The Development of a Patient-Reported Functional Limitations Index

We describe an easy-to-interpret, patient-reported Functional Limitations Index that can be used to monitor care of patients along the disability continuum.

ABSTRACT

Objectives: To develop an easy-to-interpret, patient-reported Functional Limitations Index (FLI) that can be used to assess and monitor the full spectrum of functioning in a community-dwelling population.

Study Design: Observational design using nationally representative survey data.

Methods: We used self-rated health as a criterion for empirically assigning weights to 5 National Health Interview Survey items assessing difficulty with seeing, hearing, walking, cognition, and self-care. In addition to succinctly summarizing cumulative limitations, we addressed 2 main questions: (1) Which limitations have stronger associations with self-rated health? and (2) How does severity (from 0, no difficulty, to 3, unable to do) relate to self-rated health? We generated a respondent-level summary score based on a model predicting self-rated health from the 5 linearly scored (0-3) items and used splines to account for nonlinear severity—self-rated health associations.

Results: The strongest association of specific functional limitations with self-rated health involved mobility; the weakest associations involved sensory limitations. The association of severity with self-rated health was nonlinear and largest moving from no difficulty to somewhat difficult. Nationally, 5% of noninstitutionalized adults were considered most limited, 8% somewhat limited, and 87% least limited. Great mobility limitations (defined as a lot of difficulty or unable to do) most distinguished limitation groups (present in 0% of least limited, 25% of somewhat limited, and 70% of most limited).

Conclusions: The FLI is an easy-to-administer, easy-to-interpret, and valid summary measure of disability that health plans and health care organizations can use for quality-of-care monitoring across a variety of settings to improve care for patients with disabilities.

Am J Manag Care. 2020;26(7):e225-e231. https://doi.org/10.37765/ajmc.2020.43765

Takeaway Points

The 5-item Functional Limitations Index is an easily administered and easily interpretable measure that distinguishes patients along the disability continuum (least to most limited).

The strongest associations of specific functional limitations with self-rated health involved mobility and self-care, possibly reflecting acute illness sequalae.
The weakest associations involved sensory limitations, possibly due to long-term adaptation through accommodations.
Greater severity was associated with worse self-rated health, with the largest increase from no difficulty to somewhat difficult, possibly reflecting challenging adjustment to new health problems.
Limitations groups were most distinguished by being unable to or having a lot of difficulty walking or climbing stairs.

An estimated 12% to 30% of Americans have a disability,^1-5 and prevalence is expected to increase.^6,7 In clinical populations, greater disability is associated with higher costs and lower quality of life.^8-11 There is a national commitment to improving the health and health care of persons with disabilities,^12,13 who make up one of the largest groups of underserved adults in the United States.¹⁴ This requires a consistent, efficient means of identifying and monitoring the spectrum of community-dwelling individuals with disabilities.

Some widely used measures of disability are used to classify working-aged adults as unable to work because of a health condition (eg, CMS original entitlement code); such measures do not capture individuals with disabilities who are able to work or who developed disabilities after age 65 years. Other measures involve a clinical diagnosis (eg, the Sheehan Disability Scale¹⁵) or are limited to 1 or 2 domains (eg, SF-36 Physical Function¹⁶ score of mobility), limiting their usefulness in the general population.

Responding to the need for a standardized, broadly applicable measure of disability,^17-19 a group of disability measurement experts developed the International Classification of Functioning, Disability and Health (ICF) to classify the consequences of disease and complement the International Classification of Diseases.^20-23 As shown in Figure 1,^24,25 functioning, defined here as activity limitations, results from dynamic interactions among health conditions, body function and body structure impairments, participation in social roles, and environmental and personal factors. The ICF model focuses on functioning independent of health condition.^23,26 For example, a patient with severe pain from a back injury and a patient with cerebral palsy may both have limited mobility, whereas a full-time student with depression may experience concentration limitations and a part-time worker with depression may not. The ICF model treats the first 2 people the same and the second 2 as distinct.

In this paper, we describe the development of a brief, easy-to-administer, and easy-to-interpret summary measure of patient functioning that health care organizations and providers can use to assess and monitor a wide spectrum of functioning independent of clinical diagnoses. In keeping with the ICF model, we focus on functional limitations independent of disease or condition. We considered only items in the 6-item Short Set of Disability Questions included in the National Health Interview Survey (NHIS) since 2010, as this measure was based on the ICF model.²⁷ This short set of questions reliably and validly²⁸ measures limitations associated with undertaking basic activities.²⁴ It represents the majority of individuals (but not all) with functional limitations and assesses the most frequently occurring (but not all) domains of functional limitation.²⁹

We describe an empirically informed method of combining the items in this set to preserve distinctions among different types and severities of functional limitations while maximizing the correlation to self-rated health. Typically, individuals are classified as having a disability if they have at least 1 serious functional limitation.^30,31 Another approach would be to classify individuals experiencing difficulty with at least 2 domains or activities of daily living as having a disability.³² Both of these dichotomous approaches ignore the possibility that the severity and different types of limitations may be associated with different levels of well-being and medical need.

Because the effect of a disability on well-being and medical need is likely to fall on a continuum, a continuous measure is needed to better capture the effect of disability and its severity, even if the continuous score is ultimately categorized for some purposes. One way to create a continuous measure is to count the number of limitations that a person reports³³; although simple, a count assumes that each functional domain implies the same level of medical need or requires the same degree of intervention. Alternatively, functioning domains could be weighted to reflect their associations with health, using published weights (eg, those used in the World Health Organization [WHO] Disability Assessment Schedule³⁴) or specific weights for the specific items in a given survey. For example, Altman and Bernstein¹ constructed a weighted summary measure of disability based on 8 functions from the 2001-2005 NHIS, based on untested assumptions about the relative effects of different functional limitations and levels of severity.

Here we describe the development and application of a weighted summary measure of functioning with empirically derived weights reflecting the association between several functional limitations and self-rated health. Self-rated health was chosen as a criterion variable because it predicts health care utilization, morbidity, illness recovery, functional decline, and mortality,^35-37 and because it is widely available in survey data. To inform our model, we addressed 2 questions: (1) Which limitations have stronger associations with self-rated health? and (2) How does the association of limitations with health vary by level of severity? Measuring the importance of severity in different patient functioning domains has practical clinical and policy implications for monitoring and improvement of quality of care.

METHODS

Data Source

Data are from the 2014-2015 NHIS Adult Functioning and Disability (AFD) supplement, fielded with the Sample Adult module to a randomly chosen subset of all sampled adults (18,303 in 2014 and 16,939 in 2015).

We excluded 1818 AFD respondents (5.2%) who were missing all 6 WHO functional limitation items. We imputed a 0 (no difficulty) for 91 (0.3%) respondents who completed some but not all functional limitation items, as it is common for respondents to misunderstand long sequences of similar items as a “check-all-that-apply” format.³³ Sampling weights incorporating study design and nonresponse were applied to all analyses, and robust variance estimation was used.

NHIS-AFD Items

The NHIS-AFD module includes the following 6 functional limitation questions: vision (difficulty seeing), hearing (difficulty hearing), mobility (difficulty walking or climbing steps), communication (difficulty communicating), cognition (difficulty remembering or concentrating), and self-care (difficulty washing all over or dressing). All items had response options of no difficulty (level 0), some difficulty (level 1), a lot of difficulty (level 2), and unable to do (level 3). We sought to create a brief index based on these 6 well-validated items.

Constructing a Summary Functional Limitations Score

We developed a linear regression model that predicted self-rated health from the functional limitation items. The final model retained 5 functional limitation items scored linearly (0-3). Communication was excluded from the final model because an initial model that included all 6 items yielded a coefficient for communication that did not significantly differ from zero (eAppendix A [eAppendices available at ajmc.com]). For each functional domain, we added a linear spline term that allowed the estimated difference between a lot of difficulty (level 2) and some difficulty (level 1) to differ from the estimated difference between no difficulty (level 0) and some difficulty (Figure 2; eAppendix B).

