NMCUES public use tapes consist of six files: the person, medical visit, dental visit, hospital stay, pre- scribed medicines and other medical expenses, and condi- tion files. The person file has one record for each of the 17,123 responding eligible persons with data describ- ing the person’s demographic characteristics, health care coverage, employment, income, and usual source of care; numbers of visits, hospital admissions, and other medical events reported for 1980; total charges for each category of care; and limitations and disabilities, includ— ing identification of conditions. Data from the other five files, which have more detailed information about events summarized in the person file, can be linked to records in the person file through a unique identifica- tion number assigned to each person. The medical visit file contains one record for every visit reported by people in the person file. A total of 86,594 visits are in the file, which includes visits to providers’ offices, hospital outpatient departments, and emergency rooms. Each record contains the identifying number of the person making the visit, the place of visit, type of physician or nonphysician seen, type of services provided, conditions causing or associated with the Visit, procedures performed during the visit, as- sociated charges, and sources of payment. Similar data on dental visits and hospital admissions are provided in the dental visit and hospital stay files, respectively. The prescribed medicines and other medical expenses file contains one record for each purchase of prescribed medications or other medical expense incurred by survey participants during 1980. Data include the identifying number of the person for whom the purchase was made, date of purchase, prescribed medicine codes, codes for conditions leading to the purchase or other expense, and associated charges and sources of payment. If a medical condition caused any limitation in a person’s activities (e.g., staying in bed, staying home from work) or caused the person to seek medical care, then a condition record appears in the condition file. For each condition, the condition file record contains the identifying number of the person, codes from the International Classification of Diseases (World Health Organization, 1977), dates of onset of illness, counts of visit types, prescribed medicines and other medical expenses, associated charges, and, if applicable, the reasons for not seeing a physician. Modifications to the public use files that were made by the University of Michigan in the course of this analysis are presented in Appendix II. Analytical strategies appropriate for NMCUES are presented in Appendix III. Sampling errors for estimators used throughout this report can be estimated using procedures outlined in Appendix IV. Definitions of terms used in this report are listed in Appendix V. Limitations of the Data Estimates of incidence—In NMCUES, a particular medical condition was noted only when it caused some type of disability or resulted in an ambulatory visit, hospital admission, purchase of a prescribed medication, or other encounter with the health care system. Hence, conditions that usually require treatment or which cause some sort of disability will be better reported. In the context of respiratory conditions, mildly symptomatic colds are less likely to be reported than lower respiratory diseases, which are often associated with significant mor- bidity and physician consultation. The diagnostic accuracy of reported problems de— pends on both information that the respondent obtained from the health care provider and the respondent’s ability to convey this information accurately to the interviewer. In the absence of medical care, the respondent's previous experience or education may affect the diagnostic accu- racy of reporting. In cases where the condition resulted in limitation of activity but was never medically attended, the diagnostic accuracy of the condition may be suspect, particularly for new conditions. The diagnostic specific- ity of subgroups of acute respiratory conditions, de- scribed in the Introduction, is particularly sensitive to this issue. Estimates of disability—Obtaining detailed informa- tion about the number of disability days associated with each medical condition is complicated by the manner in which the public use files were constructed. For each condition group discussed in this report, the number of associated disability days (restricted-activity days, bed-disability days, and work—loss days) is of interest. Respondents could list more than one underlying condi- tion for a disability day. It is possible to compute the number of disability days listed for each condition in the condition file, but duplication exists for days reported as caused by two or more conditions. Also, the structure of the public use files does not permit linkage of a specific disability day with all the associated illnesses. The person file contains an unduplicated count of disabil- ity days for each respondent, but no information on conditions causing disability. This problem is particularly important with regard to respiratory conditions because they are so common and frequently aggravate or compli- cate other medical problems, particularly coexistent chronic diseases. Therefore, a procedure was devised that would allow estimation of condition-related disabil- ity days for persons reporting more than one condition. Estimation of disability days attributable to a given condition was accomplished by a two-step process. First, for each person, the ratio of the number of disability days in the person file (an unduplicated count) to the total number of disability days in the condition file (a duplicated count) was computed. Second, this ratio was multiplied by the number of disability days listed in the condition file for each medical condition. The result is an estimate of disability days attributable to each condition. The major criticism of this method is that it uniformly reduces the proportion of duplicated days for all conditions. Therefore, variability in actual illness behavior across medical conditions is minimized. Utilization of health services—For each medical en- counter recorded in the survey, respondents could report up to four medical conditions. The public use files show that approximately 10 percent of medical visits have two conditions recorded; multiple conditions are listed for about 12 percent of all hospital stays; and 4 percent of the prescribed medication records have two conditions recorded. On one hand, listing multiple conditions on the event record permits analysis of patterns of care-seeking 8 behavior associated with different illnesses. Such data can reveal, for example, whether certain illnesses are generally treated by themselves or are treated along with other conditions during a medical visit or hospitalization. On the other hand, the NMCUES survey instrument does not designate “principal diagnosis" or primary reason for each medical encounter. Therefore, when mul- tiple conditions are reported, it is difficult to attribute health service use to a specific diagnosis. For this report, a condition-related medical service is defined as one for which the respondent identified an acute respiratory condition as the only or as one of several reasons for seeking medical care. Services that are not condition related are defined as those for which none of the acute respiratory conditions was listed. Cost of health services—The NMCUES data contain a number of improbably low values of total charges for ambulatory visits, prescribed medications, and hospi- tal stays. In many cases, the reported data may not correspond with total charges for the service received but instead represent out-of-pocket expenses incurred by patients. To the extent that some respondents reported out-of—pocket expenses as total charges for services, esti- mates oftotal charges are biased downward. As noted above, people are often treated for more than one condition when they seek medical care. As a result, it is difficult to isolate those charges that are specific to a given illness. Thus, for these analyses, condition-related charges are defined as charges for health services for which acute respiratory conditions were listed as the only or as one of several reasons for seeking care. Because these charges may also reflect the treatment of other conditions, they may overestimate the economic impact of acute respiratory conditions, both for the population as a whole and for individuals suffering from these conditions. Indirect costs—The indirect cost of illness and injury is the loss of resources resulting from them. Resource loss is generally calculated as lost productive capacity: the loss of potential economic output because of morbid- ity and mortality. Indirect costs are usually estimated on the basis of the amount of time by which the indi- vidual's productivity is diminished or lost and the mone- tary value of that lost productive time. In calculating the indirect costs of morbidity for 1980, the first necessary calculation is the number of years of productive activity lost by individuals with ill- ness or injury. This measure deals with lost productivity, so the convention is to count only persons 17 years of age and over who were either working or keeping house at the time of their illness or who were unable to engage in these activities because of illness or injury. However, persons who were unable to work for health reasons for the entire year are excluded from calculations in this report because in NMCUES no condition was associated with such long-term disability. Individuals who were not in the work force for other reasons, e. g., students or retirees, are also not part of the population “at risk” in these calculations. The unit for calculation of lost productive time is productive person years. Productive years lost, a non— monetary measure of morbidity costs, is defined as the number of productive days lost because of illness in a year divided by the number of productive days in a year. For this report, lost productive time is calculated for all employed persons and homemakers. Persons who were employed at any time in 1980 were classified as employed in the NMCUES data files. Homemakers are defined as persons who were not employed or disabled in 1980 and who claimed “keeping house" as their pri- mary activity in 1979. For employed persons, reported work-loss days are divided by 245, the average number of workdays in a year, to determine productive time lost. In this study, calculations of lost output for home- makers were performed for both bed-disability days and restricted-activity days because the former underesti- mates lost productivity and the latter overestimates lost productivity. The appropriate denominator to analyze days lost for either of these calculations is 365 because homemakers can perform their work every day of the year. By performing both sets of calculations, a range of lost productivity with upper and lower bounds can be constructed for homemakers. Estimates in this report are given for the more restrictive unit of measure, bed- disability days, and for restricted-activity days, which yield somewhat higher estimates of lost productivity. Measures of lost productive time for employed individ- uals and homemakers have been weighted and aggregated to produce national estimates of productive person years for these two population groups. Estimates of the indirect costs of morbidity are calcu- lated by multiplying an individual's reported work-loss time by his or her reported earnings, when available. Reported earnings do not include employee benefits, so earnings are adjusted by a factor of 1.172 to account for the additional value represented by fringe benefits. The adjustment factor is based on the mean percent of earnings represented by employee benefits (17.2 per— cent) in 1980 (Survey of Current Business, 1981). Lost earnings for employed persons whose earnings were not reported are estimated using US. Department of Labor 1980 data for mean annual earnings and are specific to the individual‘s age, sex, race, and employment status (full or part time). Again, figures are adjusted to include the value of employee benefits. Lost productivity for homemakers, whose labor is not reimbursed, is estimated using the market—value approach. The value of lost home- maker services is approximated by estimating the cost of replacing those services with services purchased in the market. The values employed are derived from time- use studies and relevant wage rates (Hodgson and Rice, 1984; Walker and Gauger. 1973). Details of the estima- tion procedures, including tables of values used to esti- mate these costs, are presented in “The costs of illness, United States, 1980,” Appendix V (Parsons et a1., 1986). Findings Incidence Over one-half of the US. civilian nonin— stitutionalized population (504 per 1,000 persons, or 112.3 million persons) had one or more episodes of acute respiratory disease during 1980 (Table A). Colds (259 per 1,000) and influenza (260 per 1,000) were the most frequently reported conditions. Acute lower respiratory infections were least frequently reported in the survey (39 per 1,000) and were reported approxi- mately one-sixth as frequently as either colds or in— fluenza. When the population is limited to those who reported any condition during 1980, the rates are slightly but consistently higher for all respiratory conditions and for each specific respiratory subgroup. One or more acute respiratory conditions were reported by 589 per 1,000 persons reporting any condition and 504 per 1,000 persons in the general population. The higher incidence rate in those reporting any other health-related condition indicates that there is a slightly greater rate of respiratory conditions among persons who report other medical conditions. These findings represent estimates of only severe or troublesome episodes of acute respiratory conditions. Only episodes resulting in a medical visit or disability were reported by respondents. Moreover, respondents reported conditions occurring in the last 3 months, mak- Table A Incidence rate of acute respiratory conditions for all persons and persons with any health condition, by condition group: United States, 1980 Estimated Persons population with any in All health Condition group thousands persons condition Rate per 1,000 population 112,302 504.0 588.8 Persons with acute respiratory conditions . . . Colds ................ 57,638 258.7 302.2 Nasopharyngitis ........... 16,150 72.5 84.7 Influenza .............. 57,866 259.7 303.4 Otisis media ............ 11,424 51.3 59.9 Lower respiratory infections ............. 8,592 38.6 45.1 NOTE: An estimated 222,824,000 persons were in the civilian nonistitutionalized population in 1980. 10 ing it less likely that a brief episode or mildly symptoma- tic illness would be recalled. NMCUES rates do not necessarily agree with those from the National Household Interview Survey (NHIS), in which information is ob— tained on all symptomatic episodes, regardless of morbid— ity, and which has a shorter recall period. NHIS data indicate 253,175,000 incidents of acute respiratory con- ditions in 1980, and 52.3 percent of respondents reported one or more episodes during 1980 (Jack, 1981). NMCUES and NHIS estimates of rates are similar, but NMCUES estimates of persons affected are lower, proba- bly because a higher threshold for reporting is used. Underreporting may differ among the specific sub- groups within this broad category because of different levels of disability. Lower respiratory conditions are generally associated with more prominent symptomatol- ogy and disability and are more likely to result in utiliza- tion of health services. Therefore, lower respiratory con- ditions would be less likely to be underreported than colds, which can be mild and not result in disability or work loss. The condition subgroups within the res— piratory condition category are not mutually exclusive, so the same surveyed individual might report episodes in more than one disease group or multiple episodes of one category but would be counted only once in a person-specific analysis. Although acute respiratory conditions are usually self—limiting and resolve with little or no residual morbid- ity, some individuals may have multiple episodes. About 29 percent of the population had one episode, and 21.6 percent had two or more episodes during the calendar year (Table B). Children under 12 years of age had the most recurrent episodes. with 9.6 percent having four or more episodes during the year, compared with 3.2 percent of the total population (Table l). The propor- tion of persons experiencing one or more episodes de- creased with age. Of children under 12 years of age, 68.1 percent had one or more episodes, and 9.6 percent had four or more. Of people 65 years of age and over, 32.6 percent reported one or more episodes, and less than 1 percent had four or more episodes. Females re- ported significantly more multiple occurrences of res- piratory disease than did males, but there was no signifi- cant gender difference in single occurrences. More single and multiple occurrences were reported by white and other persons than by black persons. Table B Percent distribution of persons by number of episodes of acute respiratory conditions, according to selected characteristics: United States, 1980 Number of episodes 4 Characteristic Total None 1 2 3 or more Percent All persons ............... 100.0 49.6 28.7 13.1 5.3 3.2 Age Under 12 years ................ 100.0 32.0 29.0 19.3 10.2 9.6 12—18 years ................. 100.0 48.2 29.9 14.0 5.8 2.1 19—44 years ................. 100.0 49.8 30.3 12.9 4.7 2.2 45—64 years ................. 100.0 57.5 27.9 10.3 3.2 1.1 65 years and over .............. 100.0 67.4 22.5 7.1 2.3 07 Sex Male ...................... 100.0 53.0 27.5 12.1 4.7 2.7 Female .................... 100.0 46.5 29.9 14.1 5.9 3.7 Race Black ..................... 100.0 60.6 26.2 8.9 3.0 1.1 White and other ................ 100.0 48.1 29.1 13.7 5.6 3 5 Perceived health status Excellent ................... 100.0 49.9 28.8 12.7 5.1 3.5 Good ..................... 100.0 48.4 28.9 13.9 5.9 3.0 Fair ...................... 100.0 49.9 28.3 13.6 5.3 2.9 Poor ...................... 100.0 56.8 26.6 10.4 3.0 3.2 It is not clear whether age, sex, and race differences represent true differences in incidence or. alternatively. variability in recall or perceived morbidity. The age gradient of decreased episodes. either single or multiple. supports the idea of decreased incidence with increasing age rather than possible differential reporting by those in school. the work force. or retirement. The male—female differences are small but consistent. The differences by race are also consistent. However. the possibility that differences in reporting or in perceived severity of illness consistently bias the results cannot be excluded. The perceived health status of persons was not related to the occurrence of single or multiple episodes of acute respiratory conditions, and persons rating their health as “poor” tended to report fewer respiratory episodes (Table B). A person’s subjective assessment of health status is generally determined by the presence of chronic or debilitating diseases. Acute respiratory conditions either occur no more frequently than chronic conditions or are given relatively little attention compared with coexisting chronic conditions. Therefore, persons rating their health status as “poor” may not feel that acute respiratory conditions merit reporting. The distributions by age, sex. race, education, and family income of persons reporting the specific condi- tions comprising acute respiratory diseases are given in Table l. Colds. nasopharyngitis, influenza. and otitis media were more commonly reported in children (under 12 years of age) and in younger adults (12—44 years of age) than in older adults. The inverse relationship of these rates to age was consistent and significant. The rates for influenza were relatively high throughout childhood and the middle adult ages, with the lowest rates being found in those 65 years of age and over. Otitis media, including complications, was predomi- nantly reported for children. Lower respiratory infections were more common at the two ends of the age range, in those under [2 years of age and 65 years of age and over. The lower rates of acute respiratory conditions for people 65 years of age and over may reflect several factors: differential reporting, decreased exposure to in- fectious agents from lessened social and work interac- tions, and effect of immunization programs, or natural development of relative immunity over a lifetime of exposure. Whatever the explanation, rates for acute res- piratory conditions exclusive of lower respiratory disease were relatively low in the elderly population even during a year ofhigh influenza rates. Females reported higher rates of disease for every acute respiratory condition except otitis media, which had similar rates for males and females. White and other persons reported higher rates for all acute respiratory conditions than did black persons, with the most striking differences being found for influenza, otitis media, and lower respiratory disease. There was a positive relation— ship between rates of reported disease and education for every condition except lower respiratory disease, 11 for which no difference was found. There was no evident pattern by income for lower respiratory conditions, but the lowest rates were found for those at the highest income level ($35,000 or more). In other condition groups, the rates generally were directly related to in- come, with the lowest rates being reported in the lowest family income group (less than $10,000) and the highest rates in the higher family income groups ($20,000- $34,999 or $35,000 and more). Demographic differences in rates could represent differential reporting because of varying perceptions of acute illness and different finan— cial ability to pay for health care. These incidence data correspond with demographic patterns of respiratory conditions found in NHIS data. (As explained earlier, NMCUES estimates are expected to be somewhat lower than those from NHIS.) According to both NHIS and NMCUES data, rates for acute upper respiratory conditions are highest in youth and decline with age. For lower respiratory infections, there is no consistent age gradient, and the highest rates are in the young and in the old. Females, white and other persons, and persons with more education and higher incomes have higher rates of acute respiratory conditions. Disability Acute respiratory conditions were associated with means of 5.9 restricted-activity days, 3.2 bed-disability days, and 2.1 work-loss days (Table C). Colds, nasopharyngitis, and otitis media resulted in the fewest days of disability. Influenza was associated with sig— nificantly more disability than other upper respiratory conditions. Lower respiratory infections accounted for the greatest mean number of restricted-activity, bed-disa- bility, and work-loss days. The civilian noninstitutionalized population had 13.8 restricted-activity days, 5.3 bed-disability days, and 5.8 work-loss days per capita (Parsons et al., 1986). There- Table C Mean days of condition-related disability for persons with acute respiratory conditions, by type of disability and condition group: United States, 1980 Type of disability Restricted Bed Work Condition group activity disability loss Mean days Total ......... 5.9 3.2 2.1 Colds ............ 3.7 1.7 1.1 Nasopharyngitis ....... 2.3 1.2 0.8 Influenza .......... 5.4 3.2 2.2 Otitis media ......... 3.4 1.3 0.6 Lower respiratory infections ......... 