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State-Level Household Energy Insecurity and Diabetes Prevalence Among US Adults, 2020

RESEARCH BRIEF — Volume 21 — August 29, 2024

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Ryan Saelee, PhD, MPH1; Kai McKeever Bullard, PhD, MPH1; Jacob T. Wittman, PhD1; Dayna S. Alexander, DrPH, MSPH, MCHES1; Darrell Hudson, PhD, MPH2 (View author affiliations)

Suggested citation for this article: Saelee R, Bullard KM, Wittman JT, Alexander DS, Hudson D. State-Level Household Energy Insecurity and Diabetes Prevalence Among US Adults, 2020. Prev Chronic Dis 2024;21:240087. DOI: http://dx.doi.org/10.5888/pcd21.240087.

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Summary

What is already known on this topic?

Energy insecurity is prevalent across the US and may be important for those with diabetes, who rely on stable energy access to reduce the impact of extreme temperatures.

What is added by this report?

Findings indicate that states with a higher prevalence of household energy insecurity had a higher prevalence of diagnosed diabetes, with the highest prevalence of both concentrated mainly among southern states.

What are the implications for public health practice?

Interventions and policies related to energy assistance may help reduce household energy insecurity, mitigate the risk of diabetes-related complications, and alleviate some of the burden of diabetes management during extreme temperatures.

Abstract

The objective of this study was to examine the state-level association between household energy insecurity and diabetes prevalence in 2020. We obtained 1) state-level data on household energy characteristics from the 2020 Residential Energy Consumption Survey and 2) diagnosed diabetes prevalence from the US Diabetes Surveillance System. We found states with a higher percentage of household energy insecurity had greater diabetes prevalence compared with states with lower percentages of energy insecurity. Interventions related to energy assistance may help reduce household energy insecurity, mitigate the risk of diabetes-related complications, and alleviate some of the burden of diabetes management during extreme temperatures.

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Objective

Climate change has led to increases in heat waves and cold spells, potentially worsening health outcomes among those with diabetes (1,2). Adverse physiologic responses to heat (eg, compromised vasodilation and sweating) and cold stress (eg, impaired vasoconstriction and brown tissue activity) may be factors driving the association between exposure to extreme temperatures and increased hospitalization and emergency department visits along with illnesses (cardiovascular disease, kidney disease, and hypertension) and death among those with diabetes (1–3). The use of residential heating and air conditioning is important for buffering against the adverse effects of extreme temperatures. However, evidence from previous research suggests that energy costs from residential heating and air conditioning are a significant burden to low-income households, which could subsequently contribute to inequalities in diabetes-related outcomes (4). In 2020, approximately 33.6 million of 123.5 million US households were considered energy insecure (ie, unable to adequately meet basic household energy needs) (5). Raising visibility at the state level of where those with energy insecurity and diabetes live may be informative for developing energy policies and interventions to meet the needs of those with diabetes. Thus, this study sought to examine the association between state-level household energy insecurity and diagnosed diabetes prevalence.

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Methods

We conducted cross-sectional analyses during August through October 2023 to examine the association between household energy insecurity and diabetes prevalence in 2020. We used data from the 2020 Residential Energy Consumption Survey (RECS), a nationally representative household survey that collects information on sociodemographic characteristics, energy use behaviors, and receipt of energy assistance (6). We used the Centers for Disease Control and Prevention’s US Diabetes Surveillance System to obtain 2020 state-level diagnosed diabetes prevalence estimates (7). We defined household energy insecurity as reporting any of the following in the past year: reducing or forgoing food or medicine to pay energy costs, leaving the home at what respondents felt were unhealthy temperatures, receiving a disconnect or delivery stop notice, and being unable — because of cost — to use heating equipment or air-conditioning equipment. We estimated weighted percentages and 95% CIs for any household energy insecurity, each of the 5 components, and those that had ever received energy assistance, overall and by state, accounting for the RECS sampling weights (6). Prevalence estimates were age-standardized to the 2000 US Census. To illustrate the relationship between age-standardized state-level prevalence of household energy insecurity and diagnosed diabetes, we categorized these variables into tertiles and created a bivariate choropleth map using R v4.3.2 package ggspatial (v1.1.8) (R Foundation) (8). We created a similar map of those who ever received energy assistance and diabetes prevalence. We used multivariable linear regression to assess the state-level association between age-standardized household energy insecurity and diagnosed diabetes prevalence, adjusting for state-level percentages of the population who are non-Hispanic White, experiencing poverty, and living in rural areas with data from the 2016 through 2020 American Community Survey (9–11) and the 2020 Housing and Demographic Characteristics file (12). We conducted these analyses in SAS v9.4 (SAS Institute Inc) and SAS-callable SUDAAN v11.0 (Research Triangle Institute).

