You are here

  • Home
  • Archive
  • Volume 7, Issue 6
  • Factors predicting self-reported medication low adherence in a large sample of adults in the US general population: a cross-sectional study

Article Text

Article menu

This article has a correction. Please see:

Download PDFPDF

XML
Public health
Research
Factors predicting self-reported medication low adherence in a large sample of adults in the US general population: a cross-sectional study
  1. Michael Feehan1,2,
  2. Margaux A Morrison2,
  3. Casey Tak1,
  4. Donald E Morisky3,
  5. Margaret M DeAngelis2,
  6. Mark A Munger1
  1. 1The Department of Pharmacotherapy, College of Pharmacy, University of Utah, Salt Lake City, Utah, USA
  2. 2The Moran Eye Center, Department of Ophthalmology and Visual Sciences, Moran Eye Centre, University of Utah School of Medicine, Salt Lake City, Utah, USA
  3. 3Department of Community Health Sciences, UCLA Fielding School of Public Health, Los Angeles, California, USA
  1. Correspondence to Dr. Michael Feehan; mike.feehan{at}utah.edu

Abstract

Objectives The study objective was to determine the level and correlates of self-reported medication low adherence in the US general population.

Setting A 30 min cross-sectional online survey was conducted with a national sample of adults.

Participants 9202 adults (aged 18+) who had filled at least three or more prescriptions at a community pharmacy in the past 12 months.

Primary and secondary outcome measures Self-reported medication adherence was measured with the 8-item Morisky Medication Adherence Scale.

Results Low adherence was reported by 42.0%, 29.4% had medium adherence and 28.6% had high adherence. Low adherence was significantly associated with: lower age, being of Hispanic origin or African-American, having difficulty with healthcare, medication or transportation costs, needing the support of others to access primary care, health limiting activity, using multiple providers, infrequent visits to primary care providers and visiting an emergency department >3 times in last 12 months.

Conclusions A very high level of low medication adherence is seen in the general population, particularly for ethnic minorities, those who use multiple healthcare providers and those who experience barriers to access for regular primary care. As clinical, patient education and counselling, and healthcare policy initiatives are directed to tracking the problem of low medication adherence, these should be priority populations for research and interventions.

  • Adherence
  • Prescribing
  • Public health
  • Health behavior

This is an Open Access article distributed in accordance with the Creative Commons Attribution Non Commercial (CC BY-NC 4.0) license, which permits others to distribute, remix, adapt, build upon this work non-commercially, and license their derivative works on different terms, provided the original work is properly cited and the use is non-commercial. See: http://creativecommons.org/licenses/by-nc/4.0/

https://doi.org/10.1136/bmjopen-2016-014435

Statistics from Altmetric.com

    Request Permissions

    If you wish to reuse any or all of this article please use the link below which will take you to the Copyright Clearance Center’s RightsLink service. You will be able to get a quick price and instant permission to reuse the content in many different ways.

    Introduction

    Medication non-adherence is recognised as one of the most important and costly worldwide healthcare problems in the 21st century.1 The comprehensive 2003 WHO report on adherence to long-term therapies highlighted that: ‘Increasing the effectiveness of adherence interventions may have a far greater impact on the health of the population than any improvement in specific medical treatments’.2 3 In the USA, an estimated $100–290 billion in preventable costs can be realised by improving the estimated 30%–50% adult non-adherence rate to chronic medications.4 The Congressional Budget Office estimates that a 1% increase in the number of prescriptions filled by beneficiaries would result in a reduction of a fifth of 1% of total Medicare spending on services.5 The literature on the prevalence of non-adherence is challenging in that estimates vary widely by countries, the methodologies employed (eg, database abstraction from claims databases vs self-report through surveys) and the criteria used to define low adherence. There is a paucity of information on the overall prevalence and correlates of medication non-adherence as reported by patients themselves (across ethnic and socioeconomic groups), across conditions in the general US population.

    Adherence is determined by multiple inter-related factors. These include attributes of the patient, the patient’s environment (including social supports, characteristics and functioning of the healthcare system and the availability and accessibility of healthcare resources) and characteristics of the disease in question and its treatment.2 Estimates of the level of medication non-adherence and its correlates in the population can vary dramatically by the way non-adherence or low-adherence is defined and the data sources were used. Primary non-adherence (not picking up a prescription) can range from 7% to 17%6–8 and has been associated with a variety of patient characteristics (adjusted ORs up to 1.76) including: smoking tobacco, having five or more ambulatory healthcare contacts, ethnicity other than non-Hispanic white, having multiple comorbidities and a shorter time in health plan enrolment.6 Once patients have picked up an initial prescription, analyses of pharmacy refill data for chronic medications can indicate the level of adherence by tracking whether patients refill their prescriptions according to the designated schedule. In our previous studies of community pharmacy databases, using the medication possession ratio and proportion of days covered, we have found rates of satisfactory adherence (80% or more medication availability) for adults in community pharmacy dispensing databases of only 14%–16% for asthma, with women and older patients having greater satisfactory adherence,9 and in an older sample, only 30%–37% for eye-drop medications for glaucoma, which is a blinding disease.10 Determining the possible drivers and correlates of low adherence in such databases is challenging given the limited breadth of data available. A more patient-centric way to understand the predictors of low medication adherence is through comparisons of self-reported medication behaviour in association with patients’ self-described social, clinical and environmental factors. As patients tend to self-report higher rates of adherence, any associations between social factors and low adherence then are likely to be conservative. This approach provides healthcare providers with evidence-based factors that should be considered as they evaluate the potential for any one patient to have a lower likelihood of adherence to the regimen recommended.

    In order to gauge the level of self-reported medication adherence in the general population, this study surveyed a sample of over 9000 healthcare consumers. The study was designed to determine the degree of association between a range of potential correlates and self-reported medication low adherence, including age, ethnicity, income level, insurance availability, healthcare utilisation and barriers to healthcare access.

    Methods

    The population-based cross-sectional quantitative study used a 30 min online survey instrument (English language only) that was approved as exempt following applicable guidelines involving the ethical treatment of human participants by the University of Utah’s Institutional Review Board (IRB) before initiating data collection.

    Participants

    The sample comprised 10 006 adults (aged 18 years or older) recruited from an established nationally representative panel of individuals in the USA, who opted-in to be contacted for research purposes (Universal Survey Center, d/b/a SHC Universal New York, New York, USA). Panellists accessed the survey electronically through an invitation email and received a minimal honorarium for participation. Respondents were prescreened to meet the inclusion criteria: being an adult aged 18 years or older who had filled at least three or more prescriptions at a pharmacy in the past 12 months (no information on specific disease states the prescriptions were for, or the actual medications, was gathered). Patients with VA, CHAMPUS or TRICARE insurance or who received care through Kaiser, Kaiser Permanente, the Permanente or the Permanente Medical Group were excluded, given the unique nature of patient management in these systems. Between 27 August 2015 and 21 September 2015, the survey was opened to 15 572 eligible patients. However, the survey was purposely capped, and the survey was closed at 10 006 respondents (64.3% of those eligible). The data set was screened to remove those respondents giving non-sensical data (ie, not providing variation in answers, completing the survey in unrealistically short time and giving manifestly inconsistent responses), resulting in a final total of 9202 surveys for analysis (92.0% of the 10 006).

    Measures

    Medication adherence

    The NIH Adherence Network expert panel (2011) recommended the use of validated measures to assess adherence.11 Accordingly, self-reported medication adherence was measured using the eight-item Morisky Medication Adherence Scale (MMAS).12 This has been validated against other adherence sources such as pharmacy dispensing database fill data13 and is accredited/endorsed by the American Medical Association and American Pharmaceutical Association. It has been widely used in adherence research for multiple disease states and medications across numerous countries.14–17 In this study, the MMAS-8 was used to assess for self-reported low adherence in general and was not grounded in any specific conditions or medications. MMAS-8 scores can range from 0 to 8 with low adherence defined as a score <6, medium adherence as scores of 6 or 7 and high adherence with a score of 8.