8.2 4.7 2.9 12 fore, in each disability category, the mean level of disa- bility attributed to acute respiratory conditions was less than that reported for all conditions in the general popula- tion. Lower respiratory infections were associated with two to four times as many restricted-activity and bed-dis— ability days as were colds, nasopharyngitis, or otitis media. The bed—disability and work—loss days associated with influenza were at least twice as great as those for other upper respiratory conditions, but 1980 was characterized as an influenza epidemic year. Indirect Costs Indirect medical costs represent the loss to society of productivity foregone because of illness. These costs were considerable for acute respiratory conditions (Ta— ble D). For the total category of acute respiratory condi- tions, $8.4 billion was calculated as the indirect cost when bed-disability days were used as the measure of lost productivity for homemakers in the estimates, and $9.1 billion was estimated when restricted-activity days were used. Employed persons incurred $7.7 billion in indirect costs; homemakers incurred $698 million and $1 .4 billion when bed-disability days and restriced-activ- ity days, respectively, were used in the calculation. Among the specific subgroups, influenza had the greatest associated indirect costs for employed persons and for homemakers when restricted-activity days were used as the measure. Somewhat lower, but nevertheless important in relation to other disorders, were the indirect costs associated with colds. Indirect costs from colds were approximately one-half of those attributed to in- fluenza, although the incidence of the two disorders in 1980 was similar (Table A). However, the indirect costs attributed to colds were several times greater than those for the other specific acute respiratory conditions. Otitis media was associated with the lowest attributable indirect costs. This disorder affects primarily younger persons, who are not in the work force, so one would not expect an appreciable indirect cost impact. On the other hand, these calculations do not capture the indirect costs to the responsible adult who must provide depend- ent care during the illness of a child. The estimates in Table D are not discrete for each of the subgroups, as persons might have had more than one respiratory condition or multiple episodes of conditions. The data files in NMCUES do not permit separation of these costs by specific episodes. The indirect costs associated with acute respiratory conditions were considerably greater than those calcu- lated for hypertension and cardiovascular diseases (Harlan et al., to be published) or for musculoskeletal conditions (Murt et al., 1986). The contrast with car- diovascular diseases is especially striking. The indirect costs of illness attributed to acute respiratory conditions were approximately fourfold to fivefold greater than those for cardiovascular conditions. The differences for mus- TableD Estimated value of productivity lost as a result of morbidity for persons with acute respiratory conditions, by employment and condition group: United States, 1980 Total Homemakers Bed Restricted Bed Restricted Condition group disability‘ activity2 Employed disability‘ activity2 Persons with acute Amount in millions respiratory conditions ........ $8,355 $9,068 $7,657 $698 $1,412 Colds ..................... 2,309 2.533 2,1 77 1 33 356 Nasopharyngitis ................ 366 407 341 24 65 Influenza ................... 4,786 5,135 4,341 45 794 Otitis media .................. 135 143 119 16 24 Lower respiratory infections ......... 772 867 688 84 180 'Caicuiated using bed-disability days as measure 01 lost productivity for homemakers. zcalculated using restricted-activity days as measure of lost productivity for homemakers. NOTE: “Employed" refers to persons employed at any time in 1980; “homemakers” refers to persons who did not work for all of 1980 but were not disabled and claimed homemaking as their major activity in 1979. Table E Mean ambulatory care visits for persons with acute respiratory conditions and percent distribution by reason for visit, according to condition group: United States, 1980 Reason for visit Indexed condition Indexed and All condition unrelated Unrelated Condition group visits only morbidity morbidity on'y Persons with acute Mean visits respiratory conditions ............ 5.9 0.9 0.1 4.9 Colds ......................... 5.9 0.6 0.1 5.2 Nasopharyngitis .................... 7.3 0.6 0.2 6.5 Influenza ....................... 5.7 0.4 0.0 5.3 Otitis media ...................... 7.4 1.6 0.4 5.3 Lower respiratory infections ............. 8.7 1.3 0.4 7.0 Persons with acute Percent distribution respiratory conditions ............ 100.0 15.0 1.7 83.3 Colds ......................... 100.0 10.4 1.6 88.0 Nasopharyngitis .................... 100.0 8.4 2.1 89.5 Influenza ....................... 100.0 6.3 0.8 92.9 Otitis media ...................... 100.0 22.1 5.7 72.3 Lower respiratory infections ............. 100.0 15.2 4.1 80.6 NOTE: An estimated 5.2 mean ambulatory care visits were made by the total civilian noninstitutionalized population. culoskelctal disorders were less marked; nevertheless, respiratory conditions had 1—1/2 to 3 times greater indirect costs. The considerably greater indirect costs for acute respiratory conditions than for two common categories of chronic disease may be attributable to the greater incidence of respiratory conditions and their propensity to result in work—loss, bed-disability, or restricted-activ— ity days. In contrast, cardiovascular and musculoskeletal conditions may result in chronic functional limitation or elimination from the work force but less work absence or bed disability. Ambulatory Visits and Treatment Ambulatory visits by the US. population for acute respiratory conditions are shown in Table E. An esti- mated 112.3 million persons had one or more episodes of acute respiratory conditions (Table A). These persons averaged 5.9 visits to health care providers, but only a fraction (0.9) of a visit was specifically attributable to acute respiratory conditions (15 percent), and 0.1 of a visit (1.7 percent) was for a respiratory condition plus another unrelated condition. The majority of 13 ambulatory visits made by persons reporting a respiratory condition (4.9 visits) were for unrelated morbidity. Al- though acute respiratory conditions were common in the general population and were frequently responsible for disability days and relatively great indirect costs, they were not commonly the main reason for an ambula- tory visit. This pattern of infrequent visits for the indexed condi- tion was found for colds, nasopharyngitis, and influenza. A greater proportion of visits for otitis media and lower respiratory infections (22.1 percent and 15.2 percent, respectively) were made for the indexed condition only. Otitis media and lower respiratory infections may have considerable morbidity and often require prescribed medications, especially antibiotics. A greater proportion of ambulatory visits were for treatment of these condi- tions alone or in conjunction with a related condition. Although ambulatory care visits include visits to non- physician providers such as chiropractors and podiatrists, it is assumed that most visits specifically attributable to acute respiratory conditions were made to physicians or to nonphysicians working under a physician’s supervision. The distributions of ambulatory visits by age, sex, and race are given for each condition in Tables 2—6. For all subgroups reporting one or more upper respiratory conditions, total visits increased for successively older groups, but the number of visits specifically attributed to acute respiratory conditions were lower for older adults. Therefore, younger persons had a greater propor- tion of ambulatory visits for the indexed respiratory con- dition, and older people made a greater proportion of visits for problems unrelated to acute respiratory conditions. Hospital Admissions and Surgical Procedures Acute respiratory conditions infrequently require hospital admissions for treatment, but they may lead to hospitalization by complicating a chronic disease or by causing development of permanent structural changes from persistent or recurrent infections. For persons re- porting acute respiratory conditions, Table F shows rates of hospital admissions specifically attributable to acute respiratory conditions (indexed condition) and attributa- ble to unrelated conditions. Less than 3 percent of persons reporting upper respiratory conditions required hospitali- zation specifically for the condition. Hospital admissions were more frequently for an unrelated condition, and 10.4 percent reported such an admission. Persons report- ing lower respiratory infections represent a different sub- group. These individuals were at least six times as likely to be hospitalized for the condition as people reporting upper respiratory conditions were. They were also sig- 14 Table F Percent of persons with acute respiratory conditions who had a hospital admission, by reason for admission and condition group: United States, 1980 Reason for admission All Indexed Unrelated admissions condition condition Condition group All acute Percent respiratory conditions . 12.5 2.1 10.4 Colds .............. 11.9 1.1 10.8 Nasopharyngitis ......... 15.5 2.7 12.8 Influenza ............ 11.0 0.5 10.5 Otitis media ........... 12.7 1.8 10.9 Lower respiratory infections . . 29.6 12.2 17.4 nificantly more likely to be hospitalized for an unrelated condition. These findings indicate the severity of lower respiratory infections and suggest that they occur more frequently in persons with other serious conditions requir- ing hospitalization. The rate for surgical procedures related to acute res— piratory conditions was 5 per 1,000 population (Ta- ble G), and more than one-half of the relevant procedures were tonsillectomy and/or adenoidectomy (2.7 per 1,000). (Thoracotomy was specifically excluded from these analyses.) The rates for all respiratory surgical procedures, and specifically for tonsillectomy and/or adenoidectomy, were highest when nasopharyngitis (31.5 per 1,000) or otitis media (17.9 per 1,000) was the associated acute disease. Surgical procedures were least frequently reported in association with influenza (5.7 per 1,000). Tonsillectomy and/or adenoidectomy represented 78.7 percent of surgical procedures for nasopharyngitis and 62.6 percent for otitis media. These proportions are slightly greater than the proportion for all persons with or without respiratory conditions (54.0 percent). The rates for all surgical procedures were highest in those under 18 years of age, and tonsillectomy and/or adenoidectomy accounted for the preponderance of pro- cedures. Rates for related surgical procedures were low- est in those 45—64 years of age and rose again among persons 65 years of age and over. The rates for tonsillec— tomy and/or adenoidectomy were essentially zero for those 45 years of age and over. Surgical procedures for these older persons were probably related to diagnos— tic procedures, such as bronchoscopy and biopsy. Res- piratory surgical procedures were significantly more common in males than females, and tonsillectomy and/or adenoidectomy rates were also significantly greater for males than females, Surgical rates were significantly greater for white and other persons than for black persons, but the tonsillectomy and/or adenoidectomy rates did not differ significantly between the racial groups. Table G Rate of condition-related surgical procedures for persons with acute respiratory conditions, rate of tonsillectomy and/or adenoidectomy procedures, and charges for procedures, by condition group and selected characteristics: United States, 1980 Relevant respiratory surgical procedures‘ Tonsillectomy and/or adenoidectomy Rate Rate Condition group per 1,000 Charges per 1,000 Charges and characteristic population in millions population in millions All persons ................... 5.0 $2,082 2.7 $651 Persons with acute respiratory conditions ............ 8.5 1,429 5.3 640 Condition group Colds ......................... 11.0 865 7.4 442 Nasopharyngitis .................... 31.5 581 24.8 429 Influenza ....................... 5.7 483 3.0 184 Otitis media ...................... 17.9 236 11.2 143 Lower respiratory infections ............. 12.3 342 6.3 60 Age Under 12 years .................... 10.7 452 9.0 371 12—18 years ..................... 7.8 357 5.5 192 19—44 years ..................... 3.0 392 0.9 88 45—64 years ..................... 1.8 217 - - 65 years and over .................. 4.6 664 . . Sex Male .......................... 5.8 1,207 3.2 379 Female ........................ 4.1 875 2.3 272 Ftace Black ......................... 4.0 137 2.9 99 White and other .................... 5.1 1,946 2.7 552 ‘Excludes thoracotomies. Direct Costs Total charges—The total charges for acute respira- tory conditions and for each subgroup are presented in Table H. Charges for inpatient hospital care accounted for $4.1 billion, or 48.6 percent of the total direct costs specifically related to acute respiratory conditions. Physi- cian services represented 39.5 percent of total charges, and smaller proportions of the charges were attributed to prescribed medications (9.5 percent), other profes- sional services (2.0 percent), and dental and other ser- vices (0.4 percent). In comparison with direct costs for all health problems in the US. civilian nonin— stitutionalized population (Table J), acute respiratory conditions had significantly greater proportions of physi- cian charges and prescribed medication charges. For lower respiratory infections, charges for inpatient hospi— tal care were proportionately greater and charges for physician services less, a pattern concordant with the greater utilization of hospital services for lower respira- tory infections (Table F). The total direct costs of acute respiratory conditions were $8.3 billion, which represented 5.4 percent of the reported health care costs for the total population (Ta- bles H and J). Acute respiratory diseases were responsible for 5.6 percent of total direct costs for hospital care and 7.6 percent of charges for physician services. Lower respiratory infections represented the greatest charges ($3.5 billion) among the subgroups of acute respiratory conditions, comprising 42.0 percent of the total. Physi- cian charges for lower respiratory infections comprised $750 million, or 22.7 percent of the total physician charges for all persons with acute respiratory conditions, although persons having this condition represented only 7.7 percent of the total reporting an acute respiratory condition. Upper respiratory conditions differed from lower respiratory infections with respect to charges. Upper respiratory conditions had a larger proportion of total direct costs attributed to physician services (44.1— 57.3 percent) and to prescribed medications (13.7—14.5 percent) than did lower respiratory infections (21 .4 per- cent for physician services and 2.7 percent for prescribed medications). On the other hand, hospital charges were proportionately smaller for upper respiratory conditions ( 26. 1 —37.7 percent) than for lower respiratory infections (74.1 percent). Per capita charges and out—of-pocket expenditures— The per capita condition-related charges attributable to medical care for acute respiratory conditions during 1980 are given in Table K. Per capita charges ranged from 15 Table H Condition-related charges for persons with acute respiratory conditions and percent distribution by type of service, according to condition group: United States, 1980 Type of service All condition- related Hospital Other Other health inpatient Physician professional Prescribed health Condition group services care1 services2 services3 medications services" Persons with acute Amount in millions respiratory conditions ........ $8,345 $4,052 $3,299 $165 $795 $35 Colds ..................... 2,030 661 1,034 48 283 4 Nasopharyngitis ................ 915 345 403 34 133 - Influenza ................... 1,164 349 635 14 160 6 Otitis media .................. 1,048 273 600 23 143 8 Lower respiratory infections ......... 3,508 2,600 750 48 93 18 Persons with acute Percent distribution respiratory conditions ........ 100.0 48.6 39.5 2.0 9.5 0.4 Colds ..................... 100.0 32.6 51.0 2.3 13.9 0.2 Nasopharyngitis ................ 100.0 37.7 44.1 3.7 14.5 ~ Influenza ................... 100.0 30.0 54.5 1.2 13.7 0.5 Otitis media .................. 100.0 26.1 57.3 2.2 13.7 0.8 Lower respiratory infections ......... 100.0 74.1 21.4 1.4 2.7 0.5 ‘Excludes physician services provrded to patients admitted to the hospital. 2Includes both inpatient and outpatient physician services. 3Includes chiropractors, podiatrists, optometrists, psychologists, socral workers, nurses, physical therapists, and others. ‘lncludes dental services, eyeglasses, orthopedic appliances, hearing aids, diabetic supplies, and ambulance services. Table J Total charges for all persons and for persons with acute respiratory conditions and percent ristribution by type of health service, according to condition group: United States, 1980 Type of service All Hospital Other Other health inpatient Physician professional Prescribed health Condition group services care1 services2 services3 medications services“ Amount in millions All persons ............... $153,878 $71,955 $43,490 $9,197 $7,831 $21,405 Persons with acute respiratory conditions ........ 73,899 30,684 22,403 4,974 4,403 11,435 Colds ..................... 35,450 13,680 11,113 2,506 2,203 5.948 Nasopharyngitis ................ 12,052 4,723 3,867 849 880 1,733 Influenza .................... 35,282 14,153 10,770 2,382 2,049 5,929 Otitis media .................. 6,993 2,675 2,533 438 491 856 Lower respiratory infections .......... 11,541 6,545 2,990 476 564 967 Percent distribution All persons ............... 100.0 46.8 28.3 6.0 5.1 13.9 Persons with acute respiratory conditions ........ 100.0 41.5 30.3 6.7 6.0 15.5 Colds ..................... 100.0 38.6 31.3 7.1 6.2 16.8 Nasopharyngitis ................ 100.0 39.2 32.1 7.0 7.3 14.4 Influenza ................... 100.0 40.1 30.5 6.8 5.8 16.8 Otitis media .................. 100.0 38.2 36.2 6.3 7.0 12.2 Lower respiratory infections ......... 100.0 56.7 25.9 4.1 4.9 8.4 ‘Excludes charges for physician services provided to patients admitted to the hospital. 2|nc|udes both inpatient and outpatient physician services. 3Includes chiropractors, podiatrists, optometrists, psychologists, social workers, nurses, physical therapists, and others. ‘lncludes dental services, eyeglasses, orthopedic appliances, hearing aids, diabetic supplies, and ambulance services. 16 Table K Per capita condition-related charges for persons with acute respiratory conditions and percent of charges paid out of pocket, by type of health service and condition group: United States, 1980 All condition-related Hospital Ambulatory Prescribed Other health health services admissions‘ visits? medications services3 Per Percent Per Percent Per Percent Per Percent Per Percent capita out of capita out of capita out of capita out of capita out of Condition group charge pocket charge pocket charge pocket charge pocket charge pocket Total ......... $74 29.8 $42 13.1 $25 46.5 $7 70.1 $0.3 31.3 Colds ............ 35 37.8 14 8.9 17 52.0 5 69.2 0.0 47.0 Nasopharyngitis ....... 57 25.8 30 4.9 18 43.6 8 63.1 - - Influenza .......... 20 36.7 7 6.2 10 46.9 3 74.9 0.0 24.2 Otitis media ......... 92 36.8 28 13.0 50 41.5 13 72.0 1 26.7 Lower respiratory infections ......... 408 21.5 343 16.7 53 42.2 11 71.0 2 29.5 'lncludes inpatient physician services. 2’Includes outpatient visits to physicians and to other health professionals. 3Includes dental and other health services. $20 to $92 for upper respiratory conditions. The high per capita charge for lower respiratory conditions, $408, reflects greater charges for hospital care ($343). Of upper respiratory conditions, otitis media was associated with the greatest charges ($92), primarily because of high charges for ambulatory visits ($50) and prescribed medi— cations ($13). Per capita charges for colds ($35) were higher than those for influenza ($20), though not significantly so. The similarity was unanticipated because influenza is generally a more severe illness, and 1980 was character- ized as an epidemic year for influenza with a significant increase in fatalities. The population reporting one or more episodes of either condition was similar (57,638,000 for colds and 57,866,000 for influenza), and only slightly more ambulatory visits were reported for colds. Multiple episodes of colds do not account for the difference, as multiple episodes were reported with equal frequency for both conditions. However, in- fluenza was reported more frequently in the working-age population than colds were and was associated with great- er indirect costs. These findings suggest that adults may have identified their illness as influenza, knowing that it was epidemic, and remained home from work but did not seek medical care. On the other hand, medical care may have been sought for younger persons with colds because of parental uncertainty about the diagnosis, severe symptoms, or complications. The problem of com— plications might also indicate why per capita hospital charges are higher for colds than for influenza. The proportion of charges paid out of pocket aver- aged 29.8 percent and varied from 21.5 percent to 37.8 percent (Table K). The smallest proportion of out-of- pocket expenditures was for lower respiratory disease, reflecting the greater number of hospital admissions and subsequent third-party health care coverage for this con- dition. Prescribed medications were generally paid out of pocket (70 percent). Charges paid out of pocket for ambulatory visits (46.5 percent) also represented impor— tant sources of these expenses. Per capita hospital charges—Per capita inpatient hospital charges were greater than per capita charges for ambulatory visits, although the proportion of out-of— pocket expenses was less than one-third (Table K). Hos- pital charges for upper respiratory conditions were mod— est, ranging from $7 to $30 per capita, but per capita hospital charges for lower respiratory infections were more than 10 times greater at $343. Per capita hospital charges for nasopharyngitis and otitis media were some- what higher than charges for colds and influenza were. This reflects the higher surgical rates, specifically for tonsillectomy and/or adenoidectomy, for these conditions (Table G). Per capita charges by demographic characteristics— The patterns of costs for specific respiratory subgroups by demographic characteristics (Tables 7—11) indicate considerable differences in charges. The tables have been constructed so the charges for all conditions can be contrasted with charges specifically for respiratory condi- tions. The tables show per capita charges as well as the percent of total charges that were out of pocket. For persons reporting colds (Table 7), the average charges specifically for colds were $35, but charges for all conditions were $615. The proportion of out-of- pocket expenses for the indexed condition was 37.8 percent, and for all conditions 33.0 percent. By age group, the charges attributable to colds were greatest in those under 12 years of age and least in those 12—17 years of age. By contrast, per capita charges for all conditions were lowest in the youngest group and in- creased progressively for each age group. Therefore, the proportion of total per capita charges attributable to colds decreased in successively older groups. The proportion was 15.3 percent ($46/$300) for those under 12 years of age but decreased to 2.3 percent ($37/$1 ,601) for those 65 years of age and over. 17 Although more females than males reported colds (Table 1), females reported lower per capita charges for care of colds. The charges for all conditions were similar for both sexes. The proportion of cold-related out-of—pocket expenses was slightly greater for females (40.8 percent) than males (35.1 percent), and females also had a greater proportion of out-of—pocket expenses for all illnesses. There were no major racial differences in charges for all conditions or specifically for colds. The proportion of total out-of—pocket expenditures was significantly greater for white and other persons than for black persons. Charges for colds were greatest for those with the lowest family income and the least education of the head of family. However, for all conditions, the distribution of per capita charges across education or income