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Results

The crude prevalence of any household energy insecurity among an estimated 123.5 million US households was 27.2% (95% CI, 26.4–28.0; range, 14.7% in Vermont to 40.4% in Mississippi), 19.9% (95% CI, 19.2–20.6) for reducing or forgoing food or medicine to pay energy costs, 9.9% (95% CI, 9.3–10.5) for leaving home at unhealthy temperatures, 10.0% (95% CI, 9.5–10.5) for receiving a disconnect or delivery stop notice, 4.0% (95% CI, 3.6–4.4) for being unable to use heating equipment, and 5.1% (95% CI, 4.7–5.5) for being unable to use air conditioning equipment (Table). The prevalence of ever receiving energy assistance was 5.3% (95% CI, 4.9–5.7; range, 3.1% in Virginia to 10.0% in California), while in 2020 alone, 3.5% (95% CI, 3.2–3.8) of US households received energy assistance (data not shown). The age-standardized bivariate choropleth map revealed that states with a higher percentage of energy insecurity also had a greater diagnosed diabetes prevalence, compared with states with lower levels of energy insecurity (Figure 1). The highest prevalence of any household energy insecurity and diabetes was found mostly in southern states (Alabama, Arkansas, Georgia, Kentucky, Louisiana, Mississippi, North Carolina, Oklahoma, South Carolina, Texas, and West Virginia), as well as Indiana and Michigan. Similarly, the adjusted linear regression model showed a positive association between household energy insecurity and diagnosed diabetes prevalence (b = 0.17, 95% CI, 0.11–0.24, P < .001) (data not shown). Furthermore, the states with the lowest prevalence of ever receiving energy assistance and the highest diabetes prevalence were Indiana and southern states that include Louisiana, North Carolina, South Carolina, Tennessee, and Texas (Figure 2).

Bivariate map of the age-standardized percentage of any energy insecurity and diagnosed diabetes prevalence by US states, 2020. Note: Cutoffs for household energy insecurity and diabetes prevalence were established based on tertiles. Sources: 2020 Residential Energy Consumption Survey (RECS) (6); 2020 Centers for Disease Control and Prevention’s US Diabetes Surveillance System.

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Figure 1.
Bivariate map of the age-standardized percentage of any energy insecurity and diagnosed diabetes prevalence by US states, 2020. Note: Cutoffs for household energy insecurity and diabetes prevalence were established based on tertiles. Sources: 2020 Residential Energy Consumption Survey (RECS) (6); 2020 Centers for Disease Control and Prevention’s US Diabetes Surveillance System. [A text description of this figure is available.]

Bivariate map of the age-standardized percentage of ever receiving energy assistance and diagnosed diabetes prevalence by US states, 2020. Note: Cutoffs of ever receiving energy assistance and diabetes prevalence were established based on tertiles. Sources: 2020 Residential Energy Consumption Survey (RECS) (6); 2020 Centers for Disease Control and Prevention’s US Diabetes Surveillance System.

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Figure 2.
Bivariate map of the age-standardized percentage of ever receiving energy assistance and diagnosed diabetes prevalence by US states, 2020. Note: Cutoffs of ever receiving energy assistance and diabetes prevalence were established based on tertiles. Sources: 2020 Residential Energy Consumption Survey (RECS) (6); 2020 Centers for Disease Control and Prevention’s US Diabetes Surveillance System. [A text description of this figure is available.]

