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Food insecurity and sleep health by race/ethnicity in the United States

Published online by Cambridge University Press:  18 May 2023

Dana M. Alhasan
Affiliation:
Epidemiology Branch, National Institute of Environmental Health Sciences, National Institutes of Health, Department of Health and Human Services, Research Triangle Park, NC, USA
Nyree M. Riley
Affiliation:
Epidemiology Branch, National Institute of Environmental Health Sciences, National Institutes of Health, Department of Health and Human Services, Research Triangle Park, NC, USA
W. Braxton Jackson II
Affiliation:
Social & Scientific Systems, Inc., a DLH Holdings Company, Durham, NC, USA
Chandra L. Jackson*
Affiliation:
Epidemiology Branch, National Institute of Environmental Health Sciences, National Institutes of Health, Department of Health and Human Services, Research Triangle Park, NC, USA Intramural Program, National Institute on Minority Health and Health Disparities, National Institutes of Health, Department of Health and Human Services, Bethesda, MD, USA
*
*Corresponding author: Chandra L. Jackson, fax 301-480-3290, email [email protected]

Abstract

Food insecurity, poised to increase with burgeoning concerns related to climate change, may influence sleep, yet few studies examined the food security-sleep association among racially/ethnically diverse populations with multiple sleep dimensions. We determined overall and racial/ethnic-specific associations between food security and sleep health. Using National Health Interview Survey data, we categorised food security as very low, low, marginal and high. Sleep duration was categorised as very short, short, recommended and long. Sleep disturbances included trouble falling/staying asleep, insomnia symptoms, waking up feeling unrested and using sleep medication (all ≥3 d/times in the previous week). Adjusting for socio-demographic characteristics and other confounders, we used Poisson regression with robust variance to estimate prevalence ratios (PRs) and 95 % confidence intervals (95 % CIs) for sleep dimensions by food security. Among 177 435 participants, the mean age of 47⋅2 ± 0⋅1 years, 52⋅0 % were women, and 68⋅4 % were non-Hispanic (NH)-White. A higher percent of NH-Black (7⋅9 %) and Hispanic/Latinx (5⋅1 %) lived in very low food security households than NH-White (3⋅1 %) participants. Very low v. high food security was associated with a higher prevalence of very short (PR = 2⋅61 [95 % CI 2⋅44–2⋅80]) sleep duration as well as trouble falling asleep (PR = 2⋅21 [95 % CI 2⋅12–2⋅30]). Very low v. high food security was associated with a higher prevalence of very short sleep duration among Asian (PR = 3⋅64 [95 % CI 2⋅67–4⋅97]) and NH-White (PR = 2⋅73 [95 % CI 2⋅50–2⋅99]) participants compared with NH-Black (PR = 2⋅03 [95 % CI 1⋅80–2⋅31]) and Hispanic/Latinx (PR = 2⋅65 [95 % CI 2⋅30–3⋅07]) participants. Food insecurity was associated with poorer sleep in a racially/ethnically diverse US sample.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © National Institutes of Health, 2023. To the extent this is a work of the US Government, it is not subject to copyright protection within the United States. Published by Cambridge University Press on behalf of The Nutrition Society

Introduction

Food insecurity – a major public health concern – is defined as limited ability or lack of access for households to provide sufficient food for an active, healthy life among all household members(Reference Coleman-Jensen, Rabbitt and Hashad1). In 2020, it was estimated that 38 million people in the United States (US) lived in food insecure households where 9⋅4 million adults lived in very low food secure households(Reference Coleman-Jensen, Rabbitt and Hashad2). When one or more household members lacked sufficient financial resources, disruptions to their eating pattern occurred thus reducing food intake(Reference Coleman-Jensen, Rabbitt and Hashad2). Additionally, food insecurity disproportionately impacts minoritised racial/ethnic adults in the US including Black/African Americans, hereafter non-Hispanic (NH)-Black, and Hispanic/Latinx, compared with NH-White adults(Reference Coleman-Jensen, Rabbitt and Hashad2). Based on the US Department of Agriculture (USDA), NH-Black (21⋅7 %) and Hispanic/Latinx (17⋅2 %) households have higher food insecurity prevalence compared with NH-White households (7⋅1 %)(Reference Coleman-Jensen, Rabbitt and Hashad2). Similarly, food insecurity differentially impacts women where food insecure women compared with men are less likely to meet the recommended dietary intake(Reference Ma, Ho and Singh3).

Food insecurity negatively impacts the health of household members where the lack of a nutritious diet is associated with chronic illnesses, such as type II diabetes mellitus, chronic kidney disease, cardiovascular diseases(Reference Abdurahman, Chaka and Nedjat4Reference Liu and Eicher-Miller6), as well as sleep(Reference Lee, Deason and Rancourt7). The uncertainty of when one's next meal will be or even being forced to make decisions between paying a bill (e.g. rent) v. buying food heightens psychological distress thus activating the sympathoadrenal medullary system and hypothalamic–pituitary–adrenal (HPA) axis, which are both implicated in poor sleep health(Reference Vgontzas and Chrousos8). Psychological distress has been shown to impact sleep(Reference Goldstein, Gaston and McGrath9). Additionally, malnutrition hinders the body from appropriately assimilating nutrients and subsequently leads to immune deficiency potentially placing individuals at higher risk for recurrent infections and chronic inflammation(Reference Bourke, Berkley and Prendergast10) that in turn may alter sleep(Reference Besedovsky, Lange and Haack11). Therefore, there are both indirect and direct pathways by which sleep may be affected by food security status. Since sleep is a modifiable health behaviour that has been identified as a risk factor for chronic illnesses, it may be fundamental to addressing racial/ethnic inequities(Reference Jackson, Redline and Emmons12). Furthermore, a review has highlighted that minoritised racial/ethnic groups are more likely to experience shorter sleep(Reference Jackson, Walker and Brown13). It has also been found that women are more likely to be diagnosed with insomnia or report difficulty falling and staying asleep(Reference Jackson, Powell-Wiley and Gaston14).