    Demographic characteristics 

    The survey collected individual demographic characteristics including income level and insurance status, perceived level of health, healthcare access and utilisation, and perceived barriers to access including the presence or absence of health insurance. Individual age, gender and ethnicity were collected. Respondent income was categorised by thresholds established by the 2014 US Census Bureau and categorised as poverty, low income or not poverty or low income.18 19

    Health status

    Respondents rated their perceived general health on a five-point scale from ‘1’: poor, ‘2’: fair, ‘3’: good, ‘4’: very good and ‘5’: excellent. The degree to which the respondent’s health limited their activities was assessed as: ‘0’: No, Not at All, ‘1’: A Little or ‘2’: A Lot. Respondents had limited activity due to health if they responded with a 2 for either question, and ‘Not at All’ if they indicated 0 for both questions. All others were classified as health limiting their activities ‘A Little’. Health status was further evaluated by counting the number of health conditions respondents were diagnosed with within the past 12 months, including cancer, cardiovascular diseases, endocrine disorders, major mental health conditions, respiratory disorders, allergies or a self-described condition. The resultant comorbidity score ranged from 0 to 16.

    Barriers to access

    Respondents indicated the degree of difficulty they had in meeting healthcare costs related to primary care and the costs of prescription medications. They also indicated the degree to which transportation issues made it difficult to access primary care services they needed as well as the degree to which they needed the support of others at home to get the services they needed. These four items used a 1–10 scale where ‘1’ means ‘Not at all Difficult’ and ‘10’ means ‘Extremely Difficult’. Scores above 7 were used to categorise respondents as ‘having difficulty’ in each domain.

    Healthcare utilisation

    Respondents indicated how often they visited a primary healthcare provider for services (defined as care for general health issues and prevention, such as illness, physical examinations, vaccinations and health screenings) in the past 12 months. They also indicted how many different providers they saw in that period. Reliance on emergency or urgent care was determined by asking what type of healthcare location they received most of their primary care services. They were also asked how often they had visited the emergency room (ER) in the past 12 months to address a personal health issue (not at all, once or twice or three or more times).

    The survey also included an experimental task evaluating perceptions of operational factors and services offered by community pharmacies (unrelated to adherence) to be reported elsewhere.

    Statistical analysis

    Risk factors were tested for their association with low medication adherence defined by a score of <6 on the MMAS-8 adherence scale, using binary logistic regression models in SAS (V.9.3). Initial univariate tests were conducted, and those variables significantly associated with low adherence (p<0.05) were then included in a multivariate model. Given the large sample size and the number of univariate tests being conducted, to avoid spurious associations, this conservative approach was used rather than using a looser inclusion criterion (p<0.20). No issues with multicollinearity between predictor variables were thus observed.

    Results

    Respondent characteristics

    A total of 9202 respondents’ surveys were analysed as completed (see table 1.) Respondents were primarily Caucasian, with those of Hispanic origin, or African-American ethnicity represented by 11.8% and 10.7%, respectively. In terms of age, 18.3% were aged ≥65 years with the majority of respondents being aged 46–64 years. The youngest age group aged 18–25 years was the smallest (6.0%), presumably more healthy, which is consistent with the study screening for prior prescription filling at a pharmacy. With regard to income, 14.6% were living below the poverty level and 24.2% had low income. Respondents were well represented from the four regions of the USA, with a somewhat higher proportion in the South (38.5%) than in the Northeast (19.1%), Midwest (24.7%) or the West (17.6%). Most answered they lived in a small city/town (31.3%) or suburb of a large city (34.8%).

