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. 2009 Sep 16;18(9):1239–1247. doi: 10.1007/s11136-009-9533-8

Measuring health-related quality of life in population-based studies of coronary heart disease: comparing six generic indexes and a disease-specific proxy score

Noelle C Garster 1, Mari Palta 1,, Nancy K Sweitzer 2, Robert M Kaplan 3, Dennis G Fryback 1
PMCID: PMC2759459  PMID: 19760103

Abstract

Purpose

To compare HRQoL differences with CHD in generic indexes and a proxy CVD-specific score in a nationally representative sample of U.S. adults.

Methods

The National Health Measurement Study, a cross-sectional random-digit-dialed telephone survey of adults aged 35–89, administered the EQ-5D, QWB-SA, HUI2, HUI3, SF-36v2™ (yielding PCS, MCS, and SF-6D), and HALex. Analyses compared 3,350 without CHD (group 1), 265 with CHD not taking chest pain medication (group 2), and 218 with CHD currently taking chest pain medication (group 3), with and without adjustment for demographic variables and comorbidities. Data on 154 patients from heart failure clinics were used to construct a proxy score utilizing generic items probing CVD symptoms.

Results

Mean scores differed between CHD groups for all indexes with and without adjustment (P < 0.0001 for all except MCS P = 0.018). Unadjusted group 3 versus 1 differences were about three times larger than for group 2 versus 1. Standardized differences for the proxy score were similar to those for generic indexes, and were about 1.0 for all except MCS for group 3 versus 1.

Conclusions

Generic indexes capture differences in HRQoL in population-based studies of CHD similarly to a score constructed from questions probing CVD-specific symptoms.

Keywords: HRQoL, CHD, Generic index, Disease-specific index, SF-36, SF-6D, HUI2, HUI3, QWB-SA, EQ-5D, HALex

Introduction

Cardiovascular disease (CVD) affects one-third of all adults or nearly 81 million individuals in the United States [1]. Coronary heart disease (CHD) is a substantial contributor to both morbidity and mortality from CVD. CHD leading to acute myocardial infarction (MI) remains one of the most common causes of hospitalization, disability, and death in the United States [1].

CHD or an MI has physical, emotional, and social consequences. As improvements in survival of ischemic events continue, researchers and clinicians acknowledge that subjective assessment of HRQoL is necessary as a complementary criterion for assessing prospective benefits of medical interventions [24]. Comparison of the impact of CHD with that of other conditions on the population level is clearly valuable for making public policy decisions incorporating cost-effectiveness [5, 6].

Population studies typically use generic HRQoL indexes [7]. It is not well known whether different generic indexes of HRQoL give consistent estimates of the impact of CHD. Some generic indexes such as the EuroQol EQ-5D (EQ-5D) and the Medical Outcomes Study Short Form-36 (SF-36v2™) have been found to be valid measures in patients with CHD [24, 810]. The EQ-5D, SF-6D, Health Utilities Index Mark 2 (HUI2) and Health Utilities Index Mark 3 (HUI3) have all been shown to be responsive to other chronic diseases in populations, such as rheumatoid arthritis [11, 12], type 2 diabetes [13], stroke [14], and intermittent claudication [15].

On the other hand, several instruments have been designed to specifically capture HRQoL with CHD or other cardiovascular conditions, and tend to be used in clinical populations [1618] and in clinical practice [8, 10]. Comparing the performance of generic indexes to a disease-specific instrument is of interest to physician researchers who may wish to incorporate the use of generic instruments to monitor HRQoL. There is some overlap in item content of CVD-specific instruments and generic indexes allowing investigators to potentially extract subsets of disease-specific questions to use as proxy disease-specific HRQoL indicators.

The objective of this study was to assess six widely used generic HRQoL indexes (the QWB-SA, SF-6D, EQ-5D, HUI2, HUI3, and HALex) as well as the physical (PCS) and mental health (MCS) subscales of the SF-36v2™ in a population-based sample in terms of the estimated differences in HRQoL between individuals with and without CHD and with varying CHD severity. We compare effect sizes to those of a proxy heart disease-specific index constructed from only CHD-relevant questions within the QWB-SA. A parallel sample of patients from three heart failure clinics allowed us to derive an equation to combine these questions to predict the CHD-relevant content of the Minnesota Living with Heart Failure Questionnaire® (MLHFQ) [16]. Comparison with a proxy score simulating a CVD-specific instrument provides a benchmark with which to compare the abilities of generic indexes. This comparison is valuable as clinicians will increasingly be graded on performance as judged by generic instruments [2].