Predominantly NH-White v. NH-Black neighbourhoods have, on average, four times as many grocery stores(Reference Morland, Wing and Diez Roux15). Fewer grocery stores coupled with other limited resources (e.g. limited transportation; less high-paying jobs) lessen the ability to access viable quality and quantity food options, worsen food security status and subsequently sleep(Reference Troxel, Haas and Ghosh-Dastidar16,Reference Ding, Keiley and Garza17) . These disparities are likely due to structural racism where policies translate and equate to limited material resources in minoritised racial/ethnic neighbourhoods(Reference Odoms-Young and Bruce18). Therefore, it is likely that lower food security status may be related to poorer sleep health, including more sleep disturbances, among minoritised populations. Food insecurity and sleep are both important modifiable factors making it important to investigate the food security status–sleep health relationship among racially/ethnically diverse US adults. Additionally, it is important to know who is most impacted by food insecurity and poor sleep health to implement intervention strategies aimed at certain subgroups.

Despite its importance, few studies have been conducted in the US(Reference Jordan, Perez-Escamilla and Desai19). Among these few studies, most do not consider racial/ethnic differences in food security status and sleep health(Reference Ding, Keiley and Garza17,Reference Becerra, Bol and Granados20,Reference Liu, Njai and Greenlund21) and even fewer include NH-Asians(Reference Narcisse, Long and Felix22Reference Whinnery, Jackson and Rattanaumpawan24). Furthermore, some studies do not assess multiple domains of food security status(Reference Narcisse, Long and Felix22,Reference Nagata, Palar and Gooding25) . Prior studies of food insecurity and sleep health have been limited by their usage of small, non-diverse populations, lack of investigation by race/ethnicity(Reference Ding, Keiley and Garza17) and sex/gender despite potential unique experiences, absence of multiple sleep dimensions beyond duration(Reference Whinnery, Jackson and Rattanaumpawan24), and lack of a usage of a validated food security scale(Reference Liu, Njai and Greenlund21). To overcome these research gaps, we sought to assess the prevalence of food security status and sleep health by race/ethnicity, to determine the association between food security status and sleep health, and to assess potential racial/ethnic variation in this association within a population of NH-White, NH-Black, Hispanic/Latinx and NH-Asian US women and men. We hypothesised that the prevalence of food security status and poorer sleep health will be higher among minoritised compared with NH-White women and men. We also hypothesised that participants with very low, low and marginal v. high food security status will have a higher prevalence of shorter sleep duration and more sleep disturbances and that this will be stronger among minoritised compared with NH-White women and men. We further hypothesised that minoritised racial/ethnic groups with very low, low, marginal and high food security status will have a higher prevalence of poorer sleep quality v. NH-White adults with high food security status.

Methods

Data source: National Health Interview Survey

We collected participant data from the National Health Interview Study (NHIS). The NHIS – a series of annual, cross-sectional, household surveys – is conducted via computer-assisted in-person interviews among non-institutionalised US citizen adults by trained interviewers. To obtain a nationally representative sample, the NHIS utilises a three-stage stratified cluster probability sampling design. All publicly available NHIS data has been extensively reviewed by the National Center for Health Statistics’ Disclosure Review Board to protect the confidentiality of survey participants, and a detailed description of NHIS procedures has been previously published(26). We used survey data from 2013 to 2018 to increase sample size and decrease likelihood of non-representative results stemming from data collected in a single year. The national prevalence of food insecurity ranged from 11% to 14 % during this timeframe(Reference Coleman-Jensen27). The final response rate for sampled adults was 56⋅1 % (range: 61⋅2 % (2013) – 53⋅1 % (2018)). Furthermore, each study participant provided informed consent to the NHIS, and the National Institute of Environmental Health Sciences’ Institutional Review Board waived approval for this study as de-identified, publicly available data are not classified as human subjects’ research.

Study population

Among 190 113 participants ≥18 years old, those with missing data regarding food security status (n 44), sleep duration (n 6126), sleep disturbances (n 1643) and race/ethnicity (n 3464) were excluded, as well as those who self-identified as Native American and multiple additional racial/ethnic groups (n 1401) due to a small sample size. These exclusions resulted in a final analytic sample of 177 435 participants (Supplementary Figure S1).

Exposure assessment: food security status

Food security status was measured via the routinely used tool to monitor food security: the US Household Food Security Survey Module (HFSSM) based on the USDA Economic Research Service recommendations(Reference Coleman-Jensen, Rabbitt and Hashad28). This screening tool was adopted from the 18-item household module to have less respondent burden and avoided asking questions about children's food security. It consisted of ten questions about food availability and consumