Abstract
Objective:
To examine Medicaid expansion (ME) effects on health insurance coverage (HIC) and cost barriers to medical care among people with asthma.
Method:
We analyzed 2012–2013 and 2015–2016 data from low-income adults with current asthma aged 18–64 years in the Behavioral Risk Factor Surveillance System Asthma Call-Back Survey (state-level telephone survey). We calculated weighted percentages and 95% confidence intervals from ME and non-ME jurisdictions (according to 2014 ME status). Outcomes were HIC and cost barriers to buying asthma medication (MED), seeing a health care provider for asthma (HCP), or any asthma care (AAC). Using SUDAAN, we performed survey-weighted difference-in-differences analyses, adjusting for demographics. Subgroup analyses were stratified by demographics.
Results:
Our study population included 6445 participants from 25 states plus Puerto Rico. In 2015–2016 compared to 2012–2013, HIC was more common in ME jurisdictions (P<0.001) but unchanged in non-ME jurisdictions. Adjusted difference-in-differences analyses showed ME was associated with a statistically significant 13.36 percentage-point increase in HIC (standard error = 0.053). Cost barriers to MED, HCP, and AAC did not change significantly for either group in descriptive and difference-in-differences analyses. In subgroup analyses, we noted variation in outcomes by demographics and 2014 ME status.
Conclusions:
We found ME significantly affected HIC among low-income adults with asthma, but not cost barriers to asthma-related health care. Strategies to reduce cost barriers to asthma care could further improve health care access among low-income adults with asthma in ME jurisdictions.
Keywords: asthma, Medicaid, Medicaid expansion, health insurance, cost, disparities, race, ethnicity, sex, age
INTRODUCTION
The Affordable Care Act expanded eligibility criteria for Medicaid to include nonelderly citizens and permanent residents with incomes below 138% of the federal poverty level (FPL) in participating states (“Medicaid expansion”), effective on or after January 1, 2014.(1, 2) Subsequently, 26 states and the District of Columbia implemented Medicaid expansion (ME) in 2014.(2, 3)
Asthma affects over 19 million U.S. adults, resulting in >8.7 million asthma-related missed work days and >1 million hospitalizations and emergency department (ED) visits among adults each year.(4, 5) Many asthma-related hospitalizations, ED visits, and missed work days can be prevented with guidelines-based preventive care for asthma, including regularly scheduled visits with health care providers and (when indicated) asthma medications intended to prevent asthma symptoms.(6)
The impact of ME has been investigated in the overall population as well as in people with some specific health conditions, such as congestive heart failure (CHF), kidney disease, diabetes, and depression.(7–10) Varied relationships between ME, health care access, health care use, and health outcomes have been reported; for example, one study found ME was associated with increased health insurance coverage among patients admitted for CHF but in-hospital mortality did not change.(7, 10, 11) Also, some studies have suggested the impact of ME can differ by demographic characteristics including race/ethnicity and sex.(12–15) For instance, one report indicated Hispanic participants were least likely to benefit from gains in health insurance coverage and access to doctors after ME.(12)
Understanding of the impact of ME on people with respiratory conditions, including asthma, remains limited.(16, 17) One recent study involving data from seven states found an association between ME and a decline in mechanical ventilation rates for people with asthma, chronic obstructive pulmonary disease (COPD), or CHF.(16) Data on study participants with asthma were not analyzed separately from those with COPD. These investigators did not detect significant relationships between ME and admissions to the intensive care unit or in-hospital mortality.(16) An earlier report showed COPD prevalence did not change after ME.(17) To date, asthma-specific data on the impact of ME have not been published.
Obtaining health insurance coverage through ME could reduce cost barriers to asthma-related health care and thereby reduce asthma morbidity and mortality.(18) We focused this investigation on examining the impact of ME on health insurance coverage and cost barriers to care among low-income adults with asthma. By first elucidating these relationships, we intended to lay a foundation for future study of how ME has affected asthma-related health care use and health outcomes.
Thus, the primary objective of our study was to investigate the impact of ME on health insurance coverage and cost barriers to care among low-income adults with asthma. Our secondary objective was to assess whether the impact of ME on health insurance coverage and cost barriers to care varied by demographic characteristics, within our study population.
METHODS
Study Design and Data Source
We used data from the Behavioral Risk Factor Surveillance System (BRFSS) Adult Asthma Call-Back Survey (ACBS). BRFSS is an ongoing, state-based, random-digit-dialing, cross-sectional telephone (land line and cell phone) survey of non-institutionalized U.S. adults aged ≥18 years; BRFSS is conducted in all 50 states, the District of Columbia, and 3 U.S. territories.(19) Details about BRFSS’ disproportionate stratified sample design and sample weighting have been reported elsewhere.(19–21) ACBS is a follow-up telephone survey that some states administer to BRFSS participants who responded that they ever had asthma (i.e., they responded “yes” to the question, “have you ever been told by a doctor, nurse, or other health professional that you had asthma?”). Any state or territory can choose to apply for funds to implement the ACBS for a particular year, but not all do; for example, 28 jurisdictions collected ACBS data from adults during each of the 4 years included in our study period (i.e., 2012, 2013, 2015, and 2016).(22, 23) ACBS is conducted approximately two weeks after BRFSS. Response rates for BRFSS and ACBS in 2016 were 47.1% and 44.5%, respectively(24, 25); response rates were similar across the years of data included in this study. Jurisdiction-specific Institutional Review Board (IRB) requirements apply to each participating jurisdiction(22, 23); informed consent was obtained. Analyses of ACBS data are exempt from review by the IRB at the Centers for Disease Control and Prevention.
We used four years of ACBS data, combining two 2 years of data for each period to obtain a sufficiently large sample to generate stable estimates (i.e., 2012–2013 and 2015–2016). Similar to prior publications on the impact of ME, we excluded 2014 data.(7) Also, we excluded 2014 data to avoid assuming that participants applied for or received Medicaid coverage as soon as ME could be implemented in January 2014.
To estimate the effect of ME, we defined the ME group as participants in jurisdictions that expanded Medicaid in 2014 (Table 1).(26–28) Our comparison group was participants in jurisdictions that did not expand Medicaid in 2014 (“non-ME”).
Table 1.
Medicaid Expansion (ME) Group (15 jurisdictions) |
Non-Medicaid Expansion (Non-ME) Group (11 jurisdictions) |
---|---|
• Connecticut | • Florida |
• Hawaii | • Georgia |
• Iowa | • Kansas |
• Massachusetts | • Maine |
• Michigan | • Mississippi |
• Nevada | • Missouri |
• New Hampshire | • Montana |
• New Jersey | • Nebraska |
• New Mexico | • Texas |
• New York | • Utah |
• Ohio | • Wisconsin |
• Oregon | |
• Puerto Rico | |
• Rhode Island | |
• Vermont |
Indiana and Pennsylvania were excluded from this analysis because these states expanded Medicaid in 2015. The 23 states not listed in this table were excluded because ACBS data were not available from these states for each of the years included in the study period.
Study Population
Our study population was low-income adult ACBS participants aged 18–64 years with current asthma from jurisdictions (U.S. states or territories) for which ACBS data were available for every year included in our study period (i.e., 2012, 2013, 2015, and 2016). From the 28 jurisdictions that had ACBS data available for these four years, we excluded two states (Indiana and Pennsylvania) because these states implemented ME in 2015(3) (in our study, 2015 was defined as part of our post-ME period). Of the remaining 26 jurisdictions, 15 jurisdictions were included in the ME group (14 states plus Puerto Rico) and 11 jurisdictions/states were represented in the non-ME group. More detail on these 26 jurisdictions is presented in Table 1. We defined low-income as reported annual household income below 138% of the 2016 FPL.(29) Because the survey collected annual household income in categories, we used the midpoints of these categories to calculate household income as a percentage of FPL while accounting for family size, similar to prior analyses.(30) We excluded participants with missing income data (11.3% of the original, entire dataset that contained our final study population as well as respondents who were excluded from our study population), as well as adults aged ≥65 years because of their eligibility for Medicare.(31) To meet our definition of current asthma, participants had to respond “yes” to both of the following questions: “Has a doctor, nurse, or other health professional ever told you that you had asthma?” and “Do you still have asthma?”
Measures
We examined four outcomes: any health insurance coverage (at the time of the survey interview), could not buy asthma medication because of cost during the past 12 months, could not see health care provider for asthma because of cost during the past 12 months, and any cost barrier to asthma care during the past 12 months. For “could not see health care provider for asthma because of cost during the past 12 months”, we classified participants as having this outcome if they answered “yes” to either of these two questionnaire items: “Was there a time in the past 12 months when you needed to see your primary care doctor for your asthma but could not because of the cost?” and “Was there a time in the past 12 months when you were referred to a specialist for asthma care but could not go because of the cost?” We classified participants as having any cost barrier to asthma care during the past 12 months if they reported they could not buy asthma medication, see their primary care doctor for asthma, or go to a specialist for asthma care because of cost in the past 12 months.
Statistical Analysis
We used SAS 9.4-callable SUDAAN (version 11.0.1) to account for the complex survey design of the ACBS. Detailed information on ACBS survey design and analytic methods is publicly available.(22) We calculated weighted percentages and 95% confidence intervals (CIs) for each variable and each period (i.e., 2012–2013 and 2015–2016), by ME status. According to standard protocols(22, 32), our analyses used ACBS final weights to adjust for loss of sample between the BRFSS interview and the ACBS interview, as well as to compensate for nonresponse during the BRFSS and ACBS interviews. We used these methods to generate data representative of the 26 jurisdictions (25 states and Puerto Rico) included in our analysis. Additional information on weight calculations and response rates is located online and in prior publications.(22, 33–35) Results for which the relative standard error was >0.3 were suppressed, per standard protocol.(22) Within each group (ME and non-ME), we used t-tests (α=0.05) to compare weighted percentages and 95% CIs from 2012–2013 to those from 2015–2016.
Furthermore, we used a quasiexperimental difference-in-differences design to estimate the effect of ME on each of the four outcomes, similar to prior research on ME effects.(8, 9, 12, 17, 27, 30, 36–43) This method contrasts the changes from before to after ME in states that implemented ME and with the changes over the same time period in states that did not implement ME.(8, 9, 17, 30, 36–38) Our linear model was specified as follows:
Outcomeist are binary indicators for responding “Yes” to the outcome of interest (e.g., health insurance coverage or could not buy asthma medication because of cost during the past 12 months) for individual i in state s in year t. Expands is a binary indicator for the 15 ME jurisdictions (14 states plus Puerto Rico) versus the 11 non-ME jurisdictions in our dataset. Yeart is a binary indicator for survey respondents in 2015–2016 versus 2012–2013. Xist is a vector of individual-level characteristics including race/ethnicity, sex, and age category; because we used annual household income to define our study population, we did not include other markers of socioeconomic status in this model. States is the fixed effect for state that captures time-invariant differences between states. β1 is the effect of ME. Identifying this effect assumes that in the absence of ME, the outcome of interest would have changed similarly from 2012–2013 to 2015–2016 in both ME and non-ME jurisdictions, after adjusting for covariates. In our estimates, we adjusted for race/ethnicity, sex, and age category. We report modeling results in percentage-point changes with standard errors (SEs). For all analyses, we excluded observations with missing outcome data. For adjusted analyses, we also excluded observations with missing covariate data.
Because of differences in asthma burden, covered Medicaid benefits, and health care access in Puerto Rico compared to states(44–46), we conducted a sensitivity analysis that excluded participants from Puerto Rico. Also, we conducted subgroup analyses by race/ethnicity, sex, and age category (including an age category for participants aged 18–25 years, who could have been affected by another ACA provision that allowed young adults aged less than 26 years to remain on their parents’ private health insurance plans).
RESULTS
Study Population Characteristics
Our results were based on 6445 survey responses from unique individuals (3346 individuals from 2012–2013 plus 3099 individuals from 2015–2016), representative of approximately 7.0 million low-income adults with current asthma aged 18–64 years in 26 jurisdictions (25 states plus Puerto Rico). Most respondents reported white, non-Hispanic race/ethnicity in both the ME and non-ME groups (Table 2). The percentage of black, non-Hispanic participants was similar in both groups. In contrast, the ME group had a higher percentage of Hispanic participants. COPD appeared more common in the non-ME group, in both 2012–2013 and 2015–2016.
Table 2.
2012–2013 | 2015–2016 | |||
---|---|---|---|---|
Characteristics | ME Groupb Unweighted n = 1797d (Weighted n = 1 968 161) |
Non-ME Groupc Unweighted n = 1549d (Weighted n = 1 783 699) |
ME Groupb Unweighted n = 1704d (Weighted n = 1 836 183) |
Non-ME Groupc Unweighted n = 1395d (Weighted n = 1 377 922) |
Weighted % (95% CI) | Weighted % (95% CI) | Weighted % (95% CI) | Weighted % (95% CI) | |
Male sex | 31.8 (26.1–38.0) | 27.4 (21.6–34.1) | 34.0 (29.4–39.0) | 32.6 (26.4–39.5) |
Race/ethnicity | ||||
White, non-Hispanic | 58.4 (52.3–64.2) | 63.5 (56.4–70.1) | 51.2 (46.3–56.1) | 60.8 (54.0–67.2) |
Black, non-Hispanic | 16.8 (11.8–23.3) | 19.8 (15.0–25.8) | 14.0 (11.0–17.6) | 13.7 (10.0–18.5) |
Other, non-Hispanic | 5.6 (4.1–7.5) | 3.7 (2.3–6.0) | 11.3 (8.1–15.4) | 7.7 (4.6–12.6) |
Hispanic | 19.3 (15.6–23.6) | 12.9 (8.5–19.2) | 23.5 (20.0–27.9) | 17.8 (12.8–24.2) |
Age in years | ||||
18–25 | 30.3 (23.9–37.5) | 22.2 (16.2–29.7) | 26.0 (21.4–31.3) | 27.3 (20.9–34.7) |
26–44 | 34.9 (29.5–40.6) | 40.3 (33.2–47.8) | 35.9 (31.2–40.9) | 32.2 (26.5–38.5) |
45–64 | 34.8 (30.2–39.9) | 37.5 (31.5–44.1) | 38.1 (33.8–42.6) | 40.5 (34.7–46.6) |
COPD | 35.6 (30.74–40.8) | 43.0 (36.0–50.2) | 33.4 (29.3–37.8) | 41.8 (35.5–48.4) |
Current smoker | 34.1 (29.0–39.6) | 35.4 (28.7–42.6) | 30.9 (26.6–35.5) | 30.2 (24.7–36.4) |
CI, confidence interval; COPD, chronic obstructive pulmonary disease; ME, Medicaid expansion.
Low-income was defined as below 138% of the federal poverty level.
Puerto Rico and the following 14 states: CT, HI, IA, MA, MI, NH, NJ, NM, NV, NY, OH, OR, RI, VT.
FL, GA, KS, ME, MS, MO, MT, NE, TX, UT, WI. Indiana and Pennsylvania were excluded from this analysis because these states expanded Medicaid in 2015. The 23 states remaining not represented in this table were excluded because ACBS data were not available from these states for each of the years included in the study period.
Total sample size (N) = 6445, which includes both 2012–2013 and 2015–2016 data.
Ever told by a doctor or other health professional that he or she had chronic obstructive pulmonary disease (COPD), emphysema, or chronic bronchitis.
Results from Descriptive Analyses
In the ME group, the prevalence of health insurance coverage was higher in 2015–2016 than in 2012–2013 (92.3% [95%CI, 89.2–94.5] vs. 79.8% [95%CI, 74.6–84.1], P<0.001; Table 3). Prevalence of health insurance coverage did not change significantly in the non-ME group. Reports of inability to buy asthma medication or see a health care provider for asthma because of cost were slightly decreased in the ME group in 2015–2016 compared to 2012–2013, but these differences were not statistically significant; we observed a similar pattern for any cost barrier to asthma care. In the non-ME group, inability to buy asthma medication or see a health care provider for asthma because of cost were slightly more prevalent in 2015–2016 than 2012–2013 but these differences were not statistically significant.
Table 3.
ME Groupb | Non-ME Groupc | |||||
---|---|---|---|---|---|---|
Outcomes | 2012–2013 n; Weighted % (95% CI) |
2015–2016 n; Weighted % (95% CI) |
P valued | 2012–2013 n; Weighted % (95% CI) |
2015–2016 n; Weighted % (95% CI) |
P valued |
Health insurance coveragee | 1788; 79.8 (74.6–84.1) | 1696; 92.3 (89.2–94.5) | <0.001 | 1543; 70.1 (63.1–76.3) | 1383; 69.9 (63.0–75.9) | 0.96 |
Could not buy asthma medication because of costf | 1795; 25.8 (20.78–31.6) | 1699; 21.7 (17.6–26.4) | 0.25 | 1544; 32.4 (26.1–39.4) | 1385; 36.4 (29.9–43.3) | 0.42 |
Could not see health care provider for asthma because of costf,g | 1795; 22.1 (17.1–28.0) | 1702; 17.5 (13.5–22.4) | 0.20 | 1548; 29.3 (23.3–36.0) | 1387; 32.9 (26.6–39.9) | 0.44 |
Any cost barrier to asthma careh | 1797; 30.6 (25.3–36.4) | 1702; 27.3 (22.9–32.2) | 0.37 | 1549; 38.7 (32.1–45.7) | 1388; 40.9 (34.4–47.7) | 0.66 |
CI, confidence interval; ME, Medicaid expansion.
Low-income was defined as below 138% of the federal poverty level.
Puerto Rico and the following 14 states: CT, HI, IA, MA, MI, NH, NJ, NM, NV, NY, OH, OR, RI, VT.
FL, GA, KS, ME, MS, MO, MT, NE, TX, UT, WI. Indiana and Pennsylvania were excluded from this analysis because these states expanded Medicaid in 2015. The 23 remaining states not represented in this table were excluded because ACBS data were not available from these states for each of the years included in the study period.
Comparison between 2012–2013 and 2015–2016 data. Boldface indicates statistical significance (P < .05).
Reported any kind of health care coverage, including health insurance, prepaid plans such as HMOs, or government plans such as Medicare or Medicaid.
During the past 12 months.
Combination of 2 questionnaire items (“Was there a time in the past 12 months when you needed to see your primary care doctor for your asthma but could not because of cost?” and “Was there a time in the past 12 months when you were referred to a specialist for asthma care but could not go because of the cost?”). A cost barrier to asthma-related visit with a health care provider was defined as present if the respondent said “yes” to either questionnaire item.
Combination of “Could not buy asthma medication because of cost” and “Could not see health care provider for asthma because of cost.” Any cost barrier was defined as present if either of these variables was associated with a positive response.
Results from Difference-in-Differences Analyses
In our adjusted difference-in-differences analyses (Table 4), ME was associated with a statistically significant 13.36 percentage-point increase in health insurance coverage (SE=0.053). Also, ME was associated with a 9.53 percentage-point decrease in reported inability to buy asthma medication because of cost (SE=0.056), a 7.67 percentage-point decrease in reported inability to see a health care provider for asthma because of cost (SE=0.055), and a 6.62 percentage-point decrease in any cost barrier to asthma care (SE=0.058); confidence intervals for these cost barrier-related difference-in-differences analyses (unadjusted [Table E1] and adjusted) included the null. We found similar results in a sensitivity analysis that excluded participants from Puerto Rico (Table E2).
Table 4.
Difference-in-Differences Estimate (Adjusted)b | |||
---|---|---|---|
Outcomes | nc | Percentage-Point Change | Standard Error |
Health insurance coveraged | 6315 | 13.36e | 0.053 |
Could not buy asthma medication because of costf | 6337 | −9.53 | 0.056 |
Could not see health care provider for asthma because of costf,g | 6328 | −7.67 | 0.055 |
Any cost barrier to asthma careh | 6441 | −6.62 | 0.058 |
Low-income was defined as below 138% of the federal poverty level.
Adjusted for age, sex, and race/ethnicity. These results estimate the change in likelihood of health insurance coverage or cost barriers to care in 2015–2016 versus 2012–2013 as a result of the Medicaid expansion, obtained from difference-in-differences analyses. These estimates are the appropriate coefficients from the regression model, multiplied by 100. The standard error represents the standard error of each coefficient, not multiplied by 100.
Unweighted (n). Total unweighted sample size (N) = 6445. Observations with missing data were excluded from analyses.
Reported any kind of health care coverage, including health insurance, prepaid plans such as HMOs, or government plans such as Medicare or Medicaid.
Significant at P < 0.05.
During the past 12 months.