tended to have a U—shaped relationship. Similar patterns were found for pharyngitis and in- fluenza (Tables 8 and 9). The proportion of total charges accounted for by these respiratory disease categories was lower in successively older age groups. Relatively small differences were found by sex and race in per capita charges specifically related to these conditions. The pattern of greater charges for males and black persons was generally present. An inverse relationship between per capita charges and education and income was found. Otitis media involved charges primarily for those under 12 years of age, but little variation among per capita charges was apparent by other sociodemographic charac- teristics (Table 10). The per capita charge pattern for lower respiratory infections differed markedly from that for the other condi- tions (Table 1 1). Per capita charges specifically for lower respiratory infections increased fivefold from the youngest to the oldest age group ($151 for under 12 years of age to $842 for 65 years of age and over). Per capita charges for all conditions also increased pro- portionately with age, from $543 to $2,882. The propor- tion of total charges attributed to lower respiratory disease was similar at all ages, varying from 27 to 37 percent. The proportion attributable to acute respiratory conditions did not decrease with increasing age, as was the case for upper respiratory infections. The proportion of lower respiratory charges that were paid out of pocket was lowest for persons 65 years of age and over, accounting for only 10.6 percent of total per capita charges. There were differences by sex and race in per capita charges for lower respiratory infections. Males had 2.4 18 times greater charges than females had for lower respira- tory infections, but the difference was not statistically significant. On the other hand, charges for all conditions for males were 1 .5 times greater than charges for females, a statistically significant difference. Black persons had almost twofold greater charges for lower respiratory dis- ease than white and other persons had, although the differential charges between the two groups for all medi- cal conditions was small and the differences were not significant. The proportion of total out-of—pocket ex— penses was significantly greater for black persons, being 2.6 times more than the proportion for white and other persons. This represents a reversal of the pattern observed for upper respiratory infections. Per capita charges were greatest for the lowest educa- tional level and were only about one-half as great among those who reported some college education. Charges for this condition differed considerably by income level. Persons with family incomes less than $20,000 per year had six times greater per capita charges for lower respira- tory disease than persons with incomes of $35,000 per year or more had, but the variances were great and the differences were not significant. Per capita charges for acute respiratory conditions confirm the pattern for visits. For younger persons, par- ticularly those under 12 years of age, respiratory infec- tions accounted for a major proportion of total health care charges, and these charges were primarily attributa- ble to ambulatory visits and prescribed medications (Ta- bles 12—16). Hospital and surgical charges resulted primarily from tonsillectomy and/or adenoidectomy. For young adults (18—44 years of age), the per capita charge for respiratory conditions constituted a lesser proportion of per capita charges for all conditions than at younger ages. Over 45 years of age, a relatively small proportion of health care charges were related to respiratory infec- tions; this was particularly striking for persons 65 years of age and over. However, the total per capita charges for all conditions were greater with increasing age. This pattern was found for each subgroup of acute respiratory conditions except lower respiratory disease. Persons with lower respiratory infections had markedly higher per capita charges, and charges were greatest in the older age groups. Moreover, total charges for all conditions were greater in persons with lower respiratory infections, indicating that their general health was not as good as that of persons with upper respiratory infections. Discussion Acute respiratory conditions are common and fre- quent in the general population and represent an impor- tant source of direct and indirect medical costs. NMCUES data permit estimates of incidence and costs for these conditions, but caveats should be noted regard- ing these estimates. The actual incidence rates for acute respiratory conditions cannot be accurately estimated from this survey because episodes were reported only if they were sufficiently troublesome to require a visit to a health provider or caused disability. An important strength of NMCUES as regards acute respiratory condi- tions was the quarterly sampling during the survey year. This frequent sampling and the use of a calendar diary improved the likelihood that relatively minor acute episodes would be recorded. The repeated surveys of the same cohort provided estimates of seasonal incidence, patterns of recurrence, and more reliable estimates of economic effects of illness, particularly when compared across sociodemographic groups. Another issue is the accuracy of respondent—reported diagnoses for the sub- groups of acute respiratory conditions. The accuracy is suspect, particularly when many episodes were not medically attended. However, the seasonal rates for sub- groups, documented in Figures 1 and 2, were remarkably consistent with the expected seasonal patterns and the reported influenza trends for 1980. Moreover, the agree- ment between the observed demographic correlates of acute respiratory subgroups in this survey and those reported in the literature support the separation of the general category into subgroups for analysis (Gwaltney, l985;Trevino and Moss, l984;Jack, 1981). During 1980, more than one-half of the civilian non- institutionalized population had one or more episodes of acute respiratory conditions. Colds and influenza ac- counted for the major proportion of occurrences, and their rates were approximately equal. However, calendar year 1980 exceeded the epidemic threshold for influenza and pneumonia deaths during the first 2 months of the year (Centers for Disease Control, 1984). Therefore, one would expect the rates for influenza, and perhaps for lower respiratory infections, to be unusually high. This probably accounts for the roughly equal rates, be— cause colds are generally more common than influenza (Gwaltney, 1985). Therefore, the results of this survey might not be representative of the “usual” year, and health care use patterns and costs may be affected as well. The effect of acute respiratory conditions on medical costs was impressive, although 1980 may not be a typical year. Direct medical charges attributed to respiratory disease accounted for 5 percent of the total direct charges for all medical care. This relatively high proportion of care costs resulted from the high incidence rate of acute respiratory conditions despite a relatively low cost per occurrence. The finding is even more impressive consid- ering that a large proportion of episodes were not medi- cally attended, the per capita costs for ambulatory visits were relatively low, and hospital admissions were infre- quent. Lower respiratory infections constituted the _only subgroup with an important proportion of hospital charges. Therefore, the direct costs attributable to acute respiratory conditions resulted from high incidence de- spite low unit costs. Indirect costs associated with acute respiratory condi- tions were equivalent with the direct costs of these disor- ders. Indirect costs reflect the economic or societal loss of productivity resulting from the condition or its treat— ment (Cooper and Rice, 1976). Disability costs are in- cluded if there was a loss of productivity even if medical consultation was not obtained. Conservative estimates based on bed-disability days yielded $7.7 billion for employed persons and $698 million for homemakers. Estimates based on bed disability are conservative be- cause lesser disability not requiring bed care is not in— cluded. These estimates are even more remarkable be- cause persons under 17 years, who had the highest inci- dence of acute respiratory conditions, were not included in the calculation of indirect costs. Moreover, indirect costs do not include the cost of attendance by a caretaker who might remain away from work although not ex- periencing the condition. The disability costs attributed to respiratory condi— tions were greater than those for either cardiovascular disease or musculoskeletal conditions, which are preva- lent chronic or recurrent disorders. The relatively great morbidity costs of acute, generally self—limiting condi— tions can be attributed to the frequency of the respiratory conditions and their predisposition to affect younger, working—age persons and to cause frequent brief periods of bed disability followed by recovery. Chronic disorders tend to result in removal from the work force through prolonged disability or a lower functional status. Thus, their impact might not be reflected in disability days lost from work. 19 Service use patterns and per capita charges differed among the subgroups of respiratory conditions. Colds and influenza were characterized by predominantly am- bulatory care with relatively low per capita charges. Otitis media and nasopharyngitis were more commonly associated with surgical procedures, primarily tonsillec- tomy and/or adenoidectomy, than were the other acute respiratory conditions (Kozak and McCarthy, 1984). De- spite more frequent surgical procedures, per capita charges remained relatively low for otitis media and nasopharyngitis. All of these subgroups were more com— mon in younger persons, for whom they comprised a major source of health costs. However. lower respiratory infections contrasted sharply with the upper respiratory conditions and had considerably higher per capita charges. Lower respiratory infections were common in older persons and were more often associated with hospi- tal admissions. The considerable costs associated with lower respiratory disease make preventive strategies for this group of conditions a high priority from the perspec- tive of cost containment and health improvement. The availability of vaccines capable of preventing pneumococcal pneumonia and influenza provides a po- tentially cost—effective strategy to prevent acute lower respiratory disease. The polyvalent pneumococcal vac— cine effectively prevents lower respiratory infection from the most common etiologic agent. The influenza vaccine is produced annually and contains the viruses most likely to be encountered during the year. Both immunizations have proved effective. The pneumococcal vaccine need be given only once to each individual; the influenza vaccine should be administered annually. Immunization has been recommended for older persons and for those with chronic or debilitating conditions. Immunization costs are small compared with the direct and indirect costs of acute lower respiratory illness, particularly for older persons. Untoward effects of the vaccines are mini- mal. However, the response by physicians and the public has been disappointingly small. Consideration should be given to a detailed formal assessment to determine whether this form of prevention is as cost effective as it appears to be. If so, incentives for immunization of persons covered by Medicare might be considered as a means of increasing compliance with the recommenda- tion for immunization. The distributions of utilization and charges for acute respiratory conditions by sociodemographic characteris- tics provide an interesting portrayal of service use. Over- all, acute respiratory conditions had the highest incidence and greatest per capita charges in children and adolescents and were lower in older persons. This pattern was most prominent for upper respiratory conditions (colds, in- fluenza, nasopharyngitis, and otitis media). Lower res- piratory infections were major reasons for service use and medical charges at the two extremes of the age distribution, in children and in those 65 years of age and over. Per capita charges for lower respiratory infec- tions were four times greater than those for any other subgroup. Males and white and other persons had greater 20 per capita charges for acute upper respiratory conditions, although the reported incidence was not remarkably dif- ferent than that for females and black persons. This suggests that incidence of acute upper respiratory condi- tions is roughly similar by sex and race, but careseeking behaviors differ. Black persons and those with lower income levels had greater charges for lower respiratory diseases. Because most persons with lower respiratory infections seek medical care, the increased charges for black persons may relate to more severe illness, delay in seeking care, or complications that increase morbidity. When ambulatory visits for all acute respiratory con- ditions were compared with ambulatory visits for unre- lated conditions, an interesting pattern was found. Acute respiratory conditions represented a greater proportion of all visits and of all per capita charges for younger persons. For older persons, the number of acute respira- tory conditions was somewhat less, and these conditions accounted for a relatively small proportion of all ambula- tory care visits. The incidence of acute respiratory condi- tions decreases in older persons, but the prevalence of chronic disorders increases. For example, older persons make more ambulatory visits and have more hospital admissions for cardiovascular and musculoskeletal condi- tions. There is no indication from these survey data that acute respiratory conditions are more common in persons with chronic conditions. Therefore, the financial impact of acute respiratory conditions is greater on younger persons (and their caretakers) than on older persons. The financial impact of lower respiratory infec- tions is somewhat greater than the impact of upper res- piratory conditions among older persons, who have greater incidence and unit charges for lower respiratory infec- tions. Acute respiratory conditions have been considered relatively unimportant from the economic perspective because of the self-limiting nature and relatively low costs of care for each episode. However, data from NMCUES indicate that the aggregate direct costs attribut- able to these conditions are relatively great, and the indirect costs from lost or decreased productivity are remarkably high, equivalent to the direct costs. Although the cost impact on individuals is low, the total cost to society is high because of the frequency of these conditions and the higher incidence in younger employed individuals. The economic impact of these conditions relates primarily to indirect costs. The direct costs of illness would be greater if all persons experiencing mor- bidity from acute respiratory conditions were to seek medical care. Acute lower respiratory infections differ in their economic impact. They more often result in ambulatory care visits and hospital admissions, and the direct charges for care are proportionately higher than for upper respiratory conditions. The economic burden of acute respiratory conditions is largely related to the indirect costs of illness. There— fore, strategies to prevent work loss and functional disa- bility would have the greatest economic impact. The desirability of immunization for the elderly has been discussed. Planners should also consider the possi- ble benefits from immunizing persons under 65 years of age. For example, military recruits are immunized against influenza, and this successfully prevents interrup- tion of training because of infections from these viruses. The cost savings of maintaining the training sequence is substantial, so immunization is cost effective in this situation. However, it is not clear that immunization would be similarly cost effective in a civilian population or that compliance with immunization would be as great. A second strategy to decrease illness costs is to make drugs for symptomatic treatment available without prescription. Symptomatic relief could thus be obtained without a physician visit. This strategy becomes increas- ingly feasible as greater numbers of drugs formerly avail- able by prescription only become available “over the counter.” The fact that a majority of colds reported in this survey did not result in an ambulatory care visit indicates that self care is important. On the other hand, bacterial infections, such as otitis media and lower res- piratory disease, require antibiotics that remain prescrip- tion drugs in the United States because of the potential for serious side effects. It will be of interest to follow trends in the costs of care for acute respiratory conditions if immunization programs are expanded and more effective over-the- counter treatment for viral infections is introduced. Economic evaluation of trends in nonprescription therapy and immunization should be directed at indirect costs, which constitute the cost component most responsive to these strategies. 21 References Casady, R. J.: The survey design and estimation methodology for the NMCUES, in Proceedings of the 19th National Meeting of the Public Health Conference on Records and Statistics. DHHS Pub. No. (PHS) 81—1214. National Center for Health Statistics, Public Health Service. Hyattsville, Md., 1983, pp. 181—185. Centers for Disease Control: Influenza Surveillance Report, 1979-80 and 1980—81. Centers for Disease Control. Public Health Service. Atlanta,Ga., 1984. Cooper, B. S. and Rice, D. P.: The economic cost ofillness revisited. Soc. Secur. Bull..' 2l—36, Feb. 1976. Cox, B. G.: The weighted sequential hot deck imputation procedure, in Proceedings of the Section on Survey Research Methods, American Statistical Association. I980, pp. 72 l-726. Gwaltney, J. M., in G. H. Mandell, R. G. Douglas, and J. E. Bennett, eds., Principles and Practice of Infectious Diseases. New York. John Wiley and Sons, Inc., 1985, pp. 351—358. Harlan, W. R., Thomas, J. W., Murt, H. A., et al.: Health care utilization and costs of adult cardiovascular disease. National Medical Care Utilization and Expenditure Survey. Series C, No. 6. National Center for Health Statistics, Public Health Service. To be published. Hodgson, T. A., Chief Economist, Office of Analysis and Epidemiol- ogy, National Center for Health Statistics, and Rice, D. P., Professor. Department of Social and Behavioral Sciences and the Aging Health Policy Center, University of California at San Francisco: Personal communication, 1984. Jack, 5.: Current estimates from the National Health Interview Sur- vey, United States, 1980. Vital and Health Statistics. Series 10, No. I39. DHHS Pub. No. (PHS) 82—l567. National Center for Health Statistics, Public Health Service. Washington. US. Govem- ment Printing Office, Dec. l98|. Kish, L.: Survey Sampling. New York. John Wiley and Sons, Inc., 1965. Kozak, L. J., and McCarthy, E.: Hospital use by children in the United States and Canada. Vital and Health Statistics. Series 5, No. I. DHHS Pub. No. (PHS) 84—1477. National Center for Health Statistics, Public Health Service. Washington. US. Government Printing Office, Aug. 1984. 22 Lepkowski, J. M., Landis, J. R., Parsons, P. E., et al.: Statistical methodologies for analyzing a complex sample survey: The National Medical Care Utilization and Expenditure Survey. National Medical Care Utilization and Expenditure Survey. Series A, Methodology. National Center for Health Statistics, Public Health Service. To be published. Lepkowski, J. M., Stehouwer, S., and Landis, J. R.: Strategies for the analysis of imputed data in a sample survey, in Proceedings of the Section on Survey Research Methods, American Statistical Association, 1984. Murt, H. A., Parsons, P. E., Harlan, W. R., et al.: Disability, utilization, and costs associated with musculoskeletal conditions. National Medical Care Utilization and Expenditure Survey. Series C, No. 5. DHHS Pub. No. 86—20405. National Center for Health Statistics, Public Health Service. Washington. US. Govern- ment Printing Office, Sept. 1986. Parsons, P. E., Lichtenstein, R., Berki, S. E., et al.: The costs of illness, United States, I980. National Medical Care Utilization and Expenditure Survey. Series C, No. 3. DHHS Pub. No. 86—20403. National Center for Health Statistics, Public Health Service. Washington. US. Government Printing Office, Apr. 1986. Trevino, F. M., and Moss, A. J.: Health indicators for Hispanic, black, and white Americans. Vital and Health Statistics. Series 10, No. 148. DHHS Pub. No. (PHS) 84-1576. National Center for Health Statistics, Public Health Service. Washington. US. Govem- ment Printing Office, Sept. I984. Walker, K. E., and Gaugcr, W. H.: The dollar value of household work. Information Bulletin No. 60. Ithaca, NY. College of Human Ecology, 1973. World Health Organization: Manual of the International Statistical Classification of Diseases, Injuries, and Causes of Death, Based on the Recommendations of the Ninth Revision Conference, 1975. Geneva. World Health Organization, 1977. List of Detailed Tables 10. 11. 12. 13. 14. 15. 16. . Number of persons with acute respiratory conditions and rate per 1,000 population, by condition and selected characteristics: United States, 1980 .............................................. . Mean ambulatory care visits for persons with colds and percent distributions by reason for visit and age, sex, and race: United States, 1980 ...................................................... Mean ambulatory care visits for persons with nasopharyngitis and percent distributions by reason for visit and age, sex, and race: United States, 1980 ................................................. . Mean ambulatory care visits for persons with influenza and percent distributions by reason for visit and age, sex, and race: United States, 1980 ................................................... Ambulatory care visits for persons with otitis media and percent distributions by reason for visit and age, sex, and race: United States, 1980 ...................................................... Mean ambulatory care visits for persons with lower respiratory infections and percent distributions by reason for visit and age, sex, and race: United States, 1980 ......................................... Per capita charges for all conditions and for colds among persons with colds and percent of charges paid out of pocket, by selected characteristics: United States, 1980 ....................................... Per capita charges for all conditions and for nasopharyngitis among persons with nasopharyngitis and percent of charges paid out of pocket, by selected characteristics: United States, 1980 ........................ Per capita charges for all conditions and for influenza among persons with influenza and percent of charges paid out of pocket, by selected characteristics: United States, 1980 ................................... Per capita charges for all conditions and for otitis media among persons with otitis media and percent of charges paid out of pocket, by selected characteristics: United States, 1980 ............................... Per capita charges for all conditions and for lower respiratory infections among persons with lower respiratory infections and percent of charges paid out of pocket, by selected characteristics: United States, 1980 ................ Per capita condition-related charges and percent of charges paid out of pocket for persons with colds, by type of health service, age, sex, and race: United States, 1980 ....................................... Per capita condition-related charges and percent of charges paid out of pocket for persons with nasopharyngitis, by type of health service, age, sex, and race: United States, 1980 ............................... Per capita condition-related charges and percent of charges paid out of pocket for persons with influenza, by type of health service, age, sex, and race: United States, 1980 ................................... Per capita condition-related charges and percent of charges paid out of pocket for persons with otitis media, by type of health service, age, sex, and race: United States, 1980 ................................... Per capita condition-related charges and percent of charges paid out of pocket for persons with lower respiratory infections, by type of health service, age, sex, and race: United States, 1980 ........................ 