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Discussion

Overall, states with a higher prevalence of household energy insecurity had a higher prevalence of diagnosed diabetes, with the highest prevalence of both concentrated mainly among southern states. Diabetes prevalence has continued to increase for people with low incomes (13). These trends, overlaid with more extreme temperature events over the past several decades because of climate change, indicate a burgeoning crisis (1). Additionally, we found that reducing or forgoing food or medicine to pay energy costs was the most common form of energy insecurity. This may contribute to challenges with diabetes management (eg, insulin rationing) and increases in diabetes-related complications (14).

The low prevalence of ever receiving energy assistance highlights an opportunity to reduce energy insecurity in states with high diabetes burden. Federal policies such as the Low-Income Home Energy Assistance Program and the Weatherization Assistance Program provide financial support to families with low incomes for energy bill payments, weatherization, and energy-related home repairs (4). However, these programs have been persistently underfunded and subject to budget cuts, undermining critical access to energy-related assistance programs for low-income households (4). State policies and utility companies may also address energy insecurity, as some states have policies prohibiting utility companies from disconnecting gas or electricity for households with people who have or are at greater risk for medical conditions (eg, diabetes) or have seasonal policies that forbid disconnections during extreme weather (4). The drawback to these policies is that many are time-limited and may not adequately address the needs of people with chronic household energy insecurity. At the local level, implementation of cooling centers has shown promise in sheltering high-risk populations from extreme heat and providing heat safety education, but residents may not be aware of or have access to these resources (15). At the clinic level, screening patients with diabetes for energy insecurity and referring them to state and community level resources for energy assistance would be important given that clinical interventions addressing social needs can improve health outcomes, reduce health care costs, and increase preventive care utilization (16). Future research could examine how to better implement these various policies and interventions and their effect on diabetes outcomes.

Limitations of this study include 1) household energy and diabetes are self-reported, resulting in misclassification bias, and 2) state-level associations may not apply at the individual level. Notwithstanding these limitations, developing new policies and strengthening existing ones could help to reduce household energy insecurity and subsequently decrease disparities in diabetes-related outcomes.

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Acknowledgments

The findings and conclusions in this report are those of the authors and do not necessarily represent the official position of the Centers for Disease Control and Prevention. The authors report no conflicts of interest. No external funding was received for this study. No copyrighted materials were used in the conduct of this research or the writing of this article.

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Author Information

Corresponding Author: Ryan Saelee, PhD, Division of Diabetes Translation, National Center for Chronic Disease Prevention and Health Promotion, Centers for Disease Control and Prevention, 4770 Buford Hwy NE, MS S107-3, Atlanta, GA, 30341 (rsaelee@cdc.gov).

Author Affiliations: 1Division of Diabetes Translation, Centers for Disease Control and Prevention, Atlanta, Georgia. 2Center for the Study of Race, Ethnicity & Equity, Brown School at Washington University, St. Louis, Missouri.