Covariate-adjusted self-rated health scores were estimated using recycled predictions.³⁸ The covariate-adjusted score is the expected self-rated health score for a given person if the person’s sociodemographic characteristics corresponded to those of the average person in the population. The coefficients of the functional limitations from the final model shown in Table 1 can be used to derive a predicted self-rated health score for every adult AFD respondent based on their self-reported vision, hearing, mobility, cognition, and self-care items (eAppendix B). We created a standardized (z score) score, the Functional Limitations Index (FLI), by subtracting the sample mean from each score and dividing the difference by the sample SD. The mean index score was 0 with an SD of 1. We classified respondents into 1 of 3 limitation groups based on the index scores. The cut points defining these groups were 1 SD apart on the index. Because the groups were meant to distinguish those with limitations, all cut points were below 0 (z score ≤ —2, most limited; z score > —2 to –1, somewhat limited; z score > —1, least limited). These cut points were selected to meet the potentially competing goals of having reasonably sized limitation groups (to ensure reliable subgroup estimates) and representing distinct levels of limitations. Most respondents were without limitations because the NHIS represents the general population. Respondents with no or very little limitation were assigned 0 or just above 0 scores. Although a small proportion of individuals with more limitations had large negative scores, there were no large positive scores; thus, the distribution of scores on the index is left-skewed.

As a preliminary validation and illustration of our approach, we compared the functional limitations and sociodemographic characteristics of the representative noninstitutionalized US adult population who were categorized as least limited, somewhat limited, and most limited per our FLI. We also determined which sociodemographic characteristics were associated with which limitation group using bivariate and multivariate logistic regression models to predict being classified somewhat limited vs least limited (referent) and most limited vs least limited.

RESULTS

Predicting Self-rated Health From Functional Limitations

Negative coefficients for each functional limitation indicated a negative association with self-rated health (0-100 scale, where 0 represented poor health and 100 excellent health). Each retained functional limitation main effect coefficient was negative and statistically significant (P < .05). The strongest predictor of self-rated health was mobility limitation (—15 points for each additional severity level), followed by self-care (–10 points), cognition (–7 points), vision (–5 points), and hearing (–3 points).

As a respondent moved from some difficulty to a lot of difficulty or from a lot of difficulty to unable to do, the negative association with functional limitations diminished (Figure 2). For example, a respondent with a single level 1 (some difficulty) mobility limitation was predicted to have a 15-point lower self-rated health score than those with no such limitation, but a respondent with a single level 2 (a lot of difficulty) mobility limitation was predicted to have one 22 points (—15 × 2 + 8) lower, and a respondent with a single level 3 (unable to do) limitation was predicted to have one 29 points (—15 × 3 + 8 × 2) lower. This means that the difference in quality of life between reporting no difficulty and some difficulty (15 points) was greater than the difference associated with reporting some difficulty and a lot of difficulty (7 points) or a lot of difficulty and being unable to do an activity (7 points). Although the association with self-rated health diminished with increased severity in general, the largest change in self-rated health associated with moving from a lot of difficulty to unable to do was for mobility and cognition.

Deriving Limitation Groups

We used the model predicting self-rated health to assign the FLI score and create 3 limitation groups: 5% of noninstitutionalized US adults, hereafter referred to as adults, were considered most limited (z score ≤ —2), 8% somewhat limited (z score > —2 and ≤ –1), and 87% least limited (z score > —1). As shown in Table 2, the proportion of adults with no limitations (no difficulty) ranged from 82% (for hearing) to 97% (for self-care). The proportion reporting great limitations (a lot of difficulty or unable to do) ranged from less than 1% (for self-care) to 6% (for mobility). Great mobility limitations most distinguished limitation groups: They were present in 0% of the least limited, 25% of the somewhat limited, and 70% of the most limited.

Distribution of the Number of Functional Limitations Among Limitation Groups

Table 3 presents the proportion of adults with any limitation or great limitations in none, 1, 2, and 3 or more areas of functioning, overall and by limitation group. Overall, 65% of adults had no limitations, 22% had 1 limitation, 9% had 2 limitations, and 4% had 3 or more limitations. About 75% of the least limited group had 0 limitations, 23% had a single limitation, and 2% had 2 limitations. Of the somewhat limited, 60% had 2 limitations, 30% had 1 limitation, and 10% had 3 or more limitations. Of the most limited, 62% had 3 or more limitations and most of the remainder (31%) had 2 limitations.

Overall, 8% of adults had at least 1 great limitation and 1% had 2 or more. Of the least limited, 2% had a single great limitation and the remainder had no great limitation. Of the somewhat limited, 31% had 1 great limitation and 2% had 2. Of the most limited, 76% had at least 1 great limitation, 14% had 2 great limitations, and 3% had 3 or more great limitations.

Distribution of Types of Limitations Among Limitation Groups

About one-fourth of the least limited had any functional limitations, most often some difficulty in a single area of sensory functioning (hearing or vision, 9%-13%), and rarely any mobility or self-care limitation (<5%). The somewhat limited all had at least 1 limitation, and most had 2 limitations (usually some difficulty but occasionally great limitation). A majority (96%) of the somewhat limited had mobility limitations; when a great limitation existed, it was usually in the realm of mobility. Approximately one-third or more of the somewhat limited group had a sensory limitation (33%-45% with any limitation) and rarely a self-care limitation (5%). A majority of the most limited had 3 or more limitations, including at least 1 great limitation. Nearly all (99%) of the most limited had mobility limitations; a majority had great mobility limitations along with cognitive, hearing, and vision limitations. More than half of the most limited group (60%-75% with any limitation) had a sensory limitation and approximately half (47%) a self-care limitation.

Sociodemographic Characteristics of the 3 Limitation Groups

Compared with the somewhat limited and most limited, the least limited were more often male, younger, and Hispanic or Asian and lived in the Northeast (eAppendix C). The least limited were more often married and socioeconomically advantaged; that is, they more often had a bachelor’s degree or more, reported an income of at least $75,000, and utilized private rather than public insurance.

DISCUSSION

The 5-item FLI is an easy-to-administer, easy-to-interpret, valid measure of functioning that health care organizations can use to identify and monitor the care and outcomes of individuals with disabilities of different severities independent of health conditions.

Our approach to scoring the FLI improves on other methods used to measure and summarize disability by utilizing patient function over clinical diagnoses and allowing empirical evidence to drive the weighting of different functional limitations and their severities for the summary score. By adjusting for sociodemographic characteristics, the FLI represents variation in health solely due to functional limitations; it can be used as a continuous measure of disability or to create limitation groups for analysis.

Interpretation of the FLI Model

Self-rated health has a strong negative association with each of 5 functional limitations, with mobility limitations having the strongest association, followed by limitations in self-care, cognition, vision, and hearing. Our results are consistent with those of Balestroni and Bertolotti,³⁹ who found that mobility was a stronger predictor of the EuroQol EQ-5D, a health-related quality-of-life measure, than self-care or daily activities limitations.

The disability paradox is the phenomenon wherein individuals with disabilities report greater well-being than unimpaired individuals assume they would experience in the same situation. In a 2014 survey, largely unimpaired community-dwelling adults cited vision loss as the limitation they believed would have the greatest effect on their day-to-day life, followed by memory loss; they ranked hearing loss as least likely to have a large effect.⁴⁰ Our finding that visual limitations are not strongly associated with self-rated health suggests that the disability paradox may be especially relevant for visual sensory limitation; the relatively small impact of hearing loss is consistent with unimpaired individuals’ assessment. The associations between sensory limitations (vision and hearing) and self-rated health may in part reflect long-term adaptation to accommodations (eg, eyeglasses and hearing aids). In contrast, mobility and self-care limitations may reflect acute illness sequelae, including physical deconditioning, early mortality, and falls resulting in loss of independence and ability to participate in social activities.^41-43 The large coefficients corresponding to a change from no limitation to some limitation may reflect the difficulty of adjusting to the new onset of a health problem, whereas the smaller coefficients corresponding to differences between some and great limitations may reflect some combination of worsening of an existing health problem and the success of environmental adaptations to functional limitations.

Limitations

This study has some limitations. Although the 6 NHIS functional limitation items are likely to capture most adults with disabilities, they probably underrepresent adults with psychiatric and cognitive disabilities associated with higher-order functioning limitations (eg, learning, decision making).⁴⁴ Mental health disability is potentially very important, especially among those who also report disability due to a chronic condition.⁴⁵ Information on US adults with intellectual disabilities is not routinely collected, despite recognized disparities in care.⁴⁶ We did not evaluate other ICF items (eg, anxiety, depression) given our interest in a function-based measure. The FLI does not distinguish between permanent and temporary disability.⁴⁷ Finally, although the construction of the FLI was supported by a strong theoretical foundation and the pattern of associations between limitation groups and sociodemographic characteristics provides preliminary evidence of the validity of the measure, additional validation work (eg, investigation of the convergent, discriminant, and predictive qualities of the index) is needed prior to any high-stakes application.