Methods

Data collection

The National Health Measurement Study

The NHMS was a random-digit-dialed telephone interview of a sample of non-institutionalized U.S. adults, ages 35–89 years, living in the contiguous United States in 2005–2006 [19]. Five generic HRQoL instruments were administered in random order during the telephone interview: SF-36v2™ [20], the Health Utilities Index (HUI) [21, 22], EQ-5D [23], the Self-Administered Quality of Well-Being Scale (QWB-SA) [24], and the Health and Activities Limitations Index (HALex) [25].

Sampling was in three stages: sampling telephone numbers within telephone exchange strata, sampling an age-stratum within households, and sampling a single respondent from a selected age-stratum. Interviews were conducted in English by trained interviewers at the University of Wisconsin Survey Center using commercial computer-assisted telephone interview (CATI) software. All subjects provided verbal informed consent. The survey was approved by the Institutional Review Board at the University of Wisconsin (protocol #H-2004-0083).

A total of 3,844 participants completed the interview, representing an estimated response rate of 46%. For each participant, a sampling weight was computed based on the sampling design. Post-stratification was used to further adjust the weights for differential response rates by age, race, and sex. Fryback et al. [19] provide further details about the sampling techniques and weighting used for the NHMS.

Clinical Outcomes and Measurement of Health Study

A parallel study to the NHMS, the Clinical Outcomes and Measurement of Health Study (COMHS) was conducted at clinics for heart failure (HF) at the University of Wisconsin, University of California, San Diego and University of California, Los Angeles. Chronic heart failure cases newly referred to the clinics were eligible if the left ventricular ejection fraction was less than 50% for at least 3 months, as measured by echocardiography, radiographic ventriculography, or radionucleotide ventriculography. Furthermore, to be enrolled in the study, patients had to be at least 35-years old, able to provide competent informed consent, able to hear and understand verbal instructions in English, and have sufficient vision and ability in reading and writing English to complete the questionnaires. Data collected included the generic HRQoL instruments administered in the NHMS sample as well as the disease-specific MLHFQ. The instruments were distributed to participants in paper form in a packet assembled with the generic HRQoL questionnaires in randomized order, followed by the MLHFQ. Analyses include baseline data from 154 participants who completed the packet of questionnaires at the first clinic visit. The study was approved by the Institutional Review Boards at the University of Wisconsin (protocol #M-2005-1171) and the University of California.

Generic HRQoL measures

Scoring according to the guidelines specific to each instrument yielded the preference-scored indexes SF-6D (from SF-36v2™ [26]), HUI2 and HUI3 (from the HUI), EQ-5D, QWB-SA, and HALex [2125]. In addition, the physical and mental component scores (SF-36v2™ PCS and SF-36v2™ MCS, respectively) were computed from the SF-36v2™ [20]. For the preference-based indexes, HRQoL is measured by a single score anchored at dead (0.0) and full health (1.0) [27]. The EQ-5D, HUI2, and HUI3 allow for scores “worse than dead” with possible scores ranging from −0.11 to 1.0 for EQ-5D, −0.03 to 1.0 for HUI2, and −0.36 to 1.0 for HUI3 [23, 28]. The QWB-SA scores, excluding dead (0.0), can range from 0.09 to 1.0 [24], and SF-6D from 0.30 to 1.0 [26]. The HALex score can range from 0.10 to 1.0 [25]. PCS and MCS scores from the SF-36v2™ have a range of 0–100, with a mean score standardized at 50 and a standard deviation of 10 [20]. Fryback et al. [19] provided detailed descriptions of all instruments and established population norms for these generic indexes.

Definition of CHD subgroups

The NHMS telephone interview collected respondent-level information frequently associated with HRQoL including some details about eleven health conditions common in U.S. adults. CHD was self-reported via the question “Have you ever been told by a doctor or other health professional that you had coronary heart disease or a heart attack, also known as a myocardial infarction or MI?”

Three CHD severity subgroups were defined in the NHMS population as follows: (1) no self-reported CHD (n = 3,350), (2) self-reported CHD without current use of chest pain medication (n = 265), and (3) self-reported CHD with current use of chest pain medication (n = 218). Current chest pain medication use was self-reported via the question “Do you currently take medicine for chest pain?” Analyses exclude 11 who did not provide an answer to the CHD question.

Development of proxy score

CHD is a common cause of HF [29] and the conditions share symptoms. The item content of the MLHFQ emphasizes activity, mobility limitations, and worry and is similar to that of the Seattle Angina Questionnaire [17], but the latter contains several items related to chest pain. Conversely, two MLHFQ items were considered not to apply to CHD (items 1 and 14, see Table 1). Several generic indexes also contain items that resemble those in the MLHFQ (as displayed in Table 1). Table 1 shows the polychoric correlation in the COMHS sample between each ordinal MLHFQ item and its generic matches. For this and subsequent purposes, QWB-SA items, which asked whether a person had symptoms during the past 3 days were dichotomized into whether a person had the symptom at all (1) or not (0).

Table 1.

Individual items selected for analysis from generic HRQoL instruments

Minnesota Living with Heart Failure Questionnaire items Corresponding survey item from NHMS HRQoL instruments Polychorica correlation
Did your heart failure prevent you from living as you wanted during the past month by: Questions were chosen from SF-36, QWB-SA-SA, and EQ-5D HRQoL measurement instruments
1. Causing swelling in your ankles or legs? N/A to CHD
2. Making you sit or lie down to rest during the day? QWB-SA bed: Over the past 3 days did you spend all or most of the day in a bed, chair, or couch because of physical reasons? 0.56
3. Making your walking about or climbing stairs difficult? Does your health limit you in these activities? If so, how much?
SF 6: Climbing several flights of stairs? 0.65
QWB-SA walking: Over the past 3 days did you avoid walking, have trouble walking, or walk more slowly than other people your age? 0.73
4. Making your working around the house or yard difficult? QWB-SA limit work: Over the past 3 days because of any physical or emotional health reasons, on which days did you avoid, need help with, or were limited in doing some of your usual activities, such as work, school, or housekeeping? 0.53
5. Making your going places away from home difficult? Does your health limit you in these activities? If so, how much?
SF 10: Walking several hundred yards? 0.60
EQ5D1: Would you say you have no problems in walking about, some problems in walking about, or are you confined to bed? 0.61
6. Making your sleeping well at night difficult? QWB-SA sleep: On any of the past 3 days did you have trouble falling asleep or staying asleep? 0.63
7. Making your relating to or doing things with your friends or family difficult? SF 32: During the past 4 weeks, how much of the time has your physical health or emotional problems interfered with your social activities, like visiting friends, relatives, etc.? 0.67
8. Making your working to earn a living difficult? SF 16: How much of the time did you have difficulty performing your work or other activities (for example it took extra effort)? 0.58
9. Making your recreational pastimes, sports, or hobbies difficult? EQ5D3: Would you say you have no problems performing your usual activities, some problems performing your usual activities, or are you unable to perform your usual activities? 0.46
QWB-SA limit social: Over the past 3 days because of physical or emotional health reasons, on which days did you avoid or feel limited in doing some of your usual activities, such as visiting family/friends, hobbies, shopping, recreational, or religious activities? 0.55
10. Making your sexual activities difficult? QWB-SA sex: On any of the past 3 days did you have any decrease of sexual interest or performance? 0.73
11. Making you eat less of the foods you like? QWB-SA diet: On any of the past 3 days did you have to stay on a medically prescribed diet for health reasons? 0.43
12. Making you short of breath? QWB-SA breathing: On any of the past 3 days did you have shortness of breath or difficulty breathing? 0.78
13. Making you tired, fatigued, or low on energy? SF 29: How much of the time during the past 4 weeks did you feel worn out? 0.72
SF 31: How much of the time during the past 4 weeks did you feel tired? 0.77
14. Making you stay in a hospital? N/A to CHD
15. Costing you money for medical care? N/A
16. Giving you side effects from treatments? N/A
17. Making you feel you are a burden to your family or friends? SF 25: How much of the time during the past 4 weeks have you felt so down in the dumps that nothing could cheer you up? 0.57
18. Making you feel a loss of self-control in your life? QWB-SA no control: On any of the past 3 days did you have feelings that you had little or no control over events in your life? 0.71
19. Making you worry? QWB-SA worry: On any of the past 3 days did you have excessive worry or anxiety? 0.68
20. Making it difficult for you to concentrate or remember things? QWB-SA confuse: On any of the past 3 days did you have confusion, difficulty understanding the written or spoken word, or significant memory loss? 0.82
21. Making you feel depressed? SF 28: How much of the time during the past 4 weeks have you felt downhearted and depressed? 0.80

aQWB items are highlighted in italics, and were dichotomized into “occurred during the last 3 days” versus “did not occur during the last 3 days”

The QWB-SA had the largest number (11) of items matching the MLHFQ, all of which had polychoric correlation of >0.40 with the corresponding MLHFQ item. The MLHFQ total score was recomputed in the COMHS sample, without the two items deemed applicable only to HF, as the sum of the remaining items rescaled to the range of the original MLHFQ. The CVD-specific proxy instrument was developed by linear regression of this modified MLHFQ total score on the matched generic items from the QWB-SA. The resulting regression coefficients were used to create a scoring algorithm for the proxy score, shown in the following equation, where the predictors are individual item values from the QWB-SA items listed in Table 1. The equation lists the QWB-SA items in the same order as they appear in Table 1, where the complete wording of each item can be found.

graphic file with name M1.gif

The negative sign of the statistically non-significant coefficient of the QWB item measuring confusion is due to it having a negative polychoric correlation (−0.18) with reporting side effects from treatments (item 16) on the MLHFQ. The proxy score correlated with the modified MLHFQ at r = 0.82.

Statistical analyses

All analyses were performed using SAS version 9.0 software (The SAS Institute, Cary, NC). To produce nationally representative estimates of index means and differences, further analyses incorporated trimmed post-stratification sampling weights and accounted for telephone exchange strata.

Weighted means and standard deviations of the generic instruments and proxy score within CHD subgroups were computed. Higher scores indicate better HRQoL on the generic measures. As the CVD-specific proxy score was developed to resemble the MLHFQ, scoring is reversed for this index; so higher scores represent an increase in problematic symptoms and thus worse HRQoL. Both unadjusted and adjusted differences in mean scores were estimated and statistical significance of group differences assessed by F-tests implemented in SAS PROC SURVEYREG. Differences were first adjusted in a joint model across groups for age (as a continuous predictor), race (white, black, and other categories) and sex, and then additionally for arthritis, respiratory disease and diabetes (comorbidities that share symptoms with CHD). Group differences adjusted for these comorbidities were also obtained.

Standardized group differences were estimated from the means adjusted for age, race, and sex, and the residual standard deviation of the adjustment model. An effect size of 1 corresponds to a one standard deviation difference in magnitude. Guidelines for interpreting standardized differences are well established, with 0.2–0.5 representing a small effect size, 0.5–0.8 medium, and >0.8 large [30]. Weighted Pearson partial correlations, adjusted for age, race, and sex between the proxy score and the scores for all generic instruments were also obtained.

Results

The three CHD severity subgroups were described by unweighted statistics (Table 2). Mean scores for the proxy index and each of the generic indexes weighted to the U.S. population are also reported (Table 3). Those without CHD have the lowest proxy score, followed by those with only CHD and those with CHD plus chest pain medication use. This suggests that higher proxy scores reflect worse CVD-related health. All generic score means for respondents with CHD are lower than for those without CHD. Differences in unadjusted and adjusted mean scores between the three CHD subgroups were calculated (Table 4) and were significant for all indexes (P = 0.018 for SF-36 MCS, all others P < 0.0001). The minimally important difference is considered to be 0.03 for the EQ-5D, QWB-SA, HUI2, and HUI3, 0.033 for the SF-6D, and 5 for the SF-36v2™ MCS and SF-36v2™ PCS [31, 32]. Unadjusted and adjusted mean score differences for these generic indexes between all CHD severity subgroups exceeded clinically significant values, with the exception of the SF-36v2™ MCS. Differences between CHD subgroups 1 and 3 tended to be 2–3 times greater than the differences between CHD subgroups 1 and 2. Adjusted differences controlling for diabetes, arthritis, and chronic respiratory disease were smaller than unadjusted differences, but remain statistically and clinically significant.

Table 2.

Descriptive statistics for NHMS sample (unweighted)

No CHD CHD only CHD + meds
N 3,350 265 218
Mean age (SD) 58.9 (14.0) 69.9 (10.2) 68.9 (10.7)
Sex (%)
 Male 41.2 57.0 49.1
 Female 58.8 43.0 50.9
Race (%)
 White 66.2 75.9 62.4
 Black 28.8 20.4 30.7
 Other 4.5 3.4 6.9
Health conditions (%)
 Stroke 3.5 15.1 21.6
 Diabetes 16.1 30.2 46.8
 Arthritis 37.4 53.6 69.7
 Sleep disorder 8.1 13.6 22.0
 Chronic respiratory disease 15.3 21.1 32.1
 Thyroid disorder 11.7 14.7 17.4
 Chronic back pain 16.6 25.3 43.6
Depression (%)
 Clinical depression or anxiety 14.0 14.7 22.5
 Take depression/anxiety medication 8.7 8.7 16.5
Smoking (%)
 Ever smoked 50.8 66.8 67.0
 Currently smoke everyday 15.1 12.5 13.8
Cardiac treatment (%)
 Bypass surgery 28.3 33.0
 Coronary angioplasty 37.0 52.3

Table 3.

Mean HRQoL scores and standard deviations weighted to US population

Unadjusted No CHD CHD w/o meds CHD with meds
Mean SD Mean SD Mean SD
Proxy CVD score 32 11 37 13 45 16
EQ-5D 0.88 0.15 0.82 0.15 0.74 0.21
QWB-SA 0.66 0.14 0.58 0.14 0.52 0.14
HUI2 0.86 0.16 0.80 0.17 0.69 0.23
HUI3 0.82 0.23 0.75 0.25 0.56 0.35
SF-6D 0.80 0.13 0.75 0.13 0.67 0.15
SF-36 MCS 54 8.5 53 9.7 51 12.4
SF-36 PCS 50 9.0 44 10.6 35 11.8
HALex 0.82 0.19 0.68 0.23 0.50 0.24

Table 4.