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References

  1. Al-Shihabi F, Moore A, Chowdhury TA. Diabetes and climate change. Diabet Med. 2023;40(3):e14971. PubMed doi:10.1111/dme.14971
  2. Ratter-Rieck JM, Roden M, Herder C. Diabetes and climate change: current evidence and implications for people with diabetes, clinicians and policy stakeholders. Diabetologia. 2023;66(6):1003–1015. PubMed doi:10.1007/s00125-023-05901-y
  3. Gao D, Friedman S, Hosler A, Sheridan S, Zhang W, Lin S. Association between extreme ambient heat exposure and diabetes-related hospital admissions and emergency department visits: a systematic review. Hyg Environ Health Adv. 2022;4:100031. PubMed doi:10.1016/j.heha.2022.100031
  4. Hernández D. Understanding ‘energy insecurity’ and why it matters to health. Soc Sci Med. 2016;167:1–10. PubMed doi:10.1016/j.socscimed.2016.08.029
  5. US Energy Information Administration. Table HC11.1 Household energy insecurity. 2020. 2023. Accessed September 27, 2023. https://www.eia.gov/consumption/residential/data/2020/hc/pdf/HC%2011.1.pdf
  6. US Energy Information Administration. 2020 Residential Energy Consumption Survey: household characteristics technical documentation summary. 2023. Accessed February 29, 2024. https://www.eia.gov/consumption/residential/data/2020/pdf/2020%20RECS_Methodology%20Report.pdf
  7. United States Diabetes Surveillance System. US Department of Health and Human Services, Centers for Disease Control and Prevention, National Center for Chronic Disease Prevention and Health Promotion, Division of Diabetes Translation; 2024. Accessed August 17, 2023. https://gis.cdc.gov/grasp/diabetes/diabetesatlas-surveillance.html
  8. Dunnington D. ggspatial: Spatial Data Framework for ggplot2. 2023. Accessed April 29, 2024. https://paleolimbot.github.io/ggspatial/, https://github.com/paleolimbot/ggspatial
  9. US Census Bureau. Hispanic or Latino origin by race. American Community Survey, ACS 5-year estimates detailed tables, table B03002. 2020. Accessed on October 12, 2023. https://data.census.gov/table/ACSDT5Y2020.B03002?q=B03002&g=010XX00US,$0400000
  10. US Census Bureau. Poverty status in the past 12 months. American Community Survey, ACS 5-year estimates subject tables, table S1701. 2020. Accessed on October 12, 2023. https://data.census.gov/table/ACSST5Y2020.S1701?q=poverty&g=010XX00US,$0400000
  11. US Census Bureau. Urban and rural. Decennial census, DEC demographic and housing characteristics, table P2. 2020. Accessed on October 12, 2023.https://data.census.gov/table/DECENNIALDHC2020.P2?q=urban&g=010XX00US,$0400000
  12. US Census Bureau. Explore Census data. Accessed October 12, 2023. https://data.census.gov/
  13. Saelee R, Hora IA, Pavkov ME, Imperatore G, Chen Y, Benoit SR, et al. . Diabetes prevalence and incidence inequality trends among U.S. adults, 2008–2021. Am J Prev Med. 2023;65(6):973–982. PubMed doi:10.1016/j.amepre.2023.07.009
  14. Gaffney A, Himmelstein DU, Woolhandler S. Prevalence and correlates of patient rationing of insulin in the United States: a national survey. Ann Intern Med. 2022;175(11):1623–1626. PubMed doi:10.7326/M22-2477
  15. Widerynski S, Schramm PJ, Conlon KC, Noe RS, Grossman E, Hawkins M, et al. . Use of cooling centers to prevent heat-related illness: summary of evidence and strategies for implementation. Accessed April 23, 2024. https://stacks.cdc.gov/view/cdc/47657
  16. Yan AF, Chen Z, Wang Y, Campbell JA, Xue Q-L, Williams MY, et al. . Effectiveness of social needs screening and interventions in clinical settings on utilization, cost, and clinical outcomes: a systematic review. Health Equity. 2022;6(1):454–475. PubMed doi:10.1089/heq.2022.0010

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Table

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Table. Crude Prevalence of Energy Insecurity Measures and Receipt of Energy Assistance by State, 2020 Residential Energy Consumption Survey
State Any household energy insecurity,a % (95% CI) Reducing or forgoing food or medicine to pay energy costs, % (95% CI) Leaving the home at unhealthy temperature, % (95% CI) Receiving disconnect or delivery stop notice, % (95% CI) Unable to use heating equipment, % (95% CI) Unable to use air conditioning equipment, % (95% CI) Ever received energy assistance, % (95% CI)
Total 27.2 (26.4–28.0) 19.9 (19.2–20.6) 9.9 (9.3–10.5) 10.0 (9.5–10.5) 4.0 (3.6–4.4) 5.1 (4.7–5.5) 5.3 (4.9–5.7)
Alabama 33.7 (27.6–39.7) 27.2 (21.7–32.7) 14.6 (9.3–19.9) 11.2 (6.8–15.6) 7.0 (3.7–10.3) 8.7 (5.0–12.3) 3.5 (0.9–6.0)
Alaska 24.9 (20.0–29.9) 17.4 (13.3–21.6) 10.3 (6.7–13.9) 11.2 (6.6–15.7) 4.6 (2.0–7.3) b 7.9 (5.0–10.9)
Arizona 26.8 (22.9–30.7) 19.9 (16.0–23.7) 11.2 (8.3–14.2) 8.2 (5.8–10.6) 4.9 (2.9–7.0) 6.5 (4.2–8.9) 4.3 (2.1–6.6)
Arkansas 36.2 (30.0–42.4) 26.2 (20.5–31.9) 11.2 (6.3–16.0) 15.1 (10.3–19.9) 8.4 (5.0–11.9) 10.2 (6.3–14.0) 6.6 (2.7–10.4)
California 30.5 (27.8–33.3) 20.9 (18.4–23.4) 13.8 (11.7–15.8) 7.1 (5.3–8.9) 4.7 (3.4–6.0) 5.8 (4.2–7.3) 10.0 (8.1–11.8)
Colorado 23.6 (19.2–28.1) 18.3 (14.4–22.3) 7.7 (4.6–10.8) 8.0 (4.7–11.3) 3.0 (1.0–5.1) 3.8 (1.0–6.6) 5.8 (3.1–8.5)
Connecticut 27.0 (22.0–32.0) 19.7 (15.2–24.2) 13.3 (8.3–18.3) 9.2 (5.7–12.7) 5.4 (2.5–8.4) 5.3 (2.5–8.1) 5.9 (2.2–9.6)
Delaware 25.7 (17.9–33.5) 19.1 (12.5–25.7) 8.5 (3.7–13.3) 8.3 (3.7–12.9) 3.3 (0.1–6.4) 4.1 (0.8–7.3) b
District of Columbia 18.3 (12.7–23.8) 13.4 (8.4–18.4) 6.2 (3.1–9.3) 6.3 (2.5–10.0) 4.2 (1.3–7.1) 3.2 (0.8–5.6) 3.4 (0.6–6.2)
Florida 22.6 (19.4–25.7) 17.9 (14.9–20.9) 7.1 (4.6–9.5) 8.7 (6.1–11.3) 3.7 (2.2–5.2) 6.1 (4.0–8.3) b
Georgia 33.5 (28.9–38.1) 23.8 (19.2–28.5) 12.4 (8.4–16.3) 15.7 (12.0–19.4) 5.3 (2.6–7.9) 9.1 (6.3–11.9) 6.0 (3.4–8.5)
Hawaii 23.6 (18.5–28.6) 15.7 (11.2–20.1) 7.3 (4.1–10.4) 6.0 (2.7–9.3) 2.5 (0.5–4.6) 3.5 (1.2–5.8) 5.2 (2.0–8.3)
Idaho 19.3 (14.9–23.6) 14.2 (10.0–18.4) 7.1 (4.1–10.1) 7.1 (3.6–10.7) 1.5 (0.1–3.0) 3.4 (1.2–5.6) 7.4 (3.5–11.3)
Illinois 23.5 (19.3–27.6) 18.0 (14.3–21.7) 7.5 (4.9–10.1) 7.4 (4.7–10.1) 2.6 (1.1–4.1) 4.3 (2.4–6.2) 6.2 (3.8–8.5)