    View this table:
    Table 1

    Demographic characteristics of 9202 adults surveyed from the general population

    Low medication adherence and its correlates

    Using the standard cutoffs for the Morisky scale, 3862 (42%) respondents had ‘low’ self-reported adherence (<6 on the scale), 2706 (29.4%) had ‘medium’ adherence (6 or 7 on the scale) and 2635 (28.6) had ‘high’ adherence (score of 8).

    Table 2 shows the degree of association between each of the demographic and predictor variables with low adherence in the univariate analyses. Univariate predictors of low adherence ranked by highest to lowest strength of association included age, adherence lowest in the youngest age group and improving with each age category, frequent visits to the emergency department (OR: 2.52 (3 or more)) or care mostly delivered through a hospital or urgent care facility (OR: 1.62), difficulty with transportation for healthcare needs (OR: 2.01), health status (OR: 1.93 (poor), 1.69 (fair), 1.36 (good) and 1.12 (very good)), needs support of others (OR: 1.92), difficulty with healthcare and medication costs (OR: 1.76), Hispanic and African-American ethnicity (OR: 1.63; 1.41), poverty or low income (OR 1.61; 1.38), visit to primary care doctor every 2 years (adjusted OR: 1.51), utilisation of more than two providers or more than two locations (OR: 1.48, 1.43) and women (OR: 1.17).

    View this table:
    Table 2

    Univariate and multivariate associations between multiple predictor variables and self-reported low medication adherence as measured by the eight-item MMAS* in 9202 adults surveyed from the general population

    Table 2 also shows the results from the multivariate model. This model was a well-fitting model with a C-statistic of 0.7.20 Low adherence was most strongly associated with being of younger age; Hispanic origin (AOR=1.24) or African-American (AOR: 1.42), difficulty with healthcare, medication, or transportation costs (AORs: 1.24, 1.24, 1.32, respectively), health limiting activity (AOR: 1.33), using more than two providers (AOR: 1.27), visiting a primary care provider every few years (AOR 2.06) and visiting an emergency department >3 times in last 12 months (AOR: 1.34).

    Discussion

    The level of self-reported low medication adherence in this large sample of healthcare consumers from the general population, using a well-recognised standardised instrument, of 42% is alarmingly high, and is probably an underestimate. It is somewhat lower than the 52.7% seen with the same measure in an inner city sample, which was associated with younger age.21 Similarly, lower age was the strongest predictor of low adherence in our study, followed by socioeconomic status as it relates specifically to the ability to afford healthcare costs, frequent use of ER or urgent care centres for healthcare and use of more providers—all associated with lower adherence rates. High adherence rates were associated with having a frequent ongoing relationship with a primary care provider.

    A limitation of the study is its cross-sectional nature. A prospective longitudinal study of a large general population sample would allow for a determination of associated adverse health outcomes from low adherence over time. Some limitations of the study may suggest the low adherence estimates obtained may be an underestimate: a potential source of bias is that those who are less adherent may be less likely to participate in online surveys. The study is focused on adherence in general, rather than specific conditions or medications. Since it is possible for a person to indicate adherence to one medication while being non-adherent to another, and reporting themselves as overall adherent, this could also suggest the present already very high estimates on low adherence may underestimate the true level of low adherence. The survey was administered in English language only; a Spanish language version may elicit more reporting of low adherence for the Hispanic respondents. One additional limitation of the study was the restriction on survey length, which limited the ability to explore adherence by specific disorders, and a deeper exploration of the patient’s health status. Furthermore, this is a comprehensive evaluation of the US population, and its application to other countries warrants further study.