CONCLUSIONS

Policy makers and clinical researchers must understand how varying levels of disability influence quality of life. As individuals experience disability at higher levels of severity, the negative association between limitations and self-rated health increases, but to a diminishing extent. Dichotomous or summed counts of disability ignore this phenomenon. A key strength of the FLI is that because it empirically summarizes multiple functional limitation items and severity levels on the same ordinal scale as a single dimension, it can meaningfully facilitate research into variability in quality of and access to care by improving the insight into the relative contributions of different areas of functioning, severity, and additivity. The FLI may also help assess heterogeneity in disability-related disparities for different population subgroups. This method can be used as a guideline and be adapted to other populations of interest, such as Medicare or Medicaid beneficiaries. Policy makers might also find the FLI useful for assessing programmatic outcomes. For example, the association between disability and general health might be used to monitor change over time related to policy changes, such as the Americans with Disabilities Act, or programs, such as the Social Security Disability Insurance program.&ensp;

Acknowledgments

The authors would like to thank Biayna Darabidian for help with preparation of the manuscript.Author Affiliations: RAND Corporation, Santa Monica, CA (MM, DA, MNE, NO, MKB), and Pittsburgh, PA (SCM); American Hospital Association (PG), Chicago, IL; National Committee for Quality Assurance (JHN), Washington, DC.

Source of Funding: This research was supported by CMS contract HHSM-500-2016-00097G.

Author Disclosures: Mr Guerino received payment for involvement in the preparation of this manuscript while employed at CMS as part of his employment. The remaining authors report no relationship or financial interest with any entity that would pose a conflict of interest with the subject matter of this article.

Authorship Information: Concept and design (MNE, PG, MKB); acquisition of data (MNE, SCM, PG); analysis and interpretation of data (MM, DA, MNE, SCM, PG, MKB); drafting of the manuscript (MM, DA, PG, NO, JHN, MKB); critical revision of the manuscript for important intellectual content (MM, DA, MNE, SCM, PG, NO, JHN, MKB); statistical analysis (MM, DA); obtaining funding (MNE, SCM, NO, JHN); and supervision (MNE, SCM, MKB).

Address Correspondence to: Marc N. Elliott, PhD, RAND Corporation, 1776 Main St, Santa Monica, CA 90401. Email: Elliott@rand.org.REFERENCES

1. Altman BM, Bernstein A. Disability and health in the United States, 2001-2005. CDC. July 2008. Accessed March 2, 2019. https://stacks.cdc.gov/view/cdc/6983

2. Okoro CA, Hollis ND, Cyrus AC, Griffin-Blake S. Prevalence of disabilities and health care access by disability status and type among adults — United States, 2016. MMWR Morb Mortal Wkly Rep. 2018;67(32):882-887. doi:10.15585/mmwr.mm6732a3

3. Brault MW. Americans with disabilities: 2010. US Census Bureau. July 2012. Accessed March 2, 2019. https://www.census.gov/library/publications/2012/demo/p70-131.html

4. National Institutes of Health Medical Rehabilitation Coordinating Committee. National Institutes of Health research plan on rehabilitation. Am J Occup Ther. 2017;71(3):7103320020p1-7103320020p5. doi:10.5014/ajot.2017.713004

5. Oreskovich J, Zimmerman H. Defining disability: a comparison of disability prevalence estimates produced by BRFSS and other data sources. Montana Department of Public Health and Human Services. 2012. Accessed March 2, 2019. https://dphhs.mt.gov/Portals/85/publichealth/documents/BRFSS/Factors/2012Factor1.pdf

6. Iezzoni LI. Eliminating health and health care disparities among the growing population of people with disabilities. Health Aff (Millwood). 2011;30(10):1947-1954. doi:10.1377/hlthaff.2011.0613

7. Institute of Medicine. The Future of Disability in America. The National Academies Press; 2007.

8. Gyllensten H, Kavaliunas A, Alexanderson K, Hillert J, Tinghög P, Friberg E. Costs and quality of life by disability among people with multiple sclerosis: a register-based study in Sweden. Mult Scler J. 2018;4(3):2055217318783352. doi:10.1177/2055217318783352

9. Bernfort L, Gerdle B, Rahmqvist M, Husberg M, Levin LÅ. Severity of chronic pain in an elderly population in Sweden—impact on costs and quality of life. Pain. 2015;156(3):521-527. doi:10.1097/01.j.pain.0000460336.31600.01

10. Jones RW, Romeo R, Trigg R, et al; DADE Investigator Group. Dependence in Alzheimer’s disease and service use costs, quality of life, and caregiver burden: the DADE study. Alzheimers Dement. 2015;11(3):280-290. doi:10.1016/j.jalz.2014.03.001

11. Messali A, Sanderson JC, Blumenfeld AM, et al. Direct and indirect costs of chronic and episodic migraine in the United States: a web-based survey. Headache. 2016;56(2):306-322. doi:10.1111/head.12755

12. Office of the Surgeon General. Closing the Gap: A National Blueprint to Improve the Health of Persons With Mental Retardation. HHS; 2002.