Combination of 2 questionnaire items (“Was there a time in the past 12 months when you needed to see your primary care doctor for your asthma but could not because of cost?” and “Was there a time in the past 12 months when you were referred to a specialist for asthma care but could not go because of the cost?”). A cost barrier to asthma-related visit with a health care provider was defined as present if the respondent said “yes” to either questionnaire item.
Combination of “Could not buy asthma medication because of cost” and “Could not see health care provider for asthma because of cost.” Any cost barrier was defined as present if either of these variables was associated with a positive response.
Results from Subgroup Analyses
In subgroup analyses, we noted variation by race/ethnicity and 2014 ME status. In the ME group, prevalence of health insurance coverage was higher in 2015–2016 than 2012–2013 for all racial/ethnic categories (Figure 1 and Table E3); we did not see this pattern in the non-ME group. Notably, in the non-ME group, Hispanic participants had the lowest prevalence of health insurance coverage in both 2012–2013 (50.9% [95%CI, 29.2–72.3]) and 2015–2016 (47.0% [95%CI, 29.9–64.8]). Regarding inability to buy asthma medication or see a health care provider for asthma because of cost, we found no statistically significant differences in our analyses stratified by race/ethnicity (Tables E4 and E5). We did observe that Hispanic participants in the non-ME group most frequently indicated they could not see a health care provider for asthma because of cost in both 2012–2013 (53.6% [95%CI, 32.8–73.2]) and 2015–2016 (55.4% [95%CI, 37.7–71.9]).
In subgroup analyses by sex, we found health insurance coverage was higher in 2015–2016 than in 2012–2013 among both males and females in the ME group (P=0.07 for males and P<0.001 for females; Table E6). We did not find statistically significant changes in cost barriers to buying asthma medication or seeing a health care provider for asthma in analyses stratified by sex (Tables E7–E8). However, among females in the ME group, we noticed nonsignificant decreases in 2015–2016 (compared to 2012–2013) in the inability to buy asthma medication because of cost (28.1% [95%CI, 21.8–35.3] vs. 21.9% [95%CI, 17.3–27.2], P=0.14) and inability to see a health care provider for asthma because of cost (25.2% [95%CI, 18.9–32.7] vs. 16.5% [95%CI, 12.2–22.1], P=0.05); we did not see a similar pattern among males in the ME group. In the non-ME group, we observed nonsignificant decreases in cost barriers to buying asthma medication or seeing a health care provider for asthma in 2015–2016 compared to 2012–2013 among males but not females.
In subgroup analyses by age category, we found the prevalence of health insurance coverage was significantly higher for all age categories in the ME group in 2015–2016 compared to 2012–2013 (Table E9). In the non-ME group, we found a nonsignificant decrease in prevalence of health insurance coverage among participants aged 18–25 years (82.2% [95%CI, 69.9–90.3] vs. 64.7% [95%CI, 47.8–78.6], P=0.07) that we did not observe among respondents in the two, older age categories. We did not see significant differences in cost barriers to buying asthma medication or seeing a health care provider for asthma in subgroup analyses by age category (Tables E10–E11), but we noted a nonsignificant increase in inability to see a health care provider for asthma because of cost among respondents aged 18–25 years in the non-ME group (22.9% [95%CI, 12.8–37.5] vs. 35.3% [95%CI, 21.1–52.5], P=0.23).
DISCUSSION
In this study of low-income adults with current asthma aged 18–64 years in 25 states and Puerto Rico, we found that ME was significantly associated with increased prevalence of health insurance coverage, but not significantly associated with cost barriers to buying asthma medication or seeing a health care provider for asthma. In subgroup analyses, we found outcomes varied by 2014 ME status and selected demographics.
To our knowledge, this analysis is the first investigation on the impact of ME on health insurance coverage and cost barriers to asthma-related health care among people with asthma. Strengths include our population-based study design and use of weighted statistical analyses to generate results representative of all 26 jurisdictions involved, as well as difference-in-differences analyses to further reduce the potential effect of unmeasured confounding.
Our findings extend prior research on the impact of ME. Knowledge is currently limited regarding the impact of ME on people with respiratory conditions; asthma-specific data are scarce.(16) Beyond the two studies we mentioned in the Introduction (a BRFSS analysis of COPD prevalence before and after ME(17) and a seven-state, hospital-based study that analyzed asthma and COPD data in aggregate(16)), other literature relevant to this topic includes several studies assessing the impact of ME on people who use tobacco.(10, 37, 38)
Although studies have generally reported positive effects of ME on affordability of care for health conditions other than asthma,(10) we observed weak-to-moderate, nonsignificant associations between ME and cost barriers to asthma-related care, despite finding ME and health insurance coverage to be significantly associated. One potential explanation is inadequate study power to detect weak-to-moderate differences between the ME and non-ME group. Another possibility is that required copayments by health insurance plans to access medical care can be a cost barrier.(46) Also, compared to therapies commonly used to treat heart disease, diabetes, and other chronic conditions, relatively few guideline-recommended, first-line treatments for asthma are available in generic formulations, which could contribute to copayment costs. For example, U.S. Food and Drug Administration approvals for the first generic fluticasone propionate/salmeterol inhalation powder and the first generic albuterol metered dose inhaler occurred in 2019 and 2020, respectively(47, 48) — after our study period ending in 2016.
Furthermore, our results support and advance previous investigations of how ME impact might differ by demographics. Prior work has examined how the prevalence of health insurance coverage after 2014 varied across age, sex, and racial/ethnic groups, as well as across specific groups within the Hispanic population (e.g., Mexican American vs. Central American).(10, 12–14) For example, as mentioned earlier, an analysis of 2013 and 2015 BRFSS data found Hispanic participants were least likely to benefit from gains in health insurance coverage and access to doctors after ME.(12) In our data, the low prevalence of health insurance coverage and high frequency of cost barriers to seeing a health care provider for asthma among Hispanic participants in non-ME jurisdictions highlight opportunities to improve health care access and reduce asthma disparities for this population.
Regarding how ME impact might differ by sex, multiple studies have focused on women’s health.(42, 49, 50) Our data suggest males did not experience reductions in cost barriers to asthma care to the same degree as females did in ME jurisdictions (although this decrease among females was not statistically significant). Some studies have reported sex differences in health care access after the Affordable Care Act(14, 15); our investigation adds asthma-specific data to this literature.
Our analysis had limitations. We obtained data from cross-sectional surveys; causality cannot be inferred. The survey did not specifically assess Medicaid coverage. Our study design did not exclude states that expanded Medicaid before 2014(51) or explore how other ACA provisions (e.g., allowing young adults aged less than 26 years to remain on their parents’ private health insurance plans) affected people with asthma.(34) All data were self-reported, including income data. Our definition of low-income was based on the 2016 FPL. Non-response bias was possible, so we conducted sampling and weighting procedures to reduce this possibility. Also, misclassification bias could have occurred; we reduced the likelihood of misclassification in our outcome measurements by excluding 2014 data, because many survey respondents in 2014 would have included 2013 health insurance coverage or cost barriers to care within the 12-month recall period of our outcome variables. Our sample size was not sufficient to perform difference-in-differences analyses by sex, race/ethnicity, or age category. We did not use multiple imputation to account for missing data; because approximately 1% of observations within our study population of 6445 respondents were excluded because of missing data, we do not expect our results would have differed substantially had we used multiple imputation.
CONCLUSION
In summary, we investigated the impact of ME among low-income adults with current asthma aged 18–64 years in 25 states and Puerto Rico, using descriptive and difference-in-differences analyses. We observed ME was significantly associated with increased prevalence of health insurance coverage, but not cost barriers to asthma medication or seeing a health care provider for asthma. These findings highlight opportunities to create and deliver tailored strategies to reduce cost barriers to care among low-income adults with asthma and existing health insurance coverage, as well as to further investigate the potential role of copayments on cost barriers to care among people with asthma who received health insurance coverage because of ME. Future study of the impact of ME on asthma exacerbations and other asthma-related health outcomes could increase understanding of how ME has affected people with asthma.
Supplementary Material
Footnotes
Disclosure statement: The authors report no conflict of interest.
Data availability statement:
Data are available at https://www.cdc.gov/brfss/acbs/index.htm
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Associated Data
This section collects any data citations, data availability statements, or supplementary materials included in this article.
Supplementary Materials
Data Availability Statement
Data are available at https://www.cdc.gov/brfss/acbs/index.htm