24 26 27 28 29 30 31 32 34 35 36 37 38 39 23 Table 1 Number of persons with acute respiratory conditions and rate per 1,000 population, by condition and selected characteristics: United States, 1980 Estimated All acute Lower population respiratory Naso- Otitis respiratory Characteristic in thousands conditions Colds pharyngitis Influenza media infections Age Number of persons in thousands Under 12 years .................. 42,019 28,582 17,314 4,189 13,412 6,513 2,237 12—17 years ..................... 24,045 12,628 6,518 1,712 6,905 892 612 18-44 years ..................... 89,713 44,918 22,307 6,161 24,733 2,517 3,113 45—64 years ..................... 43,578 18.528 7,921 2,837 9,459 1,062 1,641 65 years and over ................ 23,469 7,646 3,579 1,250 3,357 440 988 Sex Male .......................... 107,481 50,547 25,588 6.596 25,831 5,576 3,607 Female ........................ 115,344 61.755 32,050 9,553 32,035 5,848 4,985 Race Black .......................... 26,046 10,252 6,119 1,411 3,736 872 709 White and other ................. 196,779 102,049 51,519 14,738 54,130 10,552 7,883 Education of head of family Not a high school graduate ......... 72,128 31,004 15,319 4,339 15,031 2,441 2,564 High school graduate ............. 78,063 39,954 20,472 5,614 20,225 4,093 3,113 Some college .................... 72,633 41,345 21,847 6,196 22,610 4,891 2,914 Family income Less than $10,000 ................ 42,766 19.334 9,626 2,765 9,474 2,080 1,594 $10,000-S19,999 ................ 60,176 80,074 15,775 4,227 15,224 2,834 2,770 $20,000-$34,999 ................ 74,839 39,429 19,874 5,745 21.154 4,146 2,763 $35.000 or more .................. 45,043 23,464 12,363 3,413 12,014 2,365 1,464 Age Rate per 1,000 population Under 12 years .................. 42,019 680.2 412.0 99.8 319.2 155.0 53.2 12—17 years ..................... 24,045 525.2 271.1 71.2 287.2 37.1 25.4 18-44 years ..................... 89,713 500.7 248.7 68.7 275.7 28.1 34.7 45—64 years ..................... 43.578 425.2 181.8 65.1 217.1 24.4 37.7 65 years and over ................ 23,469 325.8 152.5 53.3 143.0 18.8 42.1 Sex Male .......................... 107,481 470.3 238.1 61.4 240.3 51.9 33.6 Female ........................ 115,344 535.4 277.9 82.8 277.7 50.7 43.2 Race Black .......................... 26.046 393.6 234.9 54.2 143.4 33.5 27.2 White and other ................. 196.779 518.6 261.8 74.9 275.1 53.6 40.1 Education of head of family Not a high school graduate ......... 72,128 429.8 212.4 60.2 208.4 33.8 35.6 High school graduate ............. 78,063 511.8 262.3 71.9 259.1 52.4 39.9 Some college .................... 72,633 569.2 300.8 85.3 311.3 67.3 40.1 Family income Less than $10,000 ................ 42,766 452.1 225.1 64.6 221.5 48.6 37.3 $10,000-$19,999 ................ 60,176 499.8 262.1 70.2 253.0 47.1 46.0 $20,000- $34,999 ................ 74,839 526.9 265.6 76.8 282.7 55.4 36.9 $35,000 or more .................. 45,043 520.9 274.5 75.8 266.7 52.5 32.5 24 Table 2 Mean ambulatory care visits for persons with colds and percent distributions by reason for visit and age, sex, and race: United States, 1980 Reason for visit Estimated Indexed Indexed condition Unrelated population condition and unrelated morbidity Age, sex, and race in thousands All visits only morbidity only Mean visits Total ...................... 57,633 5.9 0.6 0.1 5.2 Age Under 12 years ................... 17,314 4.8 0.8 0.1 3.9 12—17 years ...................... 7,546 4.6 0.5 0.0 4.1 18-44 years ...................... 21,279 6.0 0.5 0.1 5.4 45-64 years ...................... 7,921 6.9 0.5 0.1 6.3 65 years and over .................. 3,579 11.0 0.6 0.2 10.2 Sex Male ............................ 25,588 5.2 0.6 0.1 4.5 Female .......................... 32,050 6.4 0.6 0.1 5.7 Race Black ........................... 6,119 4.4 0.6 0.1 3.7 White and other ................... 51,519 6.1 0.6 0.1 5.4 Percent distributions Total ...................... 100.0 100.0 10.4 1.6 88.0 Age Under 12 years ................... 30.0 100.0 17.1 2.8 80.1 12-17 years ...................... 13.1 100.0 11.3 1.0 87.6 18—44 years ...................... 36.9 100.0 8.6 1.0 90.4 45—64 years ...................... 13.7 100.0 7.3 1.4 91.3 65 years and over .................. 6.2 100.0 5.6 1.9 92.5 Sex Male ............................ 44.4 100.0 12.0 1.6 86.4 Female .......................... 55.6 100.0 9.4 1.6 89.0 Race Black ........................... 10.6 100.0 13.9 2.2 83.8 White and other ................... 89.4 100.0 10.1 1.5 88.3 Table 3 Mean ambulatory care visits for persons with nasopharyngitis and percent distributions by reason for visit and age, sex, and race: United States, 1980 Reason for visit Estimated Indexed Indexed condition Unrelated population condition and unrelated morbidity Age, sex, and race in thousands All visits only morbidity only Mean visits Total .................. 16,150 ”.3 0.6 0.2 6.5 Age Under 12 years .............. 4,189 6.0 0.7 0.1 5.2 12—17 years ................. 1,957 4.7 0.7 0.1 4.0 18—44 years ................. 5,916 7.2 0.5 0.1 6.6 45-64 years ................. 2,837 10.0 0.6 0.3 9.1 65 years and over ............. 1,250 10.0 0.7 0.3 9.0 Sex Male ....................... 6,596 6.5 0.7 0.1 5.7 Female ..................... 9,553 7.8 0.6 0.2 7.1 Race Black ...................... 1,411 9.5 0.7 0.3 8.5 White and other .............. 14,738 7.1 0.6 0.1 6.4 Percent distributions Total ................. 100.0 100.0 8.4 2.1 89.5 Age Under 12 years .............. 25.9 100.0 11.3 2.3 86.5 12—17 years ................. 12.1 100.0 14.0 1.3 84.7 18—44 years ................. 36.6 100.0 7.5 1.4 91.1 45~64 years ................. 17.6 100.0 5.9 3.0 91.2 65 years and over ............. 7.7 100.0 7.2 2.7 90.0 Sex Male ....................... 40.8 100.0 10.5 2.1 87.4 Female ..................... 59.2 100.0 7.2 2.1 90.7 Race Black ...................... 8.7 100.0 7.6 3.0 89.4 White and other .............. 91.3 100.0 8.5 2.0 89.5 26 Mean ambulatory care visits for persons with influenza and percent distributions by reason for visit and age, sex, and race: United States, 1980 Table 4 Reason for visit Estimated Indexed Indexed condition Unrelated population condition and unrelated morbidity Age, sex, and race in thousands All visits only morbidity only Mean visits Total ....................... 57,866 5.7 0.4 0.0 5.3 Age Under 12 years ................... 13,412 4.2 0.4 0.1 3.7 12—17 years ...................... 7,582 4.8 0.3 0.0 4.4 18-44 years ...................... 24,056 5.8 0.3 0.0 5.5 45—64 years ...................... 9,459 6.7 0.3 0.1 6.3 65 years and over .................. 3,357 9.7 0.5 0.1 9.1 Sex Male ............................ 25,831 4.7 0.4 0.0 4.3 Female .......................... 32,035 6.4 0.3 0.1 6.0 Race Black ........................... 3,736 5.4 0.5 0.1 4.7 White and other ................... 54,130 5.7 0.3 0.0 5.3 Percent distributions Total ....................... 100.0 100.0 6.3 0.8 92.9 Age Under 12 years ................... 23.2 100.0 10.7 1.3 88.1 12—17 years ..................... 13.1 100.0 6.2 0.5 93.3 18—44 years ...................... 41.6 100.0 5.2 0.6 94.2 45-64 years ...................... 16.3 100.0 5.1 0.9 94.0 65 years and over .................. 5.8 100.0 5.4 1.3 93.4 Sex Male ............................ 44.6 100.0 7.8 0.8 91.4 Female .......................... 55.4 100.0 5.4 0.8 93.8 Race Black ........................... 6.5 100.0 10.2 1.5 88.2 White and other ................... 93.5 100.0 6.0 0.8 93.2 27 Table 5 Ambulatory care visits for persons with otitis media and percent distributions by reason for visit and age, sex, and race: United States, 1980 Reason for visit Estimated Indexed Indexed condition Unrelated population condition and unrelated morbidity Age, sex, and race in thousands All visits only morbidity only Mean visits Total ................. 11,424 7.4 1.6 0.4 5.3 Age Under 12 years .............. 6,513 6.3 1.7 0.4 4.2 12-17 years ................. 998 7.6 1.3 0.3 5.9 18—44 years ................. 2,411 8.1 1.6 0.3 6.2 45—64 years ................. 1,062 9.8 1.5 0.5 7.8 65 years and over ............. 440 12.9 1.4 0.8 10.7 Sex Male ....................... 5,576 6.7 1.6 0.4 4.7 Female ..................... 5,848 8.0 1.7 0.4 5.9 Race Black ...................... 872 7.4 1.7 0.2 5.5 White and other .............. 10,552 7.4 1.6 0.4 5.3 Percent distributions Total ................. 100.0 100.0 22.1 5.7 72.3 Age Under 12 years .............. 57.0 100.0 27.5 6.6 65.9 12—17 years ................. 8.7 100.0 17.5 4.4 78.0 18-44 years ................. 21.1 100.0 19.6 4.2 76.3 45—64 years ................. 9.3 100.0 14.9 4.9 80.2 65 years and over ............. 3.9 100.0 10.7 6.6 82.8 Sex Male ....................... 48.8 100.0 23.4 6.4 70.2 Female ..................... 51.2 100.0 21.0 5.0 74.0 Race Black ...................... 7.6 100.0 22.7 3.2 74.1 White and other .............. 92.4 100.0 22.0 5.9 72.1 28 Table 6 Mean ambulatory care visits for persons with lower respiratory infections and percent distributions by reason for visit and age, sex, and race: United States, 1980 Reason for visit Estimated Indexed Indexed condition Unrelated population condition and unrelated morbidity Age, sex, and race in thousands All visits only morbidity only Mean visits Total ...................... 8,592 8.7 1.3 0.4 7.0 Age Under 12 years ................... 2,237 8 2 1.3 0.3 6.7 12—18 years ...................... 779 7.4 2.0 0.3 5.0 19—44 years ...................... 2,946 7.7 1.1 0.2 6.4 45—64 years ...................... 1,641 10 4 1.6 0.6 8.2 65 years and over .................. 988 10 6 1.0 0.6 9.1 Sex Male ............................ 3,607 8.4 1.4 0.3 6.7 Female .......................... 4,985 8.9 1.3 0.4 7.2 Race Black ........................... 709 7.0 1.4 0.3 5.3 White and other ................... 7,883 8.8 1.3 0.4 7.1 Percent distributions Total ....................... 100.0 100.0 15.2 4.1 80.6 Age Under 12 years ................... 26.0 100.0 15.7 3.4 80.9 12—18 years ...................... 9.1 100.0 27.5 4.7 67.8 19-44 years ...................... 34.3 100.0 14.4 2.7 82.8 45—64 years ...................... 19.1 100.0 15.6 5.5 78.9 65 years and over .................. 11.5 100.0 9.0 5.8 85.2 Sex Male ............................ 42.0 100.0 16.7 3.5 79.9 Female .......................... 58.0 100.0 14.3 4.6 81.2 Race Black ........................... 8.3 100.0 19.9 4.3 75.9 White and other ................... 91.7 100.0 14.9 4.1 81.0 Table 7 Per capita charges for all conditions and for colds among persons with colds and percent of charges paid out of pocket, by selected characteristics: United States, 1980 All conditions Colds Estimated population Per capita Percent Per capita Percent Characteristic in thousands charge out of pocket charge out of pocket Total ................... 57,638 $615 33.0 $35 37.8 Age Under 12 years ................ 17.314 300 33.3 46 35.5 12—17 years ................... 7,546 444 48.0 25 38.9 18—44 years ................... 21,279 661 35.2 30 38.5 45—64 years ................... 7,921 900 31.5 34 40.8 65 years and over .............. 3,579 1,601 20.2 37 41.1 Sex Male ........................ 25,588 613 30.5 42 35.1 Female ...................... 32,050 617 34.9 30 40.8 Race Black ........................ 6,119 605 24.0 37 27.6 White and other ............... 51,519 616 34.0 35 39.1 Education of head of family Not a high school graduate ....... 15,319 675 27.6 40 34.5 High school graduate ........... 20,472 544 36.7 35 38.5 Some college .................. 21,847 640 33.9 32 40.1 Family income Less than $10,000 .............. 9,626 814 25.0 46 25.9 $10,000—$19,000 .............. 15,775 599 31.1 27 47.6 $20,000-$34,999 .............. 19,874 498 38.5 36 38.5 $35,000 or more ............... 12,363 669 36.0 36 39.3 30 Table 8 Per capita charges for all conditions and for nasopharyngitis among persons with nasopharyngitis and percent of charges paid out of pocket, by selected characteristics: United States, 1980 All conditions Nasopharyngitis Estimated population Per capita Percent Per capita Percent Characteristic in thousands charge out of pocket charge out of pocket Total ................... 16,150 $746 31.3 $57 25.8 Age Under 12 years ................ 4,189 472 24.1 59 21.8 12—17 years ................... 1,957 626 37.4 102 15.9 18—44 years ................... 5,916 657 35.0 35 33.4 45—64 years ................... 2,837 1,092 30.8 56 35.0 65 years and over .............. 1,250 1,493 27.8 80 24.8 Sex Male ........................ 6,596 756 25.8 61 24.3 Female ...................... 9,553 726 35.3 54 27.0 Race Black ........................ 1,411 654 30.1 68 12.4 White and other ............... 14,738 755 31.4 56 27.3 Education of head of family Not a high school graduate ....... 4,339 787 28.9 78 18.9 High School graduate ........... 5,614 786 28.2 54 26.1 Some college .................. 6,196 682 36.4 44 33.9 Family income Less than $10,000 .............. 2,765 890 24.3 75 15.4 $10,000-$19,000 .............. 4,227 676 32.8 50 29.4 $20,000-634,999 .............. 5 745 730 32.0 60 25.8 3435.000 or more ............... 3:413 745 35.1 44 35.0 Table 9 Per capita charges for all conditions and for influenza among persons with influenza and percent of charges paid out of pocket, by selected characteristics: United States, 1980 All conditions Influenza Estimated population Per capita Percent Per capita Percent Characteristic in thousands charge out of pocket charge out of pocket Total ................... 57,866 $610 31.1 $20 36.7 Age Under 12 years ................ 13,412 278 33.5 22 33.5 12—17 years ................... 7,582 511 36.9 12 41.3 18—44 years ................... 24,056 587 32.9 13 51.7 45—64 years ................... 9,459 792 33.7 22 39.6 65 years and over .............. 3,357 1,808 18.8 75 17.5 Sex Male ........................ 25,831 549 27.7 20 36.2 Female ...................... 32,035 359 33.4 20 37.1 Race Black ........................ 3,736 555 35.6 27 38.6 White and other ............... 54,130 614 30.9 20 365 Education of head of family Not a high school graduate ....... 15,031 791 24.3 27 30.6 High school graduate ........... 20,225 549 31.1 23 33.2 Some college .................. 22,610 544 37.8 13 51.0 Family income Less than $10,000 .............. 9,474 1,021 20.4 41 17.7 $10,000-$19,000 .............. 15,224 554 33.8 20 37.9 $20,000-$34,999 .............. 21,154 504 33.9 16 48.4 $35,000 or more ............... 12,014 542 39.2 11 60.5 32 Table 10 Per capita charges for all conditions and for otitis media among persons with otitis media and percent of charges paid out of pocket, by selected characteristics: United States, 1980 All conditions Otitis media Estimated population Per capita Percent Per capita Percent Characteristic in thousands charge out of pocket charge out of pocket Total ................... 11,424 $312 33.0 $92 36.8 Age Under 12 years ................ 6,513 436 27.4 91 37.6 12-17 years ................... 998 701 62.0 55 65.3 18—44 years ................... 2,411 527 36.8 61 51.3 45-64 years ................... 1,062 1,011 37.4 125 22.3 65 years and over .............. T440 T2,517 T20.4 f269 117.8 Sex Male ........................ 5,576 543 32.4 107 32.4 Female ...................... 5,848 679 33.4 77 42.6 Race Black ........................ 872 699 28.3 110 34.0 White and other ............... 10,552 605 33.4 90 37.1 Education of head of family Not a high school graduate ....... 2,441 643 26.8 85 30.2 High school graduate ........... 4,093 642 34.5 109 31.0 Some college .................. 4,891 472 36.8 81 46.8 Family income Less than $10,000 .............. 2,080 996 20.9 157 18.0 $10,000-$19,000 .............. 2,834 476 34.8 59 51.8 $20,000-534,999 .............. 4,146 497 43.6 95 40.2 $35,000 or more ............... 2,365 640 33.4 67 51.0 33 Table 11 Per capita charges for all conditions and for lower respiratory infections among persons with lower respiratory infections and percent of charges paid out of pocket, by selected characteristics: United States, 1980 All conditions Lower respiratory infections Estimated population Per capita Percent Per capita Percent Characteristic in thousands charge out of pocket charge out of pocket Total ................................. 8,592 $1,343 23.2 $408 21.5 Age Under 12 years .............................. 2,237 543 24.1 151 20.5 12—17 years ................................. 779 955 40.3 354 41.5 18—44 years ................................. 2,946 1,083 31.5 370 27.8 45—64 years ................................. 1,641 2,158 20.2 593 18.5 65 years and over ............................ 988 2,882 12.9 842 10.6 Sex Male ...................................... 3,607 1,665 20.2 621 20.4 Female ..................................... 4,985 1,1 10 26.6 255 23.4 Race Black ...................................... 709 1,483 31.6 712 45.7 White and other ............................. 7,883 1,331 22.4 381 17.5 Education of head of family Not a high school graduate ..................... 2,564 1,886 17.1 519 13.5 High school graduate .......................... 3,113 1,240 23.2 480 26.7 Some college ................................ 2,914 976 33.7 234 26.0 Family income Less than $10,000 ............................ 1,594 1,970 16.7 561 19.5 $10,000-$19,000 ............................ 2,770 1,752 21.1 595 20.4 $20,000-$34,999 ............................ 2,763 900 29.5 300 23.7 $35,000 or more .............................. 1,464 725 37.7 95 35.0 34 9%: Table 12 Per capita condition-related charges and percent of charges paid out of pocket for persons with colds, by type of health service, age, sex, and race: United States, 1980 All health services1 Hospital admissions Ambulatory visits Prescribed medications Estimated Per Percent Per. Percent Per Percent Per Percent population capita out of capita out of capita out of capita out of Age, sex, and race in thousands charge pocket charge pocket charge pocket charge pocket Total ................................. 57,633 $35 37.8 $ 14 8.9 $17 52.0 $5 69.2 Age Under 12 years .............................. 17,308 46 35.5 17 12.3 23 44.2 6 66.9 12—17 years ................................. 7,546 25 38.9 10 4.5 11 60.0 4 69.7 1844 years ................................. 21,279 30 38.5 12 9.6 14 55.0 4 69.4 45—64 years ................................. 7,921 34 40.8 14 2.4 15 65.2 6 67.9 65 years and over ............................ 3,579 37 41.1 12 6.8 18 51.6 6 81.8 Sex Male ...................................... 25,583 41 35.1 19 9.6 17 53.4 5 69.0 Female ..................................... 32,050 30 40.8 9 7.9 16 50.7 5 69 0 Race Black ...................................... 6,116 37 27.6 16 10.2 17 38.4 5 48.6 White and other ............................. 51,517 35 39.1 13 8.8 17 53.6 5 71.5 1 Includes dental and other services, such as eyeglasses, orthopedic appliances. hearing aids, diabetic supplies, and ambulance services. 91: Table 13 Per capita condition-related charges and percent of charges paid out of pocket for persons with nasopharyngitis, by type of health service, age, sex, and race: United States, 1980 All health servicesl Hospital admissions Ambulatory visits Preseribed medications Estimated Per Percent Per Percent Per Percent Per Percent population capita out of capita out of capita out of capita out of Age, sex, and race in thousands charge pocket charge pocket charge pocket charge pocket Total ................................. 16,150 $57 25.8 530 4.9 $18 43.6 $8 63.1 Age Under 12 years .............................. 4,189 59 21.8 36 6.2 18 41.6 5 62.2 12—17 years ................................. 1,957 102 15.9 82 7.0 16 45.3 5 70.7 18—44 years ................................. 5,916 35 33.4 10 -— 16 38.7 8 64.9 45—64 years ................................. 2,837 56 35.0 24 5.0 18 59.3 14 54.2 65 years and over ............................ 1,250 80 24.8 39 - 29 37.8 11 77.5 Sex Male ...................................... 6,596 61 24.3 35 6.8 18 43.6 8 57.4 Female ..................................... 9,553 53 27.0 27 3.2 18 43.7 8 66.9 Race Black ...................................... 1,411 68 12.4 39 0.0 22 23.8 7 43.7 White and other ............................. 14,738 56 27.3 29 5.5 18 45.9 8 64.7 1Includes dental and other services, such as eyeglasses, orthopedic appliances, hearing aids, diabetic supplies, and ambulance services. LE Table 14 Per capita condition-related charges and percent of charges paid out of pocket for persons with influenza, by type of health service, age, sex, and race: United States, 1980 l All health services Hospital admissions Ambulatory visits Prescribed medications Estimated Per Percent Per Percent Per Percent Per Percent population capita out of capita out of capita out of capita out of Age, sex, and race in thousands charge pocket charge pocket charge pocket charge pocket 'l‘otal ................................. 57,864 $20 36.7 $7 6.2 $10 46.9 $3 74.9 Age Under 12 years .............................. 13,409 22 33.5 7 8.7 13 39.7 3 71.8 12—17 years ................................. 7,582 12 41.3 3 5.0 6 51.6 2 73.6 18-44 years ................................. 24,056 13 51.7 2 1.0 9 56.1 3 77.4 45-64 years ................................. 9,469 22 39.6 5 5.4 13 43.2 4 74.7 65 years and over ............................ 3,357 75 17.5 53 6.8 17 38.1 4 73.0 Sex Male ...................................... 25,828 20 36.2 7 6.1 11 45.8 3 74.0 Female ..................................... 32,035 20 37.1 7 6.3 10 47.9 3 75.5 Race Black ...................................... 3,734 27 38.6 6 11.9 18 41.6 3 69.9 White and other ............................. 54,130 20 36.5 7 5.9 10 47.6 3 75.3 1 Includes dental and other services, such as eyeglasses, orthopedic appliances, hearing aids, diabetic supplies, and ambulance services. 82'. Table 15 Per capita condition-related charges and percent of charges paid out of pocket for persons with otitis media, by type of health service, age, sex, and race: United States, 1980 All health services1 Hospital admissions Ambulatory visits Prescribed medications Estimated Per Percent Per Percent Per Percent Per Percent population capita out of capita out of capita out of capita out of Age, sex, and race in thousands charge pocket charge pocket charge pocket charge pocket Total ................................. 11,424 $92 36.8 $28 13.0 $50 41.5 $133 72.0 Age Under 12 years .............................. 6,513 91 37.6 28 13.7 51 42.6 13 69.9 12—17 years ................................. 998 55 65.3 13 10.0 32 47.4 11 76.6 18—44 years ................................. 2,411 61 51.3 — — 48 43.4 13 81.8 45434 years ................................. 1,062 125 22.3 41 - 64 30.2 14 60.2 65 years and over ............................ 1440 1269 117.8 f 188 14.7 166 141.3 1 10 172.8 Sex Male ...................................... 5,576 107 32.4 45 10.2 49 43.2 12 69.9 Female ..................................... 5,848 77 42.6 12 23.1 51 40.0 13 73.9 Race Black ...................................... 872 110 34.0 36 20.0 60 31.7 13 82.0 White and other ............................. 10,552 90 37.1 27 12.2 50 42.5 12 71.1 1 Includes dental and other services, such as eyeglasses, orthopedic appliances, hearing aids, diabetic supplies, and ambulance services. 6?: Table 16 Per capita condition-related charges and percent of charges paid out of pocket for persons with lower respiratory infections, by type of health service, age, sex, and race: United States, 1980 All health services1 Hospital admissions Ambulatory visits Prescribed medications Estimated Per Percent Per Percent Per Percent Per Percent population capitn out of capita out of capita out of capita out of Age, sex, and race in thousands charge pocket charge pocket charge pocket charge pocket Total ................................. 