13. Office of the Surgeon General. The Surgeon General’s Call to Action to Improve the Health and Wellness of Persons With Disabilities. Office of the Surgeon General; 2005.

14. Drum C, McClain MR, Horner-Johnson W, Taitano G. Health Disparities Chart Book on Disability and Racial and Ethnic Status in the United States. University of New Hampshire; 2011. Accessed March 2, 2019. https://iod.unh.edu/sites/default/files/media/Project_Page_Resources/HealthDisparities/health_disparities_chart_book_080411.pdf

15. Sheehan DV, Harnett-Sheehan K, Raj BA. The measurement of disability. Int Clin Psychopharmacol. 1996;11(suppl 3):89-95. doi:10.1097/00004850-199606003-00015

16. Ware JE Jr, Gandek B. Overview of the SF-36 Health Survey and the International Quality of Life Assessment (IQOLA) Project. J Clin Epidemiol. 1998;51(11):903-912. doi:10.1016/s0895-4356(98)00081-x

17. Disability & health related conditions. CDC. September 9, 2019. Accessed October 15, 2019. https://www.cdc.gov/ncbddd/disabilityandhealth/relatedconditions.html

18. Disability and health. Office of Disease Prevention and Health Promotion. Accessed January 8, 2020. https://www.healthypeople.gov/2020/topics-objectives/topic/disability-and-health/objectives

19. Madans JH, Altman BM, Rasch EK, et al. Washington Group position paper: proposed purpose of an internationally comparable general disability measure. National Center for Health Statistics. January 23, 2004. Accessed August 21, 2019. https://www.cdc.gov/nchs/data/washington_group/meeting3/WG_purpose_paper.pdf

20. Livermore G, Whalen D, Prenovitz S, Aggarwal R, Bardos M. Disability data in national surveys. August 25, 2011. Accessed August 21, 2019. https://aspe.hhs.gov/basic-report/disability-data-national-surveys

21. Gulley SP, Rasch EK, Bethell CD, et al. At the intersection of chronic disease, disability and health services research: a scoping literature review. Disabil Health J. 2018;11(2):192-203. doi:10.1016/j.dhjo.2017.12.012

22. Madans JH, Loeb ME, Altman BM. Measuring disability and monitoring the UN Convention on the Rights of Persons with Disabilities: the work of the Washington Group on Disability Statistics. BMC Public Health. 2011;11(suppl 4):S4. doi:10.1186/1471-2458-11-S4-S4

23. International Classification of Functioning, Disability and Health (ICF). World Health Organization. March 2, 2018. Accessed January 22, 2019. https://www.who.int/classifications/icf/en/

24. WG conceptual framework. Washington Group on Disability Statistics. February 15, 2016. Accessed May 18, 2017. http://www.washingtongroup-disability.com/methodology-and-research/conceptual-framework/

25. International Classification of Functioning, Disability and Health. World Health Organization; 2001. Accessed August 6, 2019. https://apps.who.int/iris/bitstream/handle/10665/42407/9241545429.pdf;jsessionid=8DF1B3BA5AB6539096DD8138F8E52177?sequence=1

26. Kostanjsek N. Use of the International Classification of Functioning, Disability and Health (ICF) as a conceptual framework and common language for disability statistics and health information systems. BMC Public Health. 2011;11(suppl 4):S3. doi:10.1186/1471-2458-11-S4-S3

27. Lauer EA, Henly M, Coleman R. Comparing estimates of disability prevalence using federal and international disability measures in national surveillance. Disabil Health J. 2019;12(2):195-202. doi:10.1016/j.dhjo.2018.08.008

28. Madans JH, Loeb M. Methods to improve international comparability of census and survey measures of disability. Disabil Rehabil. 2013;35(13):1070-1073. doi:10.3109/09638288.2012.720353

29. Rationale for the short set. CDC. November 6, 2015. Accessed January 8, 2020. https://www.cdc.gov/nchs/washington_group/wg_rationale.htm

30. Carroll DD, Courtney-Long EA, Stevens AC, et al; CDC. Vital signs: disability and physical activity—United States, 2009-2012. MMWR Morb Mortal Wkly Rep. 2014;63(18):407-413.