Unadjusted and adjusted differences in mean scores between CHD groups

No CHD − CHD w/o meds (standard error) No CHD − CHD with meds (standard error) P valuec
Unadjusted
 Proxy CVD score −4.6 (1.1) −12 (1.7) <.0001
 EQ-5D 0.055 (0.013) 0.14 (0.022) <.0001
 QWB-SA 0.095 (0.013) 0.15 (0.015) <.0001
 HUI2 0.051 (0.017) 0.17 (0.024) <.0001
 HUI3 0.068 (0.024) 0.26 (0.039) <.0001
 SF-6D 0.048 (0.012) 0.13 (0.019) <.0001
 SF-36 MCS 0.59 (0.94) 2.9 (1.2) 0.018
 SF-36 PCS 6.2 (0.96) 15 (1.4) <.0001
 HALex 0.13 (0.023) 0.32 (0.027) <.0001
Adjusteda
 Proxy CVD score −5.7 (1.1) −13 (1.7) <.0001
 EQ-5D 0.047 (0.013) 0.12 (0.023) <.0001
 QWB-SA 0.077 (0.012) 0.13 (0.016) <.0001
 HUI2 0.050 (0.017) 0.16 (0.024) <.0001
 HUI3 0.065 (0.024) 0.25 (0.040) <.0001
 SF-6D 0.045 (0.012) 0.12 (0.020) <.0001
 SF-36 MCS 2.0 (0.95) 3.9 (1.3) 0.0024
 SF-36 PCS 4.2 (0.96) 13 (1.4) <.0001
 HALex 0.11 (0.024) 0.29 (0.028) <.0001
Adjustedb
 Proxy CVD score −5.2 (1.2) −9.2 (1.6) <.0001
 EQ-5D 0.038 (0.013) 0.084 (0.020) <.0001
 QWB-SA 0.069 (0.013) 0.088 (0.014) <.0001
 HUI2 0.038 (0.018) 0.12 (0.021) <.0001
 HUI3 0.047 (0.025) 0.19 (0.035) <.0001
 SF-6D 0.038 (0.012) 0.082 (0.017) <.0001
 SF-36 MCS 1.8 (0.97) 2.6 (1.3) 0.038
 SF-36 PCS 3.6 (0.90) 9.6 (1.2) <.0001
 HALex 0.098 (0.025) 0.21 (0.027) <.0001

aAdjusted for age, sex, and race

bAdjusted for age, sex, race, arthritis, respiratory disease, and diabetes

cP value by F-test across groups

Three effect sizes were calculated for each instrument: those with CHD without chest pain medications compared to those without CHD (subgroup 2 vs. 1), those with CHD using chest pain medications compared to those with CHD without chest pain medications (subgroup 3 vs. 2), and those with CHD using chest pain medications compared to those without CHD (subgroup 3 vs. 1). The effect sizes are shown in Table 5. The results show the HALex, the SF-36v2™ PCS and the proxy score to have the largest effect sizes in all comparisons, and the SF-36v2™ MCS to have the lowest. However, while the HUI2 and HUI3 differentiate next best between the CHD groups taking and not taking chest pain medication, the QWB-SA has a larger effect size between those with CHD without chest pain medication and those without CHD. All measures except the SF-36v2™ MCS have strong effect sizes between those with CHD taking chest pain medication and those without CHD.

Table 5.

Effect sizes between CHD severity groups

Index score Difference between CHD only and no CHDa Difference between CHD + meds and CHD onlya Difference between CHD + meds and no CHDa
Proxy CVD score 0.51 0.62 1.13
EQ-5D 0.32 0.52 0.84
QWB-SA 0.52 0.36 0.88
HUI2 0.31 0.72 1.03
HUI3 0.28 0.81 1.09
SF-6D 0.36 0.58 0.94
SF-36 MCS 0.24 0.22 0.45
SF-36 PCS 0.49 0.97 1.46
HALex 0.57 0.93 1.50

For effect size calculation, differences in mean HRQoL scores were standardized to population standard deviation among those without CHD from Table 4. Root mean squared error for model with index score as outcome and CHD group and adjustment variables (age, sex, gender) as predictors was used for standardization

aReference group

Partial correlations demonstrated that all of the generic indexes correlated highly with the CVD-specific proxy score, in both the NHMS sample as a whole and in a subgroup of only those with self-reported CHD (severity subgroups 2 and 3 combined) (Table 6).

Table 6.