8,592 $408 21.5 $343 16.7 $53 42.2 $11 71.0 Age Under 12 years .............................. 2,287 151 20.5 101 6.9 40 43.2 10 68.9 12—17 years ................................. 779 354 41.5 275 43.2 70 30.2 9 75.8 18—44 years ................................. 2,946 370 27.8 319 23.3 40 52.1 11 71.8 45—64 years ................................. 1,641 593 18.5 504 13.5 73 44.0 12 71.6 65 years and over ............................ 988 842 10.6 748 7.4 71 30.5 13 69.2 Sex Male ...................................... 3,607 621 20.4 553 17.4 56 41.5 10 69.2 Female ..................................... 4,985 255 23.4 191 15.3 50 42.8 11 72.2 Race Black ...................................... 709 712 45.7 646 45.7 46 37.1 13 77.5 White and other ............................. 7,883 381 17.5 316 11.4 53 42.6 11 70.3 1 Includes dental and other services such as eyeglasses, orthopedic appliances, diabetic supplies, hearing aids, and ambulance services. Appendixes Contents |. Sample Design, Data Collection, and Processing ....................................... 41 Introduction ......................................................... 41 Survey Background ..................................................... 41 Sample Design ....................................................... 41 Research Triangle Institute Sample Design ........................................ 42 National Opinion Research Center Sample Design .................................... 42 Data Collection ....................................................... 43 Weighting .......................................................... 43 Survey Nonresponse .................................................... 44 Attrition Imputation ..................................................... 44 Item Nonresponse and Imputation ............................................. 45 IL Data Modifications to Public Use Files ............................................ 47 Ill. Analytical Strategies ...................................................... 49 Notion of an Average Population .............................................. 49 Role of Weights and Imputation .............................................. 50 Estimation Procedures ................................................... 53 N. Sampling Errors ........................................................ 55 Totals ............................................................ 56 Means ............................................................ 56 Proportions, Percents, and Prevalence Rates ....................................... 58 Mutually Exclusive Subgroup Difference .......................................... 59 Subgroup to Total Group Differences ........................................... 60 V. Definition of Terms ....................................................... 61 List of Appendix Figures |. Dynamic population for 12 time period panel survey ..................................... 49 ll. Estimated mean charges per hospital outpatient department visit, by 4 family income classes for all and real data: United States, 1980 ...................................................... 52 Ill. Estimated mean charges per hospital outpatient department visit, by 16 imputation classes for all persons and for persons in families with incomes less than $5,000: United States,1980 ........................... 52 List of Appendix Tables I. Percent of data imputed for selected survey items in 4 of the NMCUES public use data files: United States, 1980 . . . . 45 II. Effect of person-year adjustment on counts and sampling weights, by 4 population groups: United States, 1980 ..... 50 Ill. Sample size, means, and standard errors for 5 disability measures, by all and real data subgroups? United States, 1980 .............................................................. 51 IV. Sample size, means, standard errors, and element variance for total charge for a hospital outpatient department visit, by data type: United States, 1980 ............................................... 51 V. Coefficients for standard error formula for estimated aggregates or totals, by estimator .................. 56 VI. Values for roh and 5‘2 for standard error formula for estimated means, by estimator ..................... 57 VII. Values of roh for standard error formula for estimated proportions, by estimator ...................... 58 40 Appendix I. Sample Design, Data Collection, and Processing Introduction The National Medical Care Utilization and Expendi- ture Survey (NMCUES) was designed to collect data about the US. civilian noninstitutionalized population during 1980. Because of the complexity of the survey, the analyst must be familiar with a range of design features, both to determine appropriate analytic methods and to investigate the impact that the design may have on a particular analysis. Several topics are addressed in this appendix: The overall design of NMCUES, the survey background, sampling methods, data collection methods, weighting, and compensation procedures for missing data. In these descriptions, the NMCUES data are presented essentially as they are available to the user of the public use data tape. This appendix draws heavily from a paper in the Proceedings of the 19th National Meeting of the Public Health Conference on Records and Statistics (Casady, 1983). Survey Background During the course of NMCUES, information was obtained on health, access to and use of medical services, associated charges and sources of payment, and health care coverage. The survey was cosponsored by the Na- tional Center for Health Statistics (NCHS) and the Health Care Financing Administration (HCFA). Data collection was provided under contract by the Research Triangle Institute (RTI) and its subcontractors, National Opinion Research Center (NORC) and SysteMetrics, Inc. The basic survey plan for NMCUES drew heavily on two previous national surveys: The National Health Interview Survey (NHIS), which is conducted by NCHS, and the National Medical Care Expenditure Survey (NMCES), which was cosponsored by the National Cen- ter for Health Services Research and NCHS. NHIS is a continuing multipurpose health survey first conducted in 1957. The primary purpose of NHIS is to collect information on illness, disability, and the use of medical care. Although some information on medi- cal charges and insurance payments has been collected in NHIS, the cross-sectional nature of the NHIS survey design is not well suited for providing annual data on charges and payments. NMCES was a panel survey in which sample house- holds were interviewed six times over an 18-month period in 1977 and 1978. NMCES was designed specifically to provide comprehensive data on how health services were used and paid for in the United States in 1977. NMCUES is similar to NMCES in survey design and question wording, so that analysis of change during the years between 1977 and 1980 is possible. Both NMCUES and NMCES are similar to NHIS in terms of question wording in areas common to the three sur- veys. Together they provide extensive information on illness, disability, use of medical care, costs of medical care, sources of payment for medical care, and health care coverage at two points in time. Sample Design General plan—The NMCUES sample of housing units and group quarters, hereafter jointly referred to as dwelling units, is a concatenation of two independently selected national samples, one provided by RTI and the other by NORC. The sample designs used by RTI and NORC are quite similar with respect to principal design features: Both can be characterized as stratified, multistage area probability designs. The principal differ- ences between the two designs are the type of stratifica- tion variables and the specific definitions of sampling units at each stage. Target population—All persons living in a sample dwelling unit at the time of the first interview became part of the national sample. Unmarried students 17—22 years of age who lived away from home were included in the sample if their parent or guardian was included in the sample. In addition, persons who died or were institutionalized between January 1 and the date of first interview were included in the sample if they were related to persons living in the sampled dwelling units and were living in the sample dwelling before their death or in— stitutionalization. All of these persons were considered “key” persons, and data were collected for them for the full 12 months of 1980 or for the portion of time that they were part of the US. civilian nonin- stitutionalized population. In addition, children born to key persons during 1980 were considered key persons, and data were collected for them from the time of birth. 41 Relatives from outside the original population (i.e., in- stitutionalized, in the Armed Forces, or outside the United States from January 1 up to the first interview) who moved in with key persons after the first interview were also considered key persons, and data were col- lected for them from the time they joined the key person. Relatives who moved in with key persons after the first interview but were part of the civilian noninstitutionalized population on January 1, 1980, were classified as “non- key” persons. Data were collected for nonkey persons for the time that they lived with a key person; but because they had a chance of selection in the initial sample, their data are not used for general analysis of persons. However, data for nonkey persons are used in an analysis of families because they contribute to the family’s utiliza- tion of and charges for health care during the time they are part of the family. Family analysis is not part of this investigation, though, and will not be discussed further. Persons included in the sample were grouped into “reporting units" for data collection purposes. Reporting units were defined as all persons related to each other by blood, marriage, adoption, or foster care status who lived in the same dwelling unit. The combined NMCUES sample consisted of approximately 7,200 reporting units, of which nearly 6,600 agreed to participate in the survey. In total, complete data were obtained on 17,123 key persons. The RTI sample yielded approximately 8,300 respondents and the NORC sample 8,800. Research Triangle Institute Sample Design Primary sampling units (PSU’s)—A PSU was de- fined as a county, a group of contiguous counties, or parts of counties with a combined minimum 1970 popula- tion size of 20,000. A total of 1,686 nonoverlapping RTI PSU‘s cover the entire land area of the 50 States and Washington, DC. The PSU’s were classified as one of two types. The 16 largest standard metropolitan statistical areas (SMSA’s) were designated as self-repre- senting PSU‘s, and the remaining 1,670 PSU’s in the primary sampling frame were designated as non-self-rep- resenting PSU's. Stratification of PSU’s—PSU’s were grouped into strata whose members tend to be relatively alike within strata and relatively unlike between strata. PSU’s derived from the 16 largest SMSA’s were of sufficient 1970 population size to be treated as primary strata. The 1,659 non-self-representing PSU’s from the continental United States were stratified into 42 approximately equal-sized primary strata. Each primary stratum had a 1970 popula- tion size of about 3.3 million. One supplementary pri- mary stratum of 11 PSU’s, with a 1970 population size of about 1 million, was added to the RTI primary frame to include Alaska and Hawaii. F irst-stage selection of PSU’s—The total RTI pri- mary sample consisted of 59 PSU’s, of which 16 were 42 self-representing. The non-self—representing PSU’s were obtained by selecting 1 PSU from each of the 43 non-self- representing primary strata. These PSU’s were selected with probability proportional to 1970 population size. Secondary stratification—In each of 59 sample PSU’s, the entire PSU was divided into nonoverlapping smaller area units called secondary sampling units (SSU’s). Each SSU consisted of one or more 1970 cen- sus-defined enumeration districts (ED's) or block groups (BG’s). Within each PSU the SSU’s were ordered and then partitioned to form approximately equal-sized sec- ondary strata. Two secondary strata were formed in the non-self—representing PSU drawn from Alaska and Hawaii, and four secondary strata were formed in each of the remaining 42 non-self-representing PSU’s. Thus, the non-self—representing PSU’s were partitioned into a total of 170 secondary strata. In a similar manner the 16 self-representing PSU’s were partitioned into 144 secondary strata. Second-stage selection of SSU’s—One SSU was selected from each of the 144 secondary strata covering the self-representing PSU’s, and two SSU’s were selected from each of the remaining secondary strata. All second- stage sampling was with replacement and with probability proportional to the SSU’s total noninstitutionalized popu- lation in 1970. The total number of sample SSU’s was 2 X 170 +144 = 484. Third-stage selection of areas and segments—Each SSU was divided into smaller nonoverlapping geographic areas, and one area within the SSU was selected with probability proportional to the 1970 total number of housing units. Next, one or more nonoverlapping seg- ments of at least 60 housing units (HU‘s) were formed in the selected area. One segment was selected from each SSU with probability proportional to the segment HU count. In response to the sponsoring agencies’ re- quest that the expected household sample size be reduced, a systematic sample of one-sixth of the segments was deleted from the household sample. Thus, the total third- stage sample was reduced to 404 segments. Fourth-stage selection of housing units—All dwell- ing units within the segment were listed, and a systematic sample of dwelling units was selected. The procedures used to determine the sampling rate for segments guaran- teed that all dwelling units had an approximately equal probability of selection. All reporting units within the selected dwelling units were included in the sample. National Opinion Research Center Sample Design Primary sampling units (PSU's)—The land area of the 50 States and Washington, DC, was divided into nonoverlapping PSU’s. A PSU consisted of SMSA‘s, parts of SMSA’s, counties, parts of counties, or inde- pendent cities. Grouping of counties into a single PSU occurred when individual counties had a 1970 population ofless than 10,000. Zoning of PSU’s—The PSU’s were classified into two groups according to metropolitan status (SMSA or not SMSA). These two groups were individually ordered and then partitioned into zones with a 1970 census popu- lation size of 1 million persons. F irst-stage zone selection of PSU’s—A single PSU was selected within each zone with a probability propor- tional to its 1970 population. It should be noted that this procedure allows a PSU to be selected more than one time. For instance, an SMSA PSU with a population of 3 million may be selected at least twice and possibly as many as four times. The full general-purpose sample contained 204 PSU’s, which were systematically allo- cated to 4 subsamples of 51 PSU’s. The final set of 76 sample PSU’s was chosen by randomly selecting 2 complete subsamples of 51 PSU’s; l subsample was included in its entirety, and 25 PSU’s in the other subsam- ple were selected systematically for inclusion in NMCUES. Second—stage zone selection of SSU’s—Each PSU selected in the first stage was partitioned into a nonover- lapping set of SSU‘s defined by BG’s, ED’s, or a combi- nation of the two types of census units. SSU’s were selected from the ordered list of these SSU’s. The cumulative number of households in the second-stage frame for each PSU was divided into 18 zones of equal width. An SSU could be selected more than once, as was the case in the PSU selection. If a PSU had been hit more than once in the first stage, then the second-stage selection process was repeated as many times as there were first-stage hits. Some 405 SSU's were identified by selecting 5 SSU’s from each of the 51 PSU’s in the subsample that was included in its entirety and 6 SSU‘s from each of the 25 PSU’s in the subsample for which one-half of the PSU’s were included. Third—stage selection of segments—The selected SSU‘s were subdivided into area segments with a mini- mum size of 100 housing units. One segment was then selected with probability proportional to the estimated number of housing units. Fourth-stage selection of housing units—Sample selection at this level was essentially the same as for the RTI design. Data Collection Field operations for NMCUES were performed by RT] and NORC under specifications established by the cosponsoring agencies. Persons in the sample dwelling units were interviewed at approximately 3-month inter- vals beginning in February 1980 and ending in March 1981. The core questionnaire was administered during each of the five interview rounds to collect data on health, health care, health care charges, sources of pay— ment, and health care coverage. A summary of responses was used to update information reported in previous rounds. Supplements to the core questionnaire were used during the first, third, and fifth interview rounds to collect data that did not change during the year or that were needed only once. Approximately 80 percent of the third- and fourth-round interviews were conducted by telephone; all remaining interviews were conducted in person. The respondent for the interview was required to be a household member 17 years of age and over. A nonhousehold proxy respondent was permitted only if all eligible household members were unable to respond because of health, language, or mental condition. Weighting For the analysis of NMCUES data, sample weights are required to compensate for unequal probabilities of selection, to adjust for the potentially biasing effects of failure to obtain data from some persons or reporting units (RU’s) (i.e., nonresponse), and failure to cover some portions of the population because the sampling frame did not include them (i.e. , undercoverage). Basic sample design weights—Development of weights reflecting the sample design of NMCUES was the first step in the development of weights for each person in the survey. The basic sample design weight for a dwelling unit is the product of four components that correspond to the four stages of sample selection. Each of the four weight components is the inverse of the probability of selection at that stage when sampling was without replacement, or the inverse of the expected number of selections when sampling was with replace- ment, and multiple selection of the sample unit was possible. Two-sample adjustment factor—As previously dis— cussed, the NMCUES sample is composed of two inde- pendently selected samples. Each sample, together with its basic sample design weights, yields independent un- biased estimates of population parameters. Because the two NMCUES samples were of approximately equal size, a simple average of the two independent estimators was used for the combined sample estimator. This is equivalent to computing an adjusted basic sample design weight by dividing each basic sample design weight by 2. In the subsequent discussion, only the combined sample design weights are considered. Total nonresponse and undercoverage adjustment— A weight adjustment factor was computed at the RU level to compensate fOr RU-level nonresponse and under- coverage. Because every RU within a dwelling unit is included in the sample, the adjusted basic sample design weight assigned to an RU is simply the adjusted basic sample design weight for the dwelling unit in which the RU is located. An RU was classified as responding if members of the RU initially agreed to participate in NMCUES and as nonresponding otherwise. Initially, 96 RU weight-adjustment cells were formed by cross-classifying the following variables: Race of RU head (white or all other), type of RU head (female, 43 male, or husband-wife), age of RU head (four levels), and size of RU (four levels). These cells were then collapsed to 63 cells so that each cell contained at least 20 responding RU’s. Within each cell an adjustment factor was computed so that the sum of adjusted basic sample design weights would equal the March 1980 Current Population Survey estimate for the same popula- tion. The weight for nonresponse and undercoverage was computed for each RU as the product of the adjusted basic sample design weight and the nonresponse—under- coverage adjustment factor for the cell containing the RU. Poststrauflcation adjustment—Once the nonre- sponse—undercoverage adjusted RU weights were com— puted, a poststratification adjusted weight was computed at the person level. Because each person within an RU is included in the sample, the nonresponse and under- coverage adjusted weight for a sample person is the nonresponse—undercoverage adjusted weight for the RU in which the person resides. Each person was classified as responding or nonresponding, as discussed sub- sequently in the section on attrition imputation. Sixty poststrata were formed by cross-classifying age (15 levels), race (2 levels), and sex (2 levels). One poststratum (black males 75 years of age and over) had fewer than 20 respondents, so it was combined with an adjacent poststratum (black males 65—74 years of age), resulting in 59 poststrata. Estimates based on population projections from the I980 census were obtained from the Bureau ofthe Census for the US. civilian noninstitutionalized population by age, race, and sex poststrata for February I, May 1, August 1, and November 1, 1980. The mean of these midquarter population estimates for each of the poststrata was computed and used as the 1980 average target popu- lation for calculating the poststrata adjustment factors. Survey-based estimates of the average poststrata population were developed using the nonresponse and undercoverage adjusted weights. First, a survey-based estimate of the target population of each poststratum for each quarter was computed by summing the nonre- sponse and undercoverage adjusted weights for respond— ents eligible for the survey on the midquarter date. Then the survey—based estimate of the 1980 average population was computed as the mean of the four midquarter esti- mates. Finally, the poststratification adjustment factor in each poststratum was computed as the ratio of the 1980 average target population (obtained from Bureau of the Census data) to the NMCUES 1980 average popu- lation. The poststratified weight for each respondent was then computed as the product of the nonresponse and undercoverage adjusted weight and the poststratification adjustment factor for the poststratum containing the respondent. Thus, the weighting procedure is composed of three steps: Development of base sample design weights for each RU, adjustment for RU-level nonresponse and undercoverage, and adjustment for person-level nonre— 44 sponse and undercoverage. A further adjustment for the number of days a person was an eligible member of the US. civilian noninstitutionalized population was made, but this adjustment affects only certain types of estimates from NMCUES and is discussed in Appendix III. Survey Nonresponse Nonresponse in panel surveys such as NMCUES occurs when sample individuals refuse to participate in the survey (total nonresponse), when initially participat— ing individuals drop out of the survey (attrition nonre- sponse), or when data for specific items on the question- naire are not collected (item nonresponse). Response rates for RU’s and persons in NMCUES were high, with approximately 90 percent of the sample RU’s agree- ing to participate in the survey and approximately 94 percent of the individuals in the participating RU‘s sup- plying complete information. Even though the overall response rates are high, survey—based estimates of means and proportions may be biased if nonrespondents tend to have different health care experiences than respondents or if there is a substantial response rate differential across subgroups of the target population. Furthermore, annual totals tend to be underestimated unless allowance is made for the loss of data attributable to nonresponse. Two methods commonly used to compensate for survey nonresponse are data imputation and adjustment of sampling weights. For NMCUES, data imputation was used to compensate for attrition and item nonre- sponse, and weight adjustment was used to compensate for total nonresponse. The calculation of the Weight adjustment factors was discussed in the previous section. Attrition lmputation A special form of the sequential hot—deck imputation method (Cox, I980) was used for attrition imputation. First, each sample person with incomplete annual data (referred to as a “recipient”) was linked to a sample person with similar demographic and socioeconomic characteristics who had complete annual data (referred to as a “donor”). Second, the time periods for which the recipient had missing data were divided into two categories: lmputed eligible days and imputed ineligible days. lmputed eligible days were those days for which the donor was eligible (i.e., in scope), and imputed ineligible days were those days for which the donor was ineligible (i.e., out of scope). The donor’s medical care experiences, such as medical provider visits, dental visits, and hospital stays, during the imputed eligible days were imputed into the recipient’s record for eligible days. Finally, the results of the attrition imputation were used to make the final determination of a person’s respon- dent status. If more than two-thirds of the person’s total eligible days (both reported and imputed) were imputed eligible days, then the person was considered a total nonrespondent, and the data for the person were removed from the data file. Item Nonresponse and Imputation Persons classified as respondents may fail to provide information for some or many items in the questionnaire. In NMCUES, item nonresponse was particularly a prob- lem for health care charges, income, and other sensitive topics. The extent of missing data varied by question, and imputation for all items in the data file would have been expensive. Imputations were made for missing data on key demographic, economic, and charge items across five of the six data files in the public use data tape (all except the condition file). Table I illustrates the extent of the item nonresponse problem for selected survey measures that received imputations in four data files used in this report. . Demographic items tend to require the least amount of imputation. Some, such as age, sex, and education, had insignificant levels of imputation. Income items had Table I Percent of data lmputed for selected survey items in 4 of the NMCUES pubic use data files: United States, 1980 Tape Percent location Description imputed Person file (n 2 17.123) P54 Age . 