    One of the larger studies of low adherence in the USA is the Cohort Study of Medication Adherence among Older Adults (CoSMO), an investigation of antihypertensive medication adherence among 2194 adults aged 65 years and older recruited from a managed care organisation in Louisiana.22 In this study, 14.1% of respondents self-reported reported low medication adherence using the MMAS eight-item version.12 Factors associated with low adherence included being younger (less than 75 years of age), being African-American, having a higher body mass index.22 In a subsequent study of this cohort, a decline in adherence was predictive by the presence of depressive symptoms, being female, being married and the level of stressful life events experienced.23 Our rate of 42% is threefold higher than the CoSMO study; however, shorter enrolment time in healthcare plans is associated with higher levels of non-adherence.6 Our higher rate may also be accounted for by the wider range of patients (ie, not restricted to those with a singly condition) and the wider age distributions compared with the CoSMO sample. As noted in the CoSMO study, even among an older sample, younger age was associated with low adherence.22 We found that younger age was the strongest independent factor associated with of low adherence in the present study, consistent with our previous studies showing higher adherence with increasing age.9 10 Age may also be related to more commonly having a continuous relationship with a provider, something that is not always seen with younger healthy individuals.

    Low adherence was observed uniformly across the country, without differentiation to geographic region, size of community and respondents’ health status and level of comorbidities. However, beyond age, certain demographic characteristics stand out as being significantly independently associated with low adherence, notably being of Hispanic origin or African-American. This is after adjusting for income and other access and healthcare utilisation factors. A recent study of income data for the US population from 1999 to 2004 showed that higher income was associated with greater longevity over time, and differences in life expectancy were correlated with rates of smoking, obesity and positively correlated with exercise rates.24 Furthermore, medical causes such as heart disease and cancer mortality are known to be higher in in individuals with lower socioeconomic status when compared with vehicle crashes, suicide and homicide. Could a lack of a consistent relationship with a provider, the inability to afford health costs or ease of being able to access healthcare and poor medication adherence lead to greater mortality from heart disease and cancer? Further exploration is warranted to determine the drivers of low adherence in these populations, so perhaps to be able to improve health outcomes in lower socioeconomic areas.

    Although respondents’ health status per se was not independently associated with low adherence in our multivariate model, importantly the level of healthcare utilisation was. Low adherence was significantly and independently associated a high level of ER use. In this study, it is not possible to tease out temporal causality, and it may be that these factors may be a consequence of low adherence, but also possible predictors, as the use of multiple providers may foster the possibility of miscommunications in health education and counselling, particularly with regard to medication use. Development of a centralised electronic medical record, independent of healthcare systems, that allows all providers a link to the same information source could assist in improving the quality of healthcare delivery by reducing harms, improving communication between providers, thereby improving medication adherence.

    In the present multivariate model, low adherence is a phenomenon observed uniformly across the country, with no statistically significant differentiation with regard to geographic region, size of community and respondents’ health status and level of comorbidities. However, beyond age, certain demographic characteristics stand out as being significantly independently associated with low adherence, notably being of Hispanic origin or African-American. This is after adjusting for income and other access and healthcare utilisation factors. Further research is warranted to determine the drivers of low adherence in these populations. Again, it may be that the quality and delivery processes for health education and counselling with regard to mediations may be deficit for ethnic minority patients.

    Conclusions

    This study demonstrated a very high level of self-reported low medication adherence in the general population, reinforcing the WHO report of non-adherence as a significant public health problem. It is particularly evident that after adjusting for income and insurance status, medication adherence remains a significant issue for ethnic minorities, those who use multiple healthcare providers and those who experience barriers to healthcare access in terms of the ability to pay for healthcare and medications, and transportation issues. Patient education, counselling and healthcare policy initiatives directed to addressing low medication adherence should be priorities for research and interventions. One such step could be to focus healthcare resources towards how to engage patients in a meaningful, continuous, and quality patient–provider relationship, that is, medication adherence-centric.