Correlations between proxy score and generic indexes, partial on age, sex, and race

Index score All NHMS participants proxy score NHMS all CHD proxy score
EQ-5D −0.63 −0.65
QWB-SA −0.67 −0.76
HUI2 −0.69 −0.69
HUI3 −0.68 −0.69
SF-6D −0.62 −0.66
SF-36 MCS −0.51 −0.56
SF-36 PCS −0.57 −0.54
HALex −0.60 −0.55

Discussion

This study is the first to examine the abilities of six simultaneously administered generic instruments to detect HRQoL differences related to CHD in a cross-sectional, nationally representative sample of U.S. adults. The total scores for all indexes demonstrated ability to differentiate between individuals with and without CHD, and between CHD severity subgroups defined by self-reports of taking or not taking medication for chest pain. The generic indexes correlated highly with a proxy CVD-specific index. While the QWB-SA and SF-36v2™ appeared to have the greatest overlap of questions with heart specific instruments, it is worth noting these generic indexes did not display larger effect sizes than the other indexes. Notably, the HUI2, HUI3, and HALex have large effect sizes, and also correlate highly with the proxy index. It is likely that much of the equivalence between measures is caused not only by items that are explicitly similar, but also the fact that heart disease may cause many general health problems. Based on these findings, it appears that administering CHD specific instruments to general population samples will be of limited value. These findings may also be of interest to clinicians, as there is increasing interest in the administration of generic HRQoL indexes to monitor patients in the ambulatory setting [2]. Items within generic measures may offer much of the information captured by disease-targeted approaches. Generic measures might be adapted to offer both general and disease-specific assessment.

There is relatively little difference between the generic indexes in their sensitivity to CHD-related HRQoL. Effect sizes were of similar magnitude to that of the proxy score for the MLHFQ, even between severity subgroups 2 and 1. Much CHD in this lower severity group could be asymptomatic, and part of the effect on HRQoL may be through the diagnostic label itself. Part of the HALex total score is based on a self-reported health scale, while other indexes ask respondents to report functioning not feelings. This difference may be important for conditions that are serious but not associated with many symptoms. HUI3 and HUI2 have higher effect sizes and absolute differences with the CHD group taking chest pain medication, while QWB-SA has a greater effect size with the CHD group not taking chest pain medication. This finding is consistent with the HUI3 having large score decrements with health states at the lowest range of health, while the QWB-SA contains more items sensitive at the higher end of health.

The analyses presented in this study have limitations. One limitation is that the proxy CVD-specific index is not a validated, disease-specific instrument such as the Seattle Angina Questionnaire [17]. Although there is overlap in item content, questions in our proxy score are not as specific with respect to physical functioning with CHD as those in the Seattle Angina Questionnaire. Our score also does not contain questions specific to chest pain, which may have led to lower sensitivity to CHD.

Another limitation is that both CHD and current chest pain medication use were self-reported in the NHMS population, and the study design did not include verification of self-report with clinical records. The accuracy of self-report for MI was investigated by Heckbert et al. [33] in the Women’s Health Initiative Study, and good agreement was reported between self-report and physician review of medical records (kappa = 0.64). Specificity was very high at 99%, while sensitivity was lower at 64%. Based on this report, HRQoL differences in our study may be somewhat attenuated, as some individuals may have been diagnosed with CHD but did not report it and some patients with symptomatic CHD have not been diagnosed. Furthermore, some individuals may have reported chest pain medication use if they have a prescription for nitroglycerin, regardless of how often or infrequently they need to use it. Such circumstances would all lead to our effect sizes being underestimated, lending further support to the ability of the generic indexes to differentiate these CHD subgroups.

As with any data obtained via survey, differential participation and response rates between groups are a limitation. Telephone surveys are particularly limited, as calls are often screened and an increasing number of households rely only on cellular phones, which are not included in random-digit-dialed household sampling. However, it has been reported that in the time the NHMS survey was completed this seems to have had little effect on population health estimates [34]. Furthermore, as several different HRQoL indexes were administered, the length of the interview and the time required to complete it may have led to the selection of participants with higher education and/or better health. This would likely have resulted in underestimation of the differences in indexes between CHD subgroups.

Despite these limitations, our results contribute an important finding to the field of cardiovascular research. Generic indexes can capture differences in HRQoL between populations with and without CHD. These differences are similar to those detected by questions specifically targeted at cardiovascular disease, and appear to also be valid as an indication of disease severity within a CHD population.

Acknowledgments

The research was supported by grant P01-AG020679 from the National Institute on Aging.

Open Access This article is distributed under the terms of the Creative Commons Attribution Noncommercial License which permits any noncommercial use, distribution, and reproduction in any medium, provided the original author(s) and source are credited.