0.1 P57 Race ‘20.0 P59 Sex 0.1 P62 Highest grade attended 0.1 P67 Perceived health status 08 P592 Functional limitation score 3.2 P125 Number of bed-disability days 7.9 P128 Number of work-loss days 89 P135 Number of cut-down days 8.2 P399 Wages, salary. business income 9.7 P434 Pension income 3.5 P445 Interest income 21 .6 P462 Total personal income 230.4 Medical visit file (n : 86,594) M1 17 Total charge 25.9 M123 First source of payment 1.8 M125 First source of payment amount 11.6 Hospital stay file (n = 2,946) H252 Nights hospitalized 3.1 H124 Total charge 36.3 H130 First source of payment 2.2 H132 First source of payment amount 17.6 Medical expenses tile (n : 58,544) E117 Total charge 19.4 E123 First source of payment 2.8 E125 First source of payment amount 10.0 'Fiace let children under 17 years at age imputed lrorn race 01 head ol reporting unit 2Cumulative across 12 types ol Income higher levels of nonresponse. Nearly one-third of the persons required imputation for at least one component of total personal income, which is a cumulation of earned income and l 1 sources of unearned income. The bed-dis- ability days, work-loss days, and cut-down days have levels of imputation between those for the demographic and income items. The highest levels of imputation occurred for the important charge items on the various visit, hospital stay, and medical expenses files. Total charges for medi- cal visits, hospital stays, and prescribed medicines and other medical expenses were imputed for 25.9 percent, 36.3 percent, and 19.4 percent ofthe events, respectively. Among the source-of—payment data, the imputation rates for the source of payment were small, but the rates for the amount paid by the first source of payment were generally subject to high rates of imputation. The number of nights hospitalized on the hospital stay file was im— puted at a rate comparable to that for first source of payment. The methods used to impute for missing items were diverse and tailored to the measure requiring imputation. Three types of imputation predominate: Edit or logical imputations, a sequential hot deck, and a weighted se— quential hot deck. The edit or logical imputations were used to eliminate missing data that could reasonably be determined from other data items that provided over- lapping information for the given item. The sequential hot deck was used primarily for small numbers of imputa- tions for the demographic items; the weighted sequential hot deck was used more extensively and for virtually all other items for which imputations were made. The edit or logical imputation is a process in which the value of a missing item is deduced from other avail- able information in the data file. For example, race was not recorded for children under 17 years of age during the survey. Instead, a logical imputation was made during data processing that assigned the race of the head of the reporting unit to the child. Similarly, extensive editing was performed for the charge data before any imputations were made. If first source of payment was available, only one source of payment was given; and if total charge was missing, the value of the first source of payment amount was assigned to the total charge item. In the sequential hot-deck procedure, the data are grouped within imputation classes formed by variables thought to be correlated with the item to be imputed. An additional sorting within imputation classes by vari- ables also thought to be correlated with the imputed item is typically used. An initial value, such as the mean of the nonmissing cases for the item, is assigned as a “cold-deck” value. The first record in the file is then examined. lf it is missing, the “cold-deck” value replaces the missing data code; if it is real (not missing), the real value replaces the “cold-deck“ value and becomes a “hot—deck” value. Then the next record is examined. Again, the “hot-deck” value is used to replace missing 45 data; if the value is real, it becomes the “hot-deck” value. The process continues sequentially through the sorted file. The weighted hot deck, a modification of the sequential hot deck, uses weights to determine which real values are used to impute for a particular record needing imputation. The imputation process will be described for two items to illustrate the nature of imputation for NMCUES. For Hispanic origin, two different imputation procedures were used: Logical and sequential hot deck. Because Hispanic origin was not recorded during the interview for children under 17 years of age, a logical imputation was made by assigning to the child the Hispanic origin of the wife of the head of the reporting unit, if present, and the origin of the head of the reporting unit otherwise. For the remaining cases that were not assigned a value by this procedure, the data were grouped into classes by observed race of the head of the reporting unit; within classes, the data were sorted by reporting unit identifica- tion number, primary sampling unit, and segment. An unweighted sequential hot deck was used to impute values of Hispanic origin for the remaining cases with missing values. The imputations for medical visit total charge were made after extensive editing had been done to eliminate as many inconsistencies as possible between sources of payment and total charges. The medical visit records were then separated into three types: emergency room, hospital outpatient department, and doctor visits. Within each type, the records were classed and sorted by several measures, which differed across visit types, prior to 46 a weighted hot-deck imputation. For example, the records for doctor visits were classified by reason for visit, type of doctor seen, whether work was done by a physician, and age of the individual. Within the groups formed by these classification variables, the records were then sorted by type of health care coverage and month of visit. Finally, the weighted hot-deck procedure was used to impute for missing total charge, sources of payment, and source-of—payment amounts for the classified and sorted data file. Because imputations were made for missing items for a large number of the important items in NMCUES, they can be expected to influence the results of the survey in several ways. In general, the weighted hot deck is expected to preserve the means of the nonmissing observations when those means are for the total sample or classes within which imputations were made. How- ever, means for other subgroups, particularly small sub- groups, may be changed substantially by imputation. In addition, sampling variances can be substantially underestimated when imputed values are used in the estimation process. For a variable with one-quarter of its values imputed, for instance, sampling variances based on all cases will be based on one-third more values than were actually collected in the survey for the given item. That is, the variance would be too small by a factor of at least one-third. Finally, the strength of relationships between measures that received imputa- tions can be substantially attenuated by the imputation. A more complete discussion of these issues can be found in Lepkowski, Stehouwer, and Landis (1984). Appendix II. Data Modifications to Public Use Files During the preparation of this report, a number of problems were discovered in the NMCUES public use files that required modification of the data. Eight sets of problems were identified: (1) Sampling weights for 68 newborns (i.e., persons born in 1980) were in error. (2) Six respondents had extremely high hospital stay charges. (3) Forty-seven respondents had health care coverage categories inconsistent with source of payment for some medical events. (4) For 173 respondents, fewer bed-disability days than hospital nights were reported. (Length—of—stay data were recorded in terms of the number of nights—as opposed to days—spent in the hospital.) (5) Four respondents had extremely long lengths of stay in the hospital as a result of incorrect hospital admis- sion dates. (6) Four respondents had poverty status categories that were inconsistent with their poverty status level. (7) Nine respondents were coded as deliveries in the hospital file but had inconsistent values for other hospital stay data. (8) One respondent had duplicate hospital stay records. Details of the changes made to correct these problems may be obtained from NCHS. Detailed descriptions of the specific changes are provided in the NMCUES series report by Lepkowski et al. (to be published). General information on the problems and changes is outlined below. (1) Records for 68 newborns were incorrectly coded as eligible for the entire survey period (all 366 days) although born after January 1, 1980. These errors were corrected by changing the eligible time—adjustment factor and the person time—adjusted weight for each of the 68 records. (2) After careful examination, the University of Michigan and NCHS determined that six hospital stay records, each with charges of at least $90,000, were incorrect and should be changed. These six records and related information in the person file (e. g., hospital stay charges, total charges) were changed to conform with records in the Medicare best estimate file or with other information about each of the six respondents’ hospitali- zations contained in the hospital stay file. (3) Discrepancies between source of payment and health care coverage were noted in the course of analysis. All of the discrepancies involved Medicare coverage. Forty-seven respondents reporting Medicare as a source of payment in the medical visit, hospital stay, or pre- scribed medicine file were not properly coded as covered by Medicare. Health care coverage for these respondents was reclassified strictly according to source-of—payment data. Respondents originally coded as covered by private insurance but whose records did not show private insur- ance as a source of payment for any services were coded as having Medicare and private insurance coverage. When reassignment based on imputed data for source of payment would conflict with real data for health care coverage, the real data were used in preference to the imputed data. (4) For 173 cases, the value for hospital nights was greater than the value for bed-disability days. According to interviewer instructions for the NMCUES question- naire, hospital nights should be included in bed-disability days, except for newborns. Therefore, the value of bed- disability days was adjusted to equal hospital nights for these 173 cases, a procedure used in Health Interview Survey processing. However, this adjustment does not fully compensate for the errors in recording or computing bed-disability days. It is likely that bed—disability days are still underestimated for these 173 cases after the edit. The edit was performed without regard to the impu- tation status of either bed-disability days or hospital nights. (5) Four cases with discrepancies between bed-disa- bility days and hospital nights also had improperly coded hospital admission dates, which led to the recording of excessively long lengths of stay. In these cases, the admission dates and hospital nights were corrected, and the bed-disability days edit was not necessary. (6) Comparison of the continuous and the categorical poverty status variables on the public use file identified four respondents whose categorical poverty status was inconsistent with their continuous poverty status value. The categorical variable was changed to correspond to their poverty status on the continuous variable. 47 48 (7) A variety of problems were discovered on nine records coded as deliveries in the hospital stay file. (a) (b) Two deliveries were attributed to male re- spondents. Examination of the data files suggested that the sex variable was incor- rectly coded in these two cases; the sex was therefore recoded to female. A third delivery attributed to a male was actually that of the respondent’s spouse. In this case, the hospi- tal record was reassigned and appropriate changes made in the person file for both respondents. Four hospitalizations for newborns were in- correctly coded as deliveries. These were re- coded in the hospital stay file. A fifth new- bom’s hospital record was attributed to its mother. In this case, the hospital record was transferred to the newborn, and appropriate changes were made in the person file for both respondents. (c) One delivery was attributed to a 74-year-old woman. Following an NCHS recommenda— tion, the response was recoded to reflect signs, symptoms, and ill—defined conditions as the admitting condition. (8) Two sets of duplicate records (four records in total) in the hospital stay file were discovered for one respondent. The two duplicates were deleted in the hospi- tal stay file, and necessary changes were made in the person file. Three of the four records had been imputed to another respondent for reasons of attrition. No changes were made in the records for the respondent receiving the attrition-imputed records. Appendix III. Analytical Strategies Notion of an Average Population NMCUES was a panel survey in which members of the population were followed during the panel period (calendar year 1980). The nature of a dynamic population over time influences the rules used to determine who should be followed and for how long. It also has signifi- cant implications for the form of estimators for character- istics of the population during the panel period. Before discussing estimation strategies for NMCUES data, it is useful to review the nature of a dynamic population overtime. The nature of a longitudinal population as members move in and out of eligibility is illustrated in Figure 1. Stable members of the population appear at Figural Dynamic population ior12time period panel survey Stable > Leaver —> ——> Entrant > —> Mixed —> —> ——> —> —> > 0123456789101112 Time the beginning and at every time point during the life of the longitudinal time period. Even though these per- sons are termed “stable," they may, of course, change residence during the panel period and may be quite difficult to trace. Leavers are persons who are eligible at the beginning of a time period but become ineligible at some later time. Leaving may occur through events such as death, institutionalization, or moving outside the geographic boundary of the population. At the same time, new members (entrants) may enter the population through births or through returns from institutions or from outside the geographic boundary of the population. Finally, there also will be mixed population elements that are both entrants and leavers from the population during different time periods. The majority of the popula- tion typically will be stable in nature, but it is the entrants and leavers, persons who may be experiencing major changes in their lives, who are often of particular interest to analysts of panel survey data. In order to assure adequate coverage of all elements in the dynamic popula- tion considered over the entire time period, NMCUES followup rules were carefully specified to include en- trants, leavers, and mixed population elements properly. As an illustration, consider a person who was in the Armed Forces on January 1, 1980, and was dis- charged on June 1, 1980, thus becoming a key person (i.e., one to be followed for the rest of the year while eligible) in the NMCUES panel. Because NMCUES was designed to provide information about the civilian popu- lation, medical care use and charges during the first 5 months of 1980 for this person are outside the scope of the survey. Data about health care use and charges were not collected unless they occurred after June 1. At the same time, this person was eligible for only 7 months of the year, and he was also “at risk” of incurring health care use or charges for only 7 of the 12 months. This person thus contributes only 7/12 or 0.58 of a year of eligibility (person year) to the study. This quantity is referred to as the “time-adjustment factor” in the documentation and throughout these appendixes. For readers not familiar with the concept of “person years of risk,” it may be useful to consider briefly the rules that were used to determine eligibility for a given person at a given moment during 1980. There were essentially two ways of becoming eligible for or entering 49 the NMCUES eligible population. One way was to be a member of the US. civilian noninstitutionalized popu- lation on January l, 1980, and hence a member of the original or base cohort about which inferences were to be made. The second way was to enter after January 1 through birth or through rejoining the civilian nonin- stitutionalized population during the year by returning from an institution, from the Armed Forces, or from outside the United States. There were also several ways by which persons who were eligible members of the population could become ineligible. Death obviously re- moves a person from further followup, as does in- stitutionalization, joining the Armed Forces, or moving to a residence outside the United States. Information was collected to monitor the exact number of days that each person selected for NMCUES was eligible during the year. These eligibility periods are summarized by the time-adjustment factor on each record. The use of “person years” to form sample estimates requires careful assessment of the characteristic to be estimated. Estimates that use only data collected from persons during periods of eligibility (e.g., total number of doctor visits, total charges for health care) do not need to account for time adjustments. Estimates for per- son characteristics (e.g., total population, proportion of the population in a given subgroup) must be based on person years to obtain estimates that correspond to those for health care estimates. Some estimates require the use of the time-adjustment factor in the denominator but not in the numerator. For example, an estimate of the mean total charge for health care during 1980 must use the total charges for health care as a numerator without time adjustment, but the denominator must be the number of person years that the US. population was exposed to the risk of such charges during 1980, a time-adjusted measure. The mean in this case is actually a rate of health care charges per person year of exposure for the eligible population in I980. When making estimates in which person years are important, the effect of the time-adjustment factor will vary depending on the subpopulation of interest (Table II). A cross—sectional cohort of N persons selected from the U.S. population on January 1, 1980, and followed for the entire year will contribute a total number of person years for 1980 that is smaller than N because of removals (i.e., deaths, institutionalization, and so on). If entrants are added to the initial cohort during the year, the person years contributed by the initial cohort and the entrants may well exceed N, but it will still be less than the number of original cohort members plus the number ofentrants. The difference between persons and person years will vary by subgroups as well. Females 25—29 years of age on January I constitute a cohort for which few additions are expected because of entrants from institu- tions, the Armed Forces, or living abroad. Few removals are expected because of death, institutionalization, join- ing the Armed Forces, or moving abroad. On the other hand, males 80 years of age and over on January 1 will contribute a much smaller number of person years to the population than the total number of persons in the cohort at the beginning of the year, because a large number of the cohort will die during the year. Role of Weights and Imputation Estimated means and sampling errors from NMCUES for bed-disability days, work-loss days, work-loss days in bed, cut-down days, and restricted-activity days are presented in Table III. For each survey measure, separate estimates were computed using all data (i.e., both real and imputed) and using only the real data. The un- weighted and weighted mean, unweighted and weighted simple random sampling standard error of the mean, and the weighted complex standard error, which accounts for the stratified, multistage nature of the design, are presented. For each measure, the weighted means computed using all the data and using only the real data are quite similar. This similarity is not unexpected given that the weighted hot deck imputation procedure is designed to preserve the weighted mean for overall sample estimates. The simple random sampling standard errors, however, are smaller when all data are used simply because the simple random sampling variance is inversely related to the sample size. For the complex standard error, three of the five measures have smaller standard errors when all data are used, and the other two measures show the opposite relationship. Weighting and imputation for the disability measures have little or no effect on esti- mated means or their standard errors for the total Table II Effect of person-year adjustment on counts and sampling weights, by 4 population groups: United States, 1980 Sum of sampling weights Basic weight Adjusted weight Population group Sample size Person years in thousands in thousands Total population ............... 17,123 1686284 226,368 222,824 Females, 25—29 years of age .......... 702 699.39 9,529 9.494 Males, 80 years of age and over ........ 113 104.05 1,384 1,274 All persons born during 1980 .......... 