31. Courtney-Long E, Stevens A, Caraballo R, Ramon I, Armour BS. Disparities in current cigarette smoking prevalence by type of disability, 2009-2011. Public Health Rep. 2014;129(3):252-260. doi:10.1177/003335491412900307

32. Montez JK, Zajacova A, Hayward MD. Disparities in disability by educational attainment across US states. Am J Public Health. 2017;107(7):1101-1108. doi:10.2105/AJPH.2017.303768

33. Stevens AC, Courtney-Long EA, Okoro CA, Carroll DD. Comparison of 2 disability measures, Behavioral Risk Factor Surveillance System, 2013. Prev Chronic Dis. 2016;13:E106. doi:10.5888/pcd13.160080

34. Üstün T, Kostanjsek N, Chatterji S, Rehm J, eds. Manual for WHO Disability Assessment Schedule. World Health Organization; 2010. Accessed March 2, 2019. https://apps.who.int/iris/bitstream/handle/10665/43974/9789241547598_eng.pdf?sequence=1

35. Benyamini Y, Leventhal EA, Leventhal H. Self-assessments of health: what do people know that predicts their mortality? Res Aging. 1999;21(3):477-500. doi:10.1177/0164027599213007

36. Jylhä M. What is self-rated health and why does it predict mortality? towards a unified conceptual model. Soc Sci Med. 2009;69(3):307-316. doi:10.1016/j.socscimed.2009.05.013

37. DeSalvo KB, Bloser N, Reynolds K, He J, Muntner P. Mortality prediction with a single general self-rated health question: a meta-analysis. J Gen Intern Med. 2006;21(3):267-275. doi:10.1111/j.1525-1497.2005.00291.x

38. Graubard BI, Korn EL. Predictive margins with survey data. Biometrics. 2004;55(2):652-659. doi:10.1111/j.0006-341x.1999.00652.x

39. Balestroni G, Bertolotti G. EuroQol-5D (EQ-5D): an instrument for measuring quality of life. Article in Italian. Monaldi Arch Chest Dis. 2012;78(3):155-159. doi:10.4081/monaldi.2012.121

40. Scott AW, Bressler NM, Ffolkes S, Wittenborn JS, Jorkasky J. Public attitudes about eye and vision health. JAMA Ophthalmol. 2016;134(10):1111-1118. doi:10.1001/jamaophthalmol.2016.2627

41. Tiernan C, Lysack C, Neufeld S, Goldberg A, Lichtenberg PA. Falls efficacy and self-rated health in older African American adults. Arch Gerontol Geriatr. 2014;58(1):88-94. doi:10.1016/j.archger.2013.08.005

42. Liu PL, Cohen HJ, Fillenbaum GG, Burchett BM, Whitson HE. Association of co-existing impairments in cognition and self-rated vision and hearing with health outcomes in older adults. Gerontol Geriatr Med. 2016;2:2333721415623495. doi:10.1177/2333721415623495

43. Pinto JM, Wroblewski KE, Huisingh-Scheetz M, et al. Global sensory impairment predicts morbidity and mortality in older U.S. adults. J Am Geriatr Soc. 2017;65(12):2587-2595. doi:10.1111/jgs.15031

44. Mont D. Measuring disability prevalence. World Bank. March 2007. Accessed March 2, 2019. http://documents.worldbank.org/curated/en/578731468323969519/pdf/395080Disability0SP070601PUBLIC1.pdf

45. Mojtabai R. National trends in mental health disability, 1997-2009. Am J Public Health. 2011;101(11):2156-2163. doi:10.2105/AJPH.2011.300258

46. Krahn GL, Fox MH. Health disparities of adults with intellectual disabilities: what do we know? what do we do? J Appl Res Intellect Disabil. 2014;27(5):431-446. doi:10.1111/jar.12067

47. Ward B, Myers A, Wong J, Ravesloot C. Disability items from the current population survey (2008-2015) and permanent versus temporary disability status. Am J Public Health. 2017;107(5):706-708. doi:10.2105/AJPH.2017.303666