Abbreviations

HRQoL

Health-related quality of life

CHD

Coronary heart disease

MI

Myocardial infarction

CVD

Cardiovascular disease

HF

Heart failure

SF-36v2™

SF-36 Health Survey Version 2.0

MCS

Mental component score from SF-36 Health Survey Version 2.0

PCS

Physical component score from SF-36 Health Survey Version 2.0

EQ-5D

EuroQol group 5 dimension questionnaire, US English version

HUI2

Health Utilities Index Mark 2

HUI3

Health Utilities Index Mark 3

QWB-SA

Quality of Well-being Scale, self-administered version

HALex

Health and Activities Limitation Index

MLHFQ

Minnesota Living with Heart Failure Questionnaire

NHMS

National Health Measurement Study

COMHS

Clinical Outcomes and Measurement of Health Study

References

  • 1.American Heart Association. (2008). Heart disease and stroke statistics 2008http://www.americanheart.org. Accessed 30 March 2009.
  • 2.Nowels, D., McGloin, J., Westfall, J. M., & Holcomb, S. (2005). Validation of the EQ-5D quality of life instrument in patients after myocardial infarction. Quality of Life Research,31, 95–105. [DOI] [PubMed]
  • 3.Failde, I., & Ramos, I. (2000). Validity and reliability of the SF-36 Health Survey Questionnaire in patients with coronary artery disease. Journal of Clinical Epidemiology,53, 359–365. [DOI] [PubMed]
  • 4.Kiebzak, G. M., Pierson, L. M., Campbell, M., & Cook, J. W. (2002). Use of the SF36 general health status survey to document health-related quality of life in patients with coronary artery disease: Effect of disease and response to coronary artery bypass graft surgery. Heart & Lung,31(3), 207–213. [DOI] [PubMed]
  • 5.Puhan, M. A., Gaspoz, J. M., Bridevaux, P. O., Schindler, C., Ackermann-Liebrich, U., Rochat, T., & Gerbase, M. W. (2008). Comparing a disease-specific and a generic health-related quality of life instrument in subjects with asthma from the general population. Health and Quality of Life Outcomes, 6(15). [DOI] [PMC free article] [PubMed]
  • 6.Schlenk, E. A., Erlen, J. A., Dunbar-Jacob, J., McDowell, J., Engberg, S., Sereika, S. M., et al. (1998). Health-related quality of life in chronic disorders: A comparison across studies using the MOS SF-36. Quality of Life Research,7, 57–65. [DOI] [PubMed]
  • 7.Heo, S., Moser, D. K., Lennie, T. A., Zambroski, C. H., & Chung, M. L. (2007). A comparison of health-related quality of life between older adults with heart failure and healthy older adults. Heart & Lung,36, 16–24. [DOI] [PubMed]
  • 8.Dempster, M., & Donnelly, M. (2000). Measuring the health related quality of life of people with ischaemic heart disease. Heart,83, 641–644. [DOI] [PMC free article] [PubMed]
  • 9.Thompson, D. R., & Roebuck, A. (2001). The measurement of health-related quality of life in patients with coronary heart disease. Journal of Cardiovascular Nursing,16(1), 28–33. [DOI] [PubMed]
  • 10.Wolinsky, F. D., Wyrwich, K. W., Nienaber, N. A., & Tierney, W. M. (1998). Generic versus disease-specific health status measures. Evaluation & The Health Professions,21(2), 216–243. [DOI] [PubMed]
  • 11.Marra, C. A., Woolcott, J. C., Kopec, J. A., Shojania, K., Offer, R., Brazier, J. E., et al. (2005). A comparison of generic, indirect utility measures (the HUI2, HUI3, SF-6D, and the EQ-5D) and disease-specific instruments (the RAQoL and the HAQ) in rheumatoid arthritis. Social Science & Medicine,60, 1571–1582. [DOI] [PubMed]
  • 12.Hurst, N. P., Kind, P., Ruta, D., Hunter, M., & Stubbings, A. (1997). Measuring health-related quality of life in rheumatoid arthritis: Validity, responsiveness, and reliability of EuroQoL (EQ-5D). British Journal of Rheumatology,36, 551–559. [DOI] [PubMed]
  • 13.Maddigan, S. L., Feeny, D. H., & Johnson, J. A. (2004). Construct validity of the RAND-12 and Health Utilities Index Mark 2 and 3 in Type 2 diabetes. Quality of Life Research,13, 435–448. [DOI] [PubMed]
  • 14.Grootendorst, P., Feeny, D., & Furlong, W. (2000). Health Utilities Index Mark 3: Evidence of construct validity for stroke and arthritis in a population health survey. Medical Care,38, 290–299. [DOI] [PubMed]