Indiana 28.9 (24.2–33.6) 22.4 (18.3–26.5) 8.5 (5.5–11.6) 14.9 (11.3–18.6) 4.8 (2.5–7.2) 5.1 (2.7–7.5) 3.3 (1.3–5.4)
Iowa 17.7 (13.0–22.3) 14.8 (10.3–19.3) 4.1 (1.5–6.8) 6.8 (3.7–9.9) b b 7.1 (3.5–10.6)
Kansas 25.4 (19.6–31.3) 15.2 (9.6–20.7) 8.1 (4.2–12.1) 8.4 (4.3–12.4) 2.7 (0.3–5.1) 4.5 (1.5–7.4) b
Kentucky 32.9 (27.1–38.8) 22.3 (17.3–27.2) 9.7 (6.5–12.9) 16.8 (12.3–21.3) 3.9 (2.0–5.8) 6.8 (4.1–9.4) 6.0 (3.6–8.3)
Louisiana 33.2 (28.2–38.2) 26.0 (21.0–31.1) 10.3 (7.1–13.6) 15.6 (11.4–19.8) 3.9 (1.8–6.0) 8.0 (4.7–11.3) 4.0 (1.3–6.8)
Maine 23.1 (17.4–28.8) 16.5 (11.0–22.0) 8.3 (4.2–12.3) 10.3 (4.9–15.8) 7.5 (3.6–11.4) 3.9 (1.2–6.6) 3.9 (1.3–6.4)
Maryland 22.5 (18.2–26.8) 16.7 (12.6–20.8) 9.0 (5.8–12.1) 10.0 (6.8–13.3) 2.8 (0.8–4.7) 4.0 (1.6–6.5) 3.9 (1.5–6.3)
Massachusetts 22.2 (17.4–27.1) 15.1 (10.4–19.7) 9.3 (6.4–12.2) 5.1 (3.0–7.1) 2.4 (1.0–3.8) 1.8 (0.7–3.0) 8.1 (5.2–11.0)
Michigan 29.4 (24.4–34.3) 20.9 (16.6–25.2) 9.1 (5.9–12.3) 10.9 (7.7–14.2) 3.8 (1.9–5.8) 2.6 (0.8–4.5) 5.1 (2.7–7.5)
Minnesota 16.5 (12.2–20.8) 12.6 (8.6–16.6) 4.0 (1.9–6.0) 5.3 (2.8–7.7) b 1.7 (0.3–3.1) 7.0 (3.9–10.2)
Mississippi 40.4 (32.0–48.8) 33.1 (25.5–40.8) 13.3 (8.4–18.2) 14.8 (8.6–20.9) 6.3 (2.4–10.3) 10.5 (6.2–14.7) 4.1 (0.3–8.0)
Missouri 26.8 (22.1–31.5) 21.1 (16.7–25.5) 9.3 (5.5–13.1) 15.6 (10.8–20.5) 8.5 (5.0–11.9) 6.8 (3.9–9.7) 5.1 (2.3–8.0)
Montana 24.4 (17.0–31.8) 18.3 (10.9–25.7) 7.8 (3.6–12.0) 9.0 (4.3–13.7) b 3.2 (0.3–6.2) 7.9 (2.9–13.0)
Nebraska 16.8 (10.3–23.3) 11.8 (6.2–17.4) 5.6 (1.5–9.7) 7.1 (3.1–11.0) 3.3 (0.5–6.1) b 3.8 (0.4–7.2)
Nevada 29.4 (22.0–36.9) 22.1 (15.8–28.4) 13.1 (7.3–18.9) 9.4 (5.0–13.7) 6.1 (1.7–10.5) 6.5 (2.6–10.5) 3.7 (0.3–7.0)
New Hampshire 22.6 (15.7–29.5) 12.2 (6.3–18.1) 5.6 (1.8–9.5) 9.6 (4.9–14.3) 3.0 (0.3–5.6) 5.2 (1.9–8.5) 3.1 (0.3–5.9)
New Jersey 25.3 (21.0–29.6) 18.4 (14.5–22.3) 8.6 (5.3–12.0) 10.2 (7.2–13.2) 2.7 (1.1–4.3) 4.9 (2.7–7.1) 5.3 (3.0–7.7)
New Mexico 25.4 (19.1–31.7) 15.7 (9.7–21.8) 11.5 (6.2–16.8) 5.7 (1.9–9.5) 4.3 (0.7–7.9) 3.2 (0.4–6.1) 7.5 (3.1–11.8)
New York 27.8 (24.8–30.8) 18.3 (15.8–20.9) 12.7 (10.3–15.0) 9.1 (7.0–11.2) 3.3 (1.9–4.8) 4.5 (2.8–6.2) 6.3 (4.5–8.0)
North Carolina 27.5 (23.3–31.6) 20.4 (16.2–24.6) 9.4 (6.3–12.5) 11.6 (8.3–15.0) 3.3 (1.3–5.2) 4.6 (2.7–6.6) 3.6 (1.8–5.4)
North Dakota 21.4 (15.7–27.0) 14.2 (9.4–18.9) 9.1 (5.3–12.9) 9.7 (6.2–13.2) 2.0 (0.4–3.6) 4.4 (1.8–7.0) 4.3 (1.8–6.9)
Ohio 26.1 (21.5–30.8) 18.2 (14.3–22.2) 7.4 (4.4–10.5) 15.3 (11.1–19.5) 4.1 (1.7–6.4) 4.4 (2.1–6.6) 6.9 (3.8–10.1)
Oklahoma 34.2 (28.0–40.5) 25.9 (20.2–31.6) 12.0 (6.5–17.5) 17.1 (11.7–22.5) 8.9 (4.5–13.3) 10.7 (6.3–15.1) 5.6 (2.3–8.9)
Oregon 21.4 (16.2–26.6) 16.7 (12.0–21.4) 9.3 (5.3–13.3) 3.7 (1.4–6.0) 3.0 (0.9–5.1) 3.6 (1.2–5.9) 3.3 (1.2–5.5)
Pennsylvania 23.9 (20.1–27.8) 17.3 (13.8–20.9) 11.0 (8.2–13.7) 7.8 (5.5–10.1) 3.8 (2.2–5.5) 2.9 (1.6–4.2) 5.7 (3.4–8.0)
Rhode Island 23.3 (15.6–31.0) 15.4 (9.3–21.5) 10.4 (4.7–16.0) 7.0 (2.3–11.7) 9.4 (4.8–14.0) 3.7 (0.3–7.2) 4.1 (1.3–7.0)
South Carolina 32.1 (26.9–37.3) 26.4 (21.6–31.2) 10.7 (6.9–14.5) 14.5 (10.6–18.5) 5.0 (2.8–7.2) 7.2 (4.1–10.4) 3.2 (1.3–5.2)
South Dakota 20.1 (12.5–27.8) 16.1 (9.2–23.0) 6.9 (2.0–11.8) 6.3 (2.4–10.2) b 2.3 (0.0–4.6) 6.7 (2.6–10.7)
Tennessee 27.5 (23.7–31.3) 22.0 (18.2–25.8) 9.8 (7.0–12.6) 11.7 (8.6–14.8) 4.1 (2.0–6.2) 6.9 (4.3–9.5) 4.0 (2.3–5.7)
Texas 34.5 (31.2–37.8) 26.2 (23.1–29.4) 10.2 (8.0–12.5) 13.0 (10.8–15.3) 4.4 (3.3–5.4) 6.0 (4.3–7.7) 3.3 (2.1–4.6)
Utah 19.1 (12.8–25.5) 11.9 (6.3–17.6) 4.6 (1.1–8.2) 9.0 (4.2–13.8) 5.2 (1.2–9.2) 4.9 (1.5–8.3) 3.6 (0.3–6.9)
Vermont 14.7 (10.4–19.0) 11.7 (7.6–15.9) 5.0 (2.3–7.7) 4.7 (2.2–7.2) 4.7 (2.1–7.3) b 4.4 (1.8–7.0)
Virginia 24.7 (20.4–28.9) 17.8 (14.0–21.5) 8.3 (5.4–11.2) 7.3 (5.0–9.6) 2.9 (1.2–4.6) 3.7 (2.0–5.4) 3.1 (1.2–5.0)
Washington 22.0 (17.3–26.6) 15.2 (11.0–19.4) 9.2 (5.9–12.5) 7.5 (4.3–10.7) 1.5 (0.3–2.6) 2.1 (0.7–3.6) 3.7 (1.9–5.6)
West Virginia 37.3 (30.4–44.2) 30.4 (24.0–36.8) 14.4 (8.9–19.8) 14.3 (9.3–19.3) 7.5 (3.6–11.4) 11.8 (6.7–16.9) 5.9 (2.6–9.2)
Wisconsin 20.5 (15.6–25.3) 15.6 (11.3–19.8) 6.6 (3.6–9.6) 4.7 (2.6–6.7) 1.3 (0.1–2.4) 3.6 (1.2–6.0) 9.1 (5.5–12.6)
Wyoming 20.7 (13.8–27.6) 14.0 (8.3–19.6) 6.7 (2.9–10.5) 7.6 (3.1–12.1) 3.6 (0.5–6.8) b 6.0 (2.5–9.4)

a Defined as having 1 of these 5 experiences: having to reduce or forgo food or medicine to pay energy costs, leaving the home at unhealthy temperatures, receiving disconnect or delivery stop notice, being unable to use heating equipment due to cost, or being unable to use air-conditioning equipment because of cost.
b Suppressed because of a relative standard error >50%.

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