251 121.02 3.560 1,713 50 Table III Sample size, means, and standard errors for 5 disablity measures, by all and real data subgroups: United States, 1980 Estimates in this table are presented for illustrative Unweighted estimates Weighted estimates purposes. Calculations were made prior to data Simple Simple modifications described in Appendix II. random random sampling sampling Complex Disability measure Sample standard standard standard and data type size Mean error Mean error error Bed-disability days All data .............................. 17,123 5.303 0.1279 5.268 0.1269 0.1540 Real data ............................ 15,777 5.253 0.1326 5.228 0.1319 0.1599 Work-loss days All data .............................. 13.069 3.614 0.1221 3.696 0.1220 0.1629 Real data ............................ 11,537 3.510 0.1284 3.574 0.1277 0.1716 Work-loss days in bed All data .............................. 13.069 1.516 0.0508 1.568 0.0518 0.0592 Real data ............................ 10,970 1.530 0.0556 1.578 0.0568 0.0652 Cut-down days All data .............................. 17,123 6.831 0.1681 6.881 0.1697 0.3343 Real data ............................ 15,724 6.609 0.1721 6.639 0.1735 0.3322 Restricted-activity days All data .............................. 17,123 13746 0.2559 13.805 0.2573 0.4716 Real data ............................ 14,049 13.036 0.2732 13.064 0.2742 0.4658 Table IV Sample size, means, standard errors, and element variance for total charge for a hospital outpatient department visit, by data type: United States, 1980 Estimates in this table are presented for illustrative Unweighted estimates Weighted estimates purposes. Calculations were made prior to data Simple Simple modifications described in Appendix II. random random sampling sampling Complex Element Sample standard standard standard variance Data type size Mean error Mean error error (x 10 3) All data .............. 9,529 51.86 1.030 51.61 1.018 1.914 9.87 Real data only ......... 4,688 52.28 1.436 52.27 1.430 2.936 9.59 Imputed data .......... 4,841 51.45 1.476 50.98 1.447 1.600 10.14 Real data Not donor .................. 929 47.83 2.108 48.53 2.117 3.935 4.17 Donor once ................. 2,789 55.85 2.016 55.76 1.982 3.386 11.00 Donor twice ................. 841 48.61 3.525 49.37 3.579 4.879 10.78 Donor 3—5 times ............. 120 29.45 7.340 28.97 7.987 11.64 7.66 population because the amount of missing data for these measures is small (approximately 7 or 8 percent). For other measures that have larger amounts of missing data, imputation has larger effects. Consider the means and standard errors for total charge for a hospital outpatient department visit shown in Table IV. Of 9,529 hospital outpatient department visits (real visit records plus those generated from the attrition imputation process), 4,841 have a total charge that was imputed from one of the other hospital outpatient department visit records. Thus, more than one-half of the total charges were missing for this particular medical event. Despite the large amount of missing data, the weighted means using all the data and using only real values are quite similar; weighting does not affect the estimated means. However, sampling errors are changed substan- tially when imputed values are added to real values to form an estimate. The weighted and unweighted simple random sampling standard errors are markedly smaller for all data than for the real data. To investigate whether this decrease in sampling error is caused by changes in sample size, changes in the element variance, or both, the element or total var— iances were estimated by multiplying the weighted simple random sampling variances by the sample sizes. Inspec- tion of Table IV suggests that the element variances are quite similar using all data and real data; the differ— ences in standard error when all data and only real 51 data are used can be attributed mostly to the loss in sample size when going from all data to real data. Not all of the real data were used as donors for imputation, and some of the real data were used as donors several times. Table IV also suggests that those real values not used as donors have a lower mean total charge than those used as donors, but values used as donors more than twice tend to have even smaller mean total charges. The means for donors used once, twice, or more frequently are a function of the use of imputation classes, within which the mean total charge and the amount of missing data varied. The difference in complex standard errors between all data and the real data in Table IV illustrates the large effects of imputation. However, neither the complex standard error computed using all the data nor that com- puted using only the real data is the correct standard error for the weighted mean estimated using all the data. The mean computed using all data includes 4,841 values that were actually subsampled with replacement from the 4,688 real values. In addition, imputations were made across the primary sampling units and strata used in both the sample selection process and the variance esti- mation procedure. It is assumed in the variance estima- tion procedure that the observations were selected inde- pendently from primary sampling units and strata. That assumption is incorrect in this case. Hence, the complex standard error for all data shown in Table IV fails to account for two sources of variability: the double sampl- ing used to select values for imputation and the correla- tion between primary sampling units and strata induced by imputation. At the same time, the complex standard error for the weighted mean computed using only the real data is an incorrect estimate of the standard error of the mean based on all the data. The actual sampling Figure II Estimated mean charges per hospital outpatient department visit, by 4 tamiy income classes tor all and real data: United States, 1980 65 — Data type I All 60 F. C] Fleal [C] 9 (V 8 55 - 'U E 8. a 50 *_‘ .C O C 8 45 H 2 40 —- 35 1 1 1 1 Lessthan $5,000- $12,000- $35,000 $5,000 $11,999 $34,999 or more Family Income 52 Figure Ill Estimated mean charges per hospital outpatient department visit, by 16 imputation classes for all persons and for persons in families with income less than $5, 000: United States, 1980 120 — Datatype .All 100 — 0 Family income 9 less than $5,000 I g, 1 g 80 I 6 I E I g 60 I a .C 0 E 40 (D 2 20 o llllllllllllllll 12 3 4 5 67 8 910111213141516 lmputation class error of the weighted mean for all the data is probably larger than that shown for the mean estimated using all the data; it may even be larger than the sampling error computed using only the real data. As a final illustration of the effects that imputation can have on survey results, Figure ll presents estimated mean charges per hospital outpatient department visit for four family income groups computed using all the data and using only the real data. For the real data, the mean charge per visit increases in a linear fashion as the family income increases. However, when all the data are used to estimate the mean charge per visit, the mean charge does not increase as rapidly with increas- ing family income. The strong relationship between fam- ily income and mean charge per hospital outpatient de— partment visit in the real data has been attenuated by the imputed values. The reason for this attenuation is shown in Figure [l]. Sixteen imputation classes were formed for the impu— tation of total charges for hospital outpatient department visits. Figure [11 shows mean charge by imputation class for real data for the total sample and for the subgroup with family incomes less than $5,000 in 1980. The low income group has lower mean charges than the total sample. Because family income was not one of the variables used to form imputation classes, low family income persons within an imputation class with missing hospital outpatient department visit total charges were imputed a charge that was, on average, higher than the mean charge for low income persons with real data. This occurs in almost every imputation class. When the real and imputed data are combined for persons with family incomes less than $5,000, the effect of imputation is to increase the mean charge for this subgroup. Conversely, for persons with family incomes of $35,000 or more, total hospital outpatient department visit charges for persons with real data tend to be larger than values imputed to persons with missing charges. The overall impact of the imputation process on the relationship between charges for hospital outpatient de- partment visits and family income is a regression toward the mean charge for real data for low- and high—income subgroups. The results in Tables III and IV and Figure II demon- strate the effect that imputation can have on estimated means, on estimated sampling errors, and on relation- ships between variables. Several strategies for handling imputation in estimation are suggested by these findings. It is beyond the scope of this discussion to evaluate various strategies and indicate the reasons why one was chosen for this report. The strategy used in preparing estimates for this report was to use all the data in all estimates despite the sizable effects caused by imputa- tion. This strategy means that estimated means and totals presented in the report have been adjusted for item nonre- sponse, but sampling errors and relationships among some variables may be adversely affected by the imputa- tion process. The reader should keep in mind that sam- pling errors for estimates that are subject to large amounts of item nonresponse may be underestimated, and the strength of relationships between a variable receiving imputed values and a variable that was not used to form imputation classes may be attenuated by the imputa- tion process. Estimation Procedures Sample estimators from the NMCUES data, regard- less of whether they are totals, means, medians, propor— tions, or standard errors, must account for the complexity of the sample survey design. Totals, means, and other estimates must include sampling weights to compensate for unequal probabilities of selection, nonresponse, and undercoverage. Stratification, clustering, and weighting must also be accounted for in the estimation of sampling errors. In addition, consideration must be given to time- adjustment factors to account for persons not eligible for the entire year and to imputations that were made to compensate for missing items. A variety of estimators were used for the descriptive analyses. To illustrate the role of time adjustments, con- sider the following six specific estimates that were used in the analysis: ° Estimated total charges for a selected subgroup (e.g. , persons with acute respiratory conditions). - Estimated total population. ° Mean charge per visit. 0 Mean charge per person. ° Proportion of charges that fall in a certain range of charges. ° Proportion of persons whose charges are less than or equal to a fixed level. To define these estimators, the following notation for these quantities for the ith person is used: y,- = total charges for health care in 1980; x,- = total number of medical visits for 1980; . w,- = nonresponse and undercoverage adjusted person weight; t,=time-adjustment factor (i.e., the proportion of days in 1980 that the person was an eligible member of the population); 1, if total charges are less than or equal to a fixed value, 0, otherwise; 1, if the total charge is between two fixed e,= values, 0, otherwise; and 1, if the ith person is a member of a desig- nated subgroup of the population, 0, otherwise. Estimating total charges, or any quantity from NMCUES that was recorded only during periods when the person was a noninstitutionalized civilian in the United States, is a relatively straightforward task requir- ing only a weighted sum of charge values. In particular, 5’: Ewiyisi is the estimated total charge for a particular service for a selected subgroup. On the other hand, for estimates of total population, a time—adjusted estimator is required such as y, = Ewiti6i . Thus, y" denotes an estimate of the 1980 average sub- group population, and y denotes the 1980 charges for a subgroup of the noninstitutionalized civilian popula- tion. Estimated means may or may not need to include a time-adjustment factor in the denominator. For exam- ple, to estimate the mean charge per visit during 1980, no time adjustment is needed. Hence, )7: zwiyi/Ewixi can be used to estimate mean charge per visit. However, to estimate mean charge per person, a time adjustment 53 is required in the denominator because the denominator is actually an estimate of the total average population in 1980. In particular, the estimator has the form )7, =2wiyi/2Witi- Estimates of mean charges for subgroups have a similar form, with the indicator variable 6,- included in the numerator and denominator for the appropriate subgroup of interest. Estimated proportions are means that have an indi- cator variable in the numerator and a count variable in the denominator. Proportions may have time adjust— ments not only in the denominator but also in the numerator. For example, to estimate the proportion of persons who had charges less than or equal to a fixed value, an estimate of the form 54 P, =2widiti/2witi was used. Appropriate indicator variables were added to the numerator and denominator to make estimates for selected subgroups. On the other hand, the estimated proportion of total charges between two fixed levels of charges does not require time adjustments in the numerator or the de- nominator. In particular, p=2wiyiei/2Wiyi is the estimated proportion of all charges for persons that occurred between two levels of charges. Appendix IV. Sampling Errors The NMCUES sample was one of a large number of samples that could have been selected from the US. civilian noninstitutionalized population using the same sampling procedures. Each possible sample could pro- vide an estimate that might differ from the same estimate from another sample. The variability among the estimates from all possible samples that could have been selected is defined as the standard error of the estimate, or the sampling error. The standard error can be used to assess the precision of the estimate itself by creating a confi- dence interval. For each interval, there is a specified probability that the average estimate over all possible samples selected from the population using the same sampling procedures will be in the interval. Preparation of sampling errors for every estimate in this report would be a sizable task, as would be presentation of sampling error estimates for every esti- mate. Rather than compute and display standard errors for every estimate in this report, standard errors were computed for a subset of estimates. A set of functions was fit to these estimated standard errors to identify a model that would allow computation of a standard error that would be reasonably close to the estimated standard error. This appendix provides summary formulas derived from the estimated standard errors that can be used to approximate the standard error for any given estimate in the report. The formulas have been designed to allow computation of an estimated standard error using an electronic calculator with basic arithmetic operators and a square root function. The computed estimate will be an average or smoothed estimate of the actual standard error of the estimate. The formulas for standard error estimates are pre— sented for three types of estimates found in the report: ' Totals or aggregates (e.g. , total charges for all health services used in 1980; total person years for males). ' Means (e.g., mean number of ambulatory visits; per capita charges for ambulatory visits). ' Proportions, percents, and prevalence rates (e. g., proportion of total charges paid out of pocket; percent of persons with hospital admissions; incidence rate of acute respiratory conditions for males 45—64 years of age). Comparisons can also be made between point esti- mates from two different subgroups of the population. Formulas are given for computing standard errors for two types of comparisons: ° Comparisons of two mutually exclusive subgroups (e.g., comparing mean number of ambulatory visits for males and females, male and female subgroups having no members in common). ' Comparisons between a subgroup and a larger group in which the subgroup is contained (e.g., comparing proportion of hospital stay charges paid out of pocket for the lower respiratory infection subgroup with those for all persons in the acute respiratory condition group). The standard error of a difference is based on the standard error of the totals. means, proportions, percents. or pre— valence rates of interest. Certain covariances between estimates, which typically are small relative to the stan- dard errors of the estimates themselves, are ignored. The standard errors calculated from the formulas in this appendix can be used to form intervals about which confidence statements can be made for estimates from all possible samples drawn in exactly the same way as NMCUES was. The confidence level is deter- mined by multiplying the estimated standard error by a constant derived from the standardized normal probabil— ity distribution. In particular, for the estimate 0 with estimated standard error 59, the upper limit for a (l -a) X 100 percent confidence interval can be formed by adding 2,1,2 times 59 to 0. The lower limit is formed by subtracting zwz times 39 from 0. The value of za,2 is obtained from the standard normal probability distribu- tion. For example, a 95-percent confidence interval cor- responding to a =0.05 can be formed with 20025 = 1.96; a 99-percent confidence interval (a=0.01) uses zolm5=2.346. Illustrations of these calculations are pro- vided in the discussion section for each formula. Confidence intervals for comparisons of estimates between two subgroups allow inferences to be made about whether the difference is statistically significant. If a (1 =a) X 100-percent confidence interval does not include the value zero, the difference is significantly different from zero. 55 Totals Let _\" denote the estimated total or aggregate for which a standard error is desired. The standard error for the estimate can be calculated by the expression 5,: [(1)7 + by]? where a and b are constants chosen from Table V for the particular estimate of interest. This formula was derived from a study of the relationship between the estimated total 1" and its standard error SE in which a parabolic or quadratic relationship was observed. As an illustration of the use of this formula. suppose that the standard error of the estimated value of lost productivity from colds is needed. From Table D, _\"= $2,309.000,000, the estimated total value of produc— tivity lost in I980 by persons with colds. Table V contains the coefficients for lost productivity, (1:11.593 and b = 9.1757 X 10 4. The estimated standard error is then computed as S~i‘v=[(ll.593)(23.09><10")+ (9. I757 x10 4)(23.09 x 10W] '3 = [(2.677X IO'”)+(4.892>< 1015)] ‘3 = 69.94().()()(). This estimated standard error for the total 1" can be used to create confidence intervals for the value of lost productivity for persons with colds. For example. a 68-percent confidence interval is obtained by adding and subtracting the standard error from the estimate. In this case. in 68 out of 100 samples drawn exactly in the same way as in NMCUES. the estimated value of lost productivity for persons with colds will range from $2,239,000.000 to $2,379,000,000. Similarly, a 95-percent confidence interval can be obtained by adding and subtracting from the estimate 1 .96 times the standard error. Thus, for 95 of 100 samples drawn in the same way as in NMCUES, the estimated value of lost produc— tivity for persons with colds would be from $2,l72,000,000t0 $2,446,000,000. Table V Coefficients for standard error formula tor estimated aggregates or totals, by estimator Coefficient Estimator a b Person years ............... 3.0476 x 104 4.7081 x 10 4 Charges ................... 1.0986 x 108 4.5524 x 10 “ Lost productivity and value of lost productivity ...... 1.1593 x 10‘ 9.1757 x 10 " Visits, prescription acquisitions, or disability days ............ 4.6408 x 102 5.7634 x10 ‘ 56 Means A large number of means for different types of meas- ures are presented in this report. Despite the variety of measures presented, a single formula is recommended for calculating an estimated standard error for a mean. The formula given here is based on the assumption that the standard error of the mean is determined by two quantities. the population variance and the effect of the sample design on the variances. The population variance for weighted survey data with weights w,- is estimated as ‘V Ew,(_v,—_V)3 § . E," where y, denotes the value of the characteristic Y for the ith sample person, and y" is the weighted sample mean. The effect of the sample design on the variance of a sample mean is called the design effect, or “deft“ (Kish, 1965), and is often expressed as deff= [i + [tn/a) — l] rah], where a is the number of clusters in the sample design and rah is a measure of within—cluster similarity among observations from the same cluster. The estimated standard error for a mean .\" can be calculated as 32 i: s. : [deif- . J - n Ii 5‘: '3 : “:1 + [‘1,795,637 — l] rah] {I :l ‘ where Ii is the estimated population total for the subgroup under consideration and l,795,637 represents the number of clusters ((12138) times the average basic person weight. Consequently, Ii/l,795,637 is an estimator for n/a in the expression for deff. The values of wk and 3‘3 for a variety of means appearing in this report can be obtained from Table VI. The table provides. for exam- ple, values of roh and 3'2 for mean charges and mean utilization measures of various types. As an illustration. consider the standard error of the mean number of ambulatory visits for persons with colds. From Table E, for persons with colds y=5.9. and from Table VI, under the entry “Mean visits per person, Ambulatory visits," the values r0h=0.048246 and 53: 1.6398 x 10" are obtained. There were an estimated ri=57,638,000 persons with colds in 1980 (Table A). Substituting these values into the expression forSf, Table VI Values for rob and :2 for standard error formula for estimated means, by estlrnator ’ 1,795,637 . 1.6398 ><106 v2 57,638,000 [1 + (32.099 — 1)(0.043246)] (0.028450) “2 Estimator roh $2 Estimator rah 52 Mean charges per person Mean charges per visit All charges: A" Cha'9933 . _ Ambulatory visits .............. 0.029644 2.4952 x 109 Ambu'a‘O'Y V's“ -------------- 0-018777 37590 X 107 Hospital stays .............. 0029644 61652 X 1010 Hospital stays ................ 0.018777 8._4926 X 10“ Physician visits .............. 0.029644 6.1914 x 108 Physician visits ............... 0.018777 2.4686 x 107 Total ..................... 0.029644 7.2407 x 1010 Emergency room visits ......... 0.018777 9.7896 x 108 Emergency room Visits ......... 0.029644 9.9816 X 107 Prescribed medications ......... 0.018777 6.7348 X 105 Prescribed medications ......... 0.029644 9.6458 x 107 mag” Pa'd 090‘ 900““ Hospital outpatient visits ........ 0.031367 7.6646 x 10° Amblf'awry V'S"S -------------- 0-018777 8-8152 X 10? Independent provider visits ...... 0.031367 2.6559 x 107 “059"?" SPY? ---------------- 0018777 9-4993 X ‘0 ° Hospital outpatient visits PhySICIan VISIts . .'. . ........... 0.018777 9.2576 x 106 (nonphysician provider) ........ 0.031367 4.2419 x 10" Emergency room W?“ -------- 0018777 1-1 109 X 108 Physician visits Prescribed medications ......... 0.018777 7.8309 x 105 . . - 7 Ogggpgyzlman prov1der) ........ 0.031367 5.3375 x 10 Mean visits per user other medical expenses ....... 0.031367 8.8305 x 107 Ambulatory visits --------------- 0-048246 1-4117 X 106 Charges paid out of pocket: Hospital stays .................. 0.048246 4.3009 x 103 Ambulatory visits ______________ 0.029644 24323 x 108 Physician visits ................. 0.048246 4.4788 X 105 Hospital stays ................ 0.029644 2.4068 x 109 Emergencv room visits ----------- 0.048246 7.9937 x 103 physician visits _____________ 0.029644 10745 x 108 Prescribed medications .......... 0.048246 1 .3402 X 106 Total ....................... 0.029644 3.5873 x 109 , , Emergency room visits ......... 0.029644 1.0038 x 107 Mean V'S'L“ 9‘" Dem" Prescribed medications ......... 