  • 15.Bosch, J. L., & Hunink, M. G. M. (2000). Comparison of the Health Utilities Mark 3 (HUI3) and the EuroQol (EQ-5D) in patients treated for intermittent claudication. Quality of Life Research,9, 591–601. [DOI] [PubMed]
  • 16.Rector, T. S., Kubo, S. H., & Cohn, J. N. (1993). Validity of the Minnesota Living with Heart Failure Questionnaire as a measure of therapeutic response to enalapril or placebo. American Journal of Cardiology,71(12), 1106–1107. [DOI] [PubMed]
  • 17.Spertus, J. A., Winder, J. A., Dewhurst, T. A., Deyo, R. A., Prodzinski, J., McDonell, M., et al. (1995). Development and evaluation of the Seattle Angina Questionnaire: A new functional status measure for coronary artery disease. Journal of the American College of Cardiology,25(2), 333–341. [DOI] [PubMed]
  • 18.Thompson, D. R., & Yu, C. M. (2003). Quality of life in patients with coronary heart disease-I: Assessment tools. Health and Quality of Life Outcomes, 1(1). [DOI] [PMC free article] [PubMed]
  • 19.Fryback, D. G., Dunham, N. C., Palta, M., Hanmer, J., Buechner, J., Cherepanov, D., et al. (2007). U.S. norms for six Generic Health-related Quality of Life Indexes from the National Health Measurement Study. Medical Care,45(12), 1162–1170. [DOI] [PMC free article] [PubMed]
  • 20.Ware, J. E. (2000). SF-36 health survey update. Spine,25(24), 3130–3139. [DOI] [PubMed]
  • 21.Feeny, D., Torrance, G., & Furlong, W. (1996). Health utilities index. In B. Spilker (Ed.), Quality of life and pharmacoeconomics in clinical trials. Philadelphia, PA: Lippincott–Raven.
  • 22.Feeny, D., Furlong, W., Torrance, G. W., et al. (2002). Multiattribute and single-attribute utility functions for the Health Utilities Index Mark 3 system. Medical Care,40, 113–128. [DOI] [PubMed]
  • 23.Rabin, R., & de Charro, F. (2001). EQ-5D: A measure of health status from the EuroQol Group. Annals of Internal Medicine,33, 337–343. [DOI] [PubMed]
  • 24.Andresen, E. M., Rothenberg, B. M., & Kaplan, R. M. (1998). Performance of a self- administered mailed version of the Quality of Well-Being (QWB-SA) questionnaire among older adults. Medical Care,36, 1349–1360. [DOI] [PubMed]
  • 25.Erickson, P. (1998). Evaluation of a population-based measure of quality of life: The Health and Activity Limitation Index (HALex). Quality of Life Research,7, 101–114. [DOI] [PubMed]
  • 26.Brazier, J., Roberts, J., & Deverill, M. (2002). The estimation of a preference-based measure of health from the SF-36. Journal of Health Economics,21, 271–292. [DOI] [PubMed]
  • 27.Guyatt, G. H. (1993). Measurement of health-related quality of life in heart failure. Journal of the American College of Cardiology,22(4), 185A–191A. [DOI] [PubMed]
  • 28.Horsman, J., Furlong, W., Feeny, D., & Torrance, G. (2003). The health utilities index (HUI): Concepts, measurement properties and applications. Health and Quality of Life Outcomes, 1(54). [DOI] [PMC free article] [PubMed]
  • 29.Dhingra, R., Sesso, H. D., Kenchaiah, S., & Gaziano, J. M. (2008). Differential effects of lipids on the risk of heart failure and coronary heart disease: The Physicians’ Health Study. American Heart Journal,155(5), 869–875. [DOI] [PubMed]
  • 30.Cohen, J. (1988). Statistical power analysis for the behavioral sciences (2nd ed.). Hillsdale, NJ: Lawrence Erlbaum Association.
  • 31.Kaplan, R. M. (2005). The minimally clinically important difference in generic utility-based measures. COPD,2(1), 91–97. [DOI] [PubMed]
  • 32.Ware, J. E., Kosinski, M., & Keller, S. D. (1994). SF-36 Physical and Mental Health Summary Scales: A user’s manual. Boston, MA: Health Institute, New England Medical Center.
  • 33.Heckbert, S. R., Kooperberg, C., Safford, M. M., Psaty, B. M., Hsia, J., McTiernan, A., et al. (2004). Comparison of self-report, hospital discharge codes, and adjudication of cardiovascular events in the Women’s Health Initiative. American Journal of Epidemiology,160(12), 1152–1158. [DOI] [PubMed]
  • 34.Blumberg, S. J., Luke, J. V., & Cynamon, M. L. (2006). Telephone coverage and health survey estimates: Evaluating the need for concern about wireless substitution. American Journal of Public Health,96, 926–931. [DOI] [PMC free article] [PubMed]

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