    References

    1. 1.
      1. Osterberg L,
      2. Blaschke T
      . Adherence to medication. N Engl J Med 2005;353:48797.doi:10.1056/NEJMra050100
      OpenUrlCrossRefPubMedWeb of Science
    2. 2.
      1. Sabaté E
      . World Health Organization. Adherence to long-term therapies: evidence for action. Geneva: World Health Organization, 2003. ISBN 92 4 154599 2.
    3. 3.
      1. Haynes RB,
      2. McDonald H,
      3. Garg AX, et al
      . Interventions for helping patients to follow prescriptions for medications. Cochrane Database Syst Rev 2002:CD000011.doi:10.1002/14651858.CD000011
    4. 4.
      1. Marcum ZA,
      2. Sevick MA,
      3. Handler SM
      . Medication nonadherence: a diagnosable and treatable medical condition. JAMA 2013;309:21056.doi:10.1001/jama.2013.4638
      OpenUrlCrossRefPubMedWeb of Science
    5. 5.
      1. Office CB
      . Offsetting effects of prescription drug use on Medicare’s spending for other health care services, 2012.
    6. 6.
      1. Raebel MA,
      2. Ellis JL,
      3. Carroll NM, et al
      . Characteristics of patients with primary non-adherence to medications for hypertension, diabetes, and lipid disorders. J Gen Intern Med 2012;27:5764.doi:10.1007/s11606-011-1829-z
      OpenUrlCrossRefPubMed
    7. 7.
      1. Shah NR,
      2. Hirsch AG,
      3. Zacker C, et al
      . Factors associated with first-fill adherence rates for diabetic medications: a cohort study. J Gen Intern Med 2009;24:2337.doi:10.1007/s11606-008-0870-z
      OpenUrlCrossRefPubMed
    8. 8.
      1. Beardon PH,
      2. McGilchrist MM,
      3. McKendrick AD, et al
      . Primary non-compliance with prescribed medication in primary care. BMJ 1993;307:8468.doi:10.1136/bmj.307.6908.846
      OpenUrlAbstract/FREE Full Text
    9. 9.
      1. Feehan M,
      2. Ranker L,
      3. Durante R, et al
      . Adherence to controller asthma medications: 6-month prevalence across a US community pharmacy chain. J Clin Pharm Ther 2015:5903.doi:10.1111/jcpt.12316
    10. 10.
      1. Feehan M,
      2. Munger MA,
      3. Cooper DK, et al
      . Adherence to Glaucoma medications over 12 months in two US Community Pharmacy chains. J Clin Med 20162016;5:79.doi:10.3390/jcm5090079
      OpenUrl
    11. 11.
      1. Stirratt MJ,
      2. Dunbar-Jacob J,
      3. Crane HM, et al
      . Self-report measures of medication adherence behavior: recommendations on optimal use. Transl Behav Med 2015;5:47082.doi:10.1007/s13142-015-0315-2
      OpenUrlCrossRefPubMed
    12. 12.
      1. Morisky DE,
      2. Ang A,
      3. Krousel-Wood M, et al
      . Predictive validity of a medication adherence measure in an outpatient setting. J Clin Hypertens 2008;10:34854.doi:10.1111/j.1751-7176.2008.07572.x
      OpenUrlCrossRefWeb of Science
    13. 13.
      1. Krousel-Wood MA,
      2. Islam T,
      3. Webber LS, et al
      . Concordance of self-reported medication adherence by pharmacy fill in patients with hypertension. Am J Managed Care 2009;15:5966.
      OpenUrlPubMedWeb of Science
    14. 14.
      1. Albekairy AM,
      2. Alkatheri AM,
      3. Jarab A, et al
      . Adherence and treatment satisfaction in liver transplant recipients. Saudi J Gastroenterol 2016;22:12732.doi:10.4103/1319-3767.164209
      OpenUrl
    15. 15.
      1. Mayet AY
      . Patient adherence to warfarin therapy and its impact on anticoagulation control. Saudi Pharm J 2016;24:2934.doi:10.1016/j.jsps.2015.02.005
      OpenUrl
    16. 16.
      1. Gupta JK,
      2. Daniels JP,
      3. Middleton LJ, et al
      . A randomised controlled trial of the clinical effectiveness and cost-effectiveness of the levonorgestrel-releasing intrauterine system in primary care against standard treatment for menorrhagia: the ECLIPSE trial. Health Technol Assess 2015;19:1118.doi:10.3310/hta19880
      OpenUrlCrossRefPubMed
    17. 17.
      1. Aspden T,
      2. Wolley MJ,
      3. Ma TM, et al
      . Understanding barriers to optimal medication management for those requiring long-term dialysis: rationale and design for an observational study, and a quantitative description of study variables and data. BMC Nephrol 2015;16:102.doi:10.1186/s12882-015-0097-2
      OpenUrl
    18. 18.
    19. 19.
    20. 20.
      1. Hosmer DW,
      2. Lemeshow S
      . Applied Logistic regression. 2nd Edition. New York, NY: John Wiley & Sons, 2000.
    21. 21.
      1. Gatti ME,
      2. Jacobson KL,
      3. Gazmararian JA, et al
      . Relationships between beliefs about medications and adherence. Am J Health Syst Pharm 2009;66:65764.doi:10.2146/ajhp080064
      OpenUrlAbstract/FREE Full Text
    22. 22.
      1. Krousel-Wood MA,
      2. Muntner P,
      3. Islam T, et al
      . Barriers to and determinants of medication adherence in hypertension management: perspective of the cohort study of medication adherence among older adults. Med Clin North Am 2009;93:75369.doi:10.1016/j.mcna.2009.02.007
      OpenUrlCrossRefPubMedWeb of Science
    23. 23.
      1. Krousel-Wood M,
      2. Joyce C,
      3. Holt E, et al
      . Predictors of decline in medication adherence: results from CoSMO. Hypertension 2011;58:80410.
      OpenUrlCrossRef
    24. 24.
      1. Chetty R,
      2. Stepner M,
      3. Abraham S, et al
      . The Association between Income and Life Expectancy in the United States, 2001-2014. JAMA 2016;315:175066.doi:10.1001/jama.2016.4226
      OpenUrlCrossRefPubMed