0.029644 4.5416 x 107 Ambulatory visits --------------- 0048246 1.6398 x 106 Hospital outpatient visits ........ 0.031367 8.6571 x 106 Hospital stays ------------------ 0048246 1.0029 x 10‘ Independent provider visits ...... 0.031367 2.4996 x 108 Physician ViSilS ----------------- 0.048246 55650 X 105 Hospital outpatient visits Emergency room visits ........... 0.048246 1.6024 x 10‘ (nonphysician provider) ........ 0031357 25341 x 107 Prescribed medications .......... 0.048246 1.6651 x 106 Physician visits ‘ (nonphysician provider) ........ 0.031367 6.7847 x 10° Mean Percem Pa'd 0‘" 0‘ PW“?t Dental and Ambulatory visits ............... 0.051674 2.3071 x 103 other medical expenses ....... 0.031367 3.8943 x 108 Hospital stays .................. 0.011724 1.7959 x 102 Prescribed medications .......... 0.056569 2.7935 x 103 Mean charges per user Dental and other Allcharges: medical expenses .............. 0.053301 2.6150 x 103 Ambulatory visits .............. 0.043633 3.0423 x 109 _ 5 Hospital stays ................ 0.0 43633 3.0044 x 1011 Mean length of hospital stay ....... 0.013098 8.5018 x 10 Physician visits ............... 0.043633 1.1955 x 109 Mean bed-dlsablllty days ......... 0.023772 7.6885 x 10‘5 Total ...................... 0.043633 8.7587 x 1010 Mean work-loss days ............ 0.026868 5.2013 x 106 Emergency room visits _________ 0.043633 3.3067 x 108 Mean restricted-activity days ...... 0.058349 3.4354 x 107 Prescribed medications ________ 0.043633 12535 x 108 Mean functional limitation score . . . . 0.050066 4.9489 x 10‘ Charges paid out of pocket: Mean-number 0i 6 Ambulatory visits .............. 0.043633 2.9046 x 108 SU'Q'ca' P'°°edu'es ~~~~~~~~~~~~ °-° ”528 X 1° Hospital stays ................ 0.043633 1.6296 x 10‘° Physician visits ............... 0.043633 1.5871 x 10" Total ....................... 0.043633 5.3877 x 109 Emergency room visits ......... 0.043633 7.5825 x 107 Prescribed medications ......... 0.043633 6.2806 x 107 = [(2.8146)(0.028450)]”2 S- = 1+ (—57’638’000 —1)(0.048246) = 0.26671 The standard error of the mean number of ambulatory visits for persons with colds is 0.27. Approximate confidence intervals may be con- structed for the population mean by adding to and sub- tracting from the estimated mean a constant times the estimated standard error. For example, to form a 95-per- cent confidence interval for the estimated mean number 57 of ambulatory visits for persons with colds, 1.96 times the estimated standard error (0.53) is added to and sub- tracted from the estimated mean y=5.9. In this case, the 95-percent interval ranges from 5.4 to 6.4. When the estimated sample size is about the same size as or smaller than the constant 1,795,637 in the standard error formula, the design effect effectively be- comes equal to 1. Thus, when fig 1 ,795,000, the design effect portion of the standard error formula is not neces- sary, and the estimated standard error can be calculated simply as 3;: [final/2, where s2 is again chosen from Table VI. For example, there are an estimated rt = 1,41 1,000 black persons with nasopharyngitis (Table 3). To estimate the standard error of the mean number of ambulatory visits for these persons in 1980 ()7 = 9.5 visits from Table 3), the value 52: 1.6398 x 10" is obtained from Table VI as before, and S _ 1.6398 x106 “2 -"’ _ 1,411,000 = 1.0780. To form an approximate 95-percent confidence interval for the mean visits, 1.96 times the standard error (2.1) is added to and subtracted from the estimated mean, y=9.5. The 95-percent interval thus ranges from 7.4 to 11.6 visits. Proportions, Percents, and Prevalence Rates The standard error of a proportion is computed using a formula similar to that recommended for the standard error of a mean. Let [3 denote the estimated proportion for which a standard error is needed. The standard error forp‘ is calculated as . 13,012,3(1—15) I“2 n 5,; =| [1 + [m- llroh]—»—' . where r“: is the estimated sample size on which the pro- portion is based, roh is a value selected from Table VII, and the constant 13,012 is the average time-adjusted weight for all persons in the sample. For proportions, the population variance can be estimated simply as §2=15(1 -13), and hence can be estimated directly from the sample proportions themselves (i.e., no value of s2 is needed in Table VII). The design effect, the ratio of the actual sampling variance for the estimated proportion to the var- 58 Table VII Values of roh for standard error formula for estimated proportions, by estimator Estimator roh Person years ................................ 0.069992 Charges .................................... 0.041917 Charges paid out of pocket ...................... 0.019816 Visits ....................................... 0.084014 iance that would be achieved for a simple random sample of the same size, is calculated for proportions in the same way as it was calculated for means. As an illustration of the use of the formula for S,,, consider obtaining the standard error for the proportion of all charges for hospital inpatient care for all persons with acute respiratory conditions during 1980 (Table J), 41.5 percent of all charges. To calculate the standard error for percents, the same formula can be used as for proportions after the percent has been divided by 100. Thus, fi=4l.5+100=0.415. There are an estimated ri=73,899,000 persons in the category (Table J), and roh =0.041917 is obtained from Table VII. Substituting these values into the formula for Sfi, SI, : 1 + (W— 1)(0.041917) 1,795,637 I a . 13,012(0.415)(1— 0.415) 73,899,000 3,159.0 73,899,000 [1 + (40.155)(0.0419l7)] [(2.6832)(4.2747 x 10—5)] 1 3 0.010710 Because S I? = 0.010710 is the estimated standard error for the proportion p‘ = 0.415, simply multiply S,3 by 100 for a standard error of 1 .0710 for the percent 41 .5. An approximate 95-percent confidence interval for the percent can now be calculated by adding to and sub- tracting from the estimated percent 1.96 times the esti- mated standard error. In this case, the 95-percent interval ranges from 39.4 to 43.6 percent of all charges for per— sons with acute respiratory conditions for hospital inpa- tient care. When the estimated sample size is less than or equal to 1,795,637, the design effect is close to 1 and the for- mula can be simplified to _ 13,012,;(1—p) “2 5,,— fi— , as described for the standard error of a mean in the previ- ous section. For example, 17.5 percent of visits for per— sons 12—17 years of age with otitis media were for otitis media conditions (Table 5). For the ri=998,000 esti- mated persons in this subcategory, the standard error of the proportion associated with this percent is estimated as [13,012-(0.175)(1 —0.175) ]”2 = 0.043386. 998,000 A 95-percent confidence interval for the estimated per- cent is calculated by multiplying this estimated standard error by 100-(1.96)= 196 and adding the result to and subtracting the result from the percent. Thus, the 95-per- cent interval ranges from 9.0 to 26.0 percent. The same procedure can be used to calculate standard errors for prevalence rates. Prevalence rates are handled in the same way as percents are except that the rate is divided by 1 ,000 rather than 100 to obtain a proportion to use in the formula. For example, to obtain the esti- mated standard error for the prevalence rate for acute respiratory conditions in Table A (a rate of 504.0 per 1,000 person years), divide the rate by 1,000 (504.0/ 1,000 = 0.504) and observe that ii = 222,824,000 (all per- sons) and r0h=0.069992 from Table VII for person years. The estimated standard error can be calculated for this prevalence rate as 5. l’ = l} + (222,824,000 — l)(0.069992) 1,795,637 1/2 13,012-(0.504)(1—0.504) 222,824,000 1/2 = [D +(123-09)(0.069992)] 23%] 1/2 = E9.6155)(1.4598 X 105)] = 0.011848. This standard error is multiplied by 1 ,000, and the 95-per- cent confidence interval for the estimated prevalence rate ranges from 480.78 to 527.22 per 1,000. Mutually Exclusive Subgroup Differences Many comparisons between the same estimate for two different subgroups in the population are made in this report. Let d= 19. — 192 denote the difference between two subgroup estimates where 19, and 62 are the estimates for the two subgroups. For example, suppose that the incidence of acute respiratory conditions per 1 ,000 males is to be compared with the rate per 1,000 females (Table 1). Then 6,: —p,= 04703 for males, 02=p2=O. 5354 for females, andd= p.— p2: —0. 0651 The standard error of this difference IS computed as 5,: 153, +5421”, where 501 and S32 are the estimated sampling variances for 6I and 192, respectively (This formula ignores the non- zero covariance between 61. and 02 that arises in complex samples such as NMCUES. This covariance is typically positive and small relative to the variances themselves. Ignoring the covariance will result in standard errors for differences that are on average somewhat larger than the actual standard errors.) From Table l, ‘ = 107,481 ,000 and 112: 115,344,000; from Table VI, roh 20.069992. Hence, 3,: [1+1 107.481 _ l)(0.069992) 1,795,637 . l3,012(0.4703)(1 —0.4703) '3 107,481,000 = 0.012426 and $1 2 1H 115,344,000 _ '2 1,795,637 l)(0.069992)] 13,012(0.5354)(1 — 0.5354) “2 115,344,000 = 0.012339. Therefore, the standard error of the difference is com- puted as 5,]: [(0012426)2 + (0.012339)2]“2 = 0.017512. This standard error can be used to form an approxi- mate confidence interval for the difference in the same manner as described previously for estimates of totals, 59 means, proportions, and percents. In this instance, the 95-percent confidence interval for the difference in inci— dence rates per 1,000 population is from 30.8 to 99.4. Since this interval does not include the value zero, it can be concluded with 95-percent confidence that incidence rates for females are higher than those for males. In other words, the chances are only 5 in 100 that the difference over a large number of identical surveys will be equal to zero. Subgroup to Total Group Differences Another type of comparison made in this report is be- tween an estimate for a subgroup and the same estimate for a group that contains the subgroup. Let d= 6,- 6T denote the difference between a subgroup estimate and the estimate for a group in which the subgroup is con- tained, where 6, is the subgroup estimate and 67 is the es- timate for the larger group. The standard error of this dif- ference is computed as 54:59.11 — (in/11TH“. where Sgl denotes the standard error of the estimator 6. and f1l and it, denote the estimated sample sizes for the subgroup and for the larger group, respectively (This for- mula is based on an assumption that the covariance be- tween 6l and 61 IS the same as the variance of 6., i. e. 59'. This assumption results in an estimated standard error for the difference that is on average somewhat larger than the actual standard error.) For example, suppose that the standard error of the difference between per capita surgical charges for per- sons with acute respiratory conditions and per capita surgical charges for all persons is needed. From Table G, 6‘ =y'.=$1,429 and, 6T=yT=$2,082. From Table A, fl. = 1 12,302,000, and r17: 222,824,000. Using the for- mula for estimating the standard error of the mean and values from Table VI under “Mean charges per visit, All charges, Hospital stays, and Surgery” (i.e., s‘2 = 8,4926 X 10” and roh = 0.018777), 3,! 112,302,000 ] 1 + *— |[ ( 1,795,637 l)(0.018777) 8,4926 X 10‘l ”2 112,302,000 127.68. Hence, the standard error of the difference, d = $1,429 - $2,082 = — $653, is computed as SJ: l27.68[l —(l l2,302,000/222,824,000)]U 2: 89.922. A 95-percent confidence interval can be constructed for the difference by adding to and subtracting from the estimated difference 1.96 times the estimated standard error of the difference. In this instance, the 95-percent confidence interval is from ~$477 to —$829. It can be concluded with 95-percent confidence that persons with acute respiratory conditions have lower per capita surgical charges than all persons because this confidence interval does not include zero. Appendix V. Definition of Terms Age—This is the age of the person as of January 1, 1980. Babies born during the survey period were included in the youngest age category. Ambulatory care visit—A direct personal exchange between an ambulatory patient and a health care provider is an ambulatory care visit. The visit may take place in the provider’s office, hospital outpatient department, emergency room, clinic, health center, or the patient’s home. Services may be rendered by a physician, chiro- practor, podiatrist, optometrist, psychologist, social worker, nurse, or other ancillary personnel. Bed-disability day—A bed—disability day is one on which a person stays in bed more than half of the daylight hours because of a specific illness or injury. All hospital days for inpatients are considered to be bed-disability days even if the patient was not actually in bed at the hospital. Condition—Any entry on the questionnaire that de— scribes a departure from a state of physical or mental well-being is included. A condition is any illness, injury, complaint, impairment, or problem perceived by the respondent as inhibiting usual activities or requiring med- ical treatment. Pregnancy, vasectomy, and tubal ligation were not considered to be conditions; however, related medical care was recorded as if they were conditions. Neoplasms were classified without regard to site. Condi- tions, except impairments, were classified by type ac- cording to the Ninth Revision of the International Classi— fication of Diseases (World Health Organization, 1977) as modified by the National Health Interview Survey Medical Coding Manual; these modifications make the code more suitable for a household interview survey. Impairments are chronic or permanent defects, usually static in nature, that result from disease, injury, or con— genital malformation. They represent decrease or loss of ability to perform various functions, particularly those of the musculoskeletal system and the sense organs. Impairments are classified by using a supplementary code specified in the coding manual. In the supplemen- tary code, impairments are grouped according to type of functional impairment and etiology. Conditiomrelated disability day—Condition-related disability days include work-loss days, restricted-activity days, and bed-disability days for which the respondent listed the indexed condition as an underlying cause for staying home from work, cutting down on usual ac- tivities, or staying in bed. Condition—related visit or hospital admission—Am- bulatory visits or hospital admissions for which the re— spondent listed the indexed condition as an underlying reason for seeking medical services are classified as condition related. Disability—Disability is the general term used to describe any temporary or long-term reduction of a per- son’s activity as a result of an acute or chronic condition. Disability day—Short term disability days are classi— fied according to whether they are days of restricted activity, bed-disability days, hospital days, or work-loss days. All hospital days are by definition days of bed disability; all days of bed disability are by definition days of restricted activity. The converse form of these statements is, of course, not true. Days lost from work apply only to the working population. Work—loss days are also days of restricted activity. Hence, the restricted- activity day is the most inclusive term used to describe disability days. Education of head of family—The years of school completed by the head of family, if the family head was 17 years of age and over, is classified. Only years completed in regular schools, where persons are given a formal education, were included. A “regular” school is one that advances a person toward an elementary or high school diploma or a college, university, or profes— sional school degree. Thus, education in vocational, trade, or business schools outside the regular school system was not counted in determining the highest grade of school completed. Employed—An individual is classified as employed if he or she worked at any time in 1980. Family—A group of people living together and re— lated to each other by blood, marriage, adoption, or foster care status is considered a family. An unmarried student 17—22 years of age living away from home was also considered part of the family even though his or her residence was in a different location during the school year Family head—At the time of the first interview, the respondent for the family was asked to designate a “family head.” If no head was designated or this infor- mation was missing, a family head was imputed. Family income in l980—Each member of a family is classified according to the total income of the family of which he or she is a member. Because some persons changed families during the year, their family income 61 is defined as the income of the family they were a member of the longest. If a family did not exist for the entire year, the family income is adjusted to an annual basis by dividing actual income by the proportion of the year the family existed. Unrelated persons are classified according to their own income. For each per- son, 12 categories of income were collected, including income from employment for persons 14 years of age and over and income from various government programs, pensions, alimony or child support, interest, and net rental income. When information was missing, data were imputed. The total income of persons who were members of more than one family was allocated to each family in proportion to the amount of time they were in that family. Homemaker—An individual is classified as a home- maker if he or she did not work at all in 1980 (unemployed or not in the labor force) and claimed housekeeping as his or her main activity in 1979. Disabled homemakers are not included. (See “Unable to work for health reasons”) Hospital admission—This is the formal acceptance by a hospital of a patient who is provided room, board, and regular nursing care in a unit of the hospital. A patient admitted to the hospital and discharged on the same day is considered to have had a hospital admission. Also included is a hospital stay resulting from an emergency department visit. Household—Occupants of group quarters or of a housing unit that was included in the sample constitute a household. A household can comprise one person, a family of related people, a number of unrelated people, or a combination ofrelated and unrelated people. Housing unit—A group of rooms or a single room occupied or intended for occupancy as separate living quarters is a housing unit if the occupants do not live and eat with any other persons in the structure and if there was either direct access from the outside or through a common hall or there were complete kitchen facilities for the use of the occupants only. Key person—A key person was (1) an occupant of a national household sample housing unit or group quarters at the time of the first interview; (2) a person related to and living with a State Medicaid household case member at the time of the first interview; (3) an unmarried student 17—22 years of age living away from home and related to a person in one of the first two groups; (4) a related person who had lived with a person in the first two groups between January l, 1980, and the round I interview, but was deceased or had been institutionalized; (5) a baby born to a key person during 1980; or (6) a person who was living outside the United States, was in the Armed Forces, or was in an institution at the time of the round 1 interview but who had joined a related key person. Limitation of activity—A functional limitation score was developed for classifying limitation of activity. It ranges form 0, indicating no limitation of activity, to 62 8, meaning severe activity limitation, and 9, indicating death during the survey period. The functional limitation score was developed from responses to a battery of ques- tions designed to assess ability to perform various com- mon functions such as walking, driving a car, and climb- ing stairs. For NMCUES, these questions were asked of persons 17 years of age and over. Nonkey person—A person related to a key person who joined him or her after the round 1 interview but was part of the civilian noninstitutionalized population of the United States at the date of the first interview is considered nonkey. Patient—A person who is formally admitted to the inpatient service of a short-stay hospital for observation, care, diagnosis, or treatment is considered a patient. In this report, the number of patients refers to the number of discharges during the year, including any multiple discharges of the same individual from one or more short-stay hospitals. The terms “patient” and “inpatient” are used synonymously. Per capita charges—These charges were calculated by dividing the total charges by the number of people in the reference population. Perceived health status—This measure is the family respondent’s judgment of the health of the person com- pared with others the same age, as reported at the time of the first interview. The categories are excellent, good, fair, and poor. Prescribed medicine acquisitions—Each time a per- son had a prescription filled, regardless of whether it was an initial filling or a refill of a prescription, is included in the number of acquisitions. Prevalence of conditions—In general, prevalence of conditions is the estimated number of conditions of a specified type existing at a specified time or the average number existing during a specified interval of time—in the case of this survey, during 1980. Race—The race of people 17 years of age and over was reported by the family respondent; the race of those under 17 was derived from the race of other family members. If the head of the family was male and had a wife who was living in the household, her race was assigned to any children under 17 years of age. In all other cases, the race of the head of the family (male or female) was assigned to any children under 17 years of age. Race is classified as “white,” “black,” or “other.” The “other” race category includes American Indian, Alaskan Native, Asian, and Pacific Islander. The cate- gory “white and other” includes the categories “white” and “other.” Reporting unit—This is the basic unit for reporting data in the household component of NMCUES. A report- ing unit consists of all related people residing in the same housing unit or group quarters. One person could give information for all members of the reporting unit. Restricted-activity day—A restricted-activity day is one on which a person cuts down on his usual activities for the whole of that day because of an illness or an injury. The term “usual activities” for any day means the things that the person would ordinarily do on that day. A day spent in bed or a day home from work because of illness or injury is, of course, a restricted-ac- tivity day. Round—A round was the administrative term used to designate all interviews that occurred within a given period of time and that used the same instruments and procedures. Surgery—Surgery is a procedure involving incision and examination or removal of tissue for diagnostic or therapeutic purposes. Work—loss day—A work-loss day is a day on which a person did not work at his or her job or business because of a specific illness or injury. The number of days lost from work is determined only for persons 17 years of age and over who reported that at any time during the survey period they either worked at or had ajob or business. 63 NCIHE [Pmibflficmfifioms Avmfiflmflpflce fiflntrcoungglln @IP© Stemming; (Dedicate Accecountmfi Standing Order Accounts with the Government Printing Officenan easy way to order and receive all new publications from the National Center for Health Statistics. Vital and Health Statistics series Charge: CI ZHSl Program and Collection Procedures [3 ZHS2 Data Evaluation and Methods Research m. C] ZHS3 Analytical Studies CI ZHS4 Documents and Committee Reports C] ZHSS Comparative International Vital and Health Statistics Report . 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