    Footnotes

    • Contributors Drs. MF and MarkM had full access to all the data in the study and take responsibility for the integrity of the data and the accuracy of the data analysis. Study concept and design: MF, MMD, DEM and MarkM. Acquisition, analysis or interpretation of data: all authors. Drafting of the manuscript: MF. Critical revision of the manuscript for important intellectual content: all authors. Statistical analysis: MargAM, CT. Obtaining funding: MF, MMD and MarkM. Study supervision: MF and MarkM. All authors approved the manuscript.

    • Funding The study was supported by grants from: The Skaggs Institute for Research; The Skaggs Foundation for Research; the National Institutes of Health, National Eye Institute (EY014800); and an unrestricted grant from Research to Prevent Blindness, Inc., New York, NY, to the Department of Ophthalmology & Visual Sciences, University of Utah. The study sponsors had no role in the study design; collection, analysis and interpretation of data; writing the report, and the decision to submit the report for publication.

    • Competing interests None declared.

    • Patient consent Respondents completed an online consent form reviewed by the University of Utah's IRB.

    • Ethics approval The study protocol and survey instrument were reviewed and considered as exempt based on applicable guidelines involving the ethical treatment of human subjects by the University of Utah Institutional Review Board before the initiation of data collection. The University of Utah Institutional Review Board is fully accredited by the Human Research Protection Programs, Inc.

    • Provenance and peer review Not commissioned; externally peer reviewed.

    • Data sharing statement No extra data available. Please contact corresponding author for access to study data.

    • Correction notice This paper has been amended since it was published Online First. Owing to a scripting error, some of the publisher names in the references were replaced with 'BMJ Publishing Group'. This only affected the full text version, not the PDF. We have since corrected these errors and the correct publishers have been inserted into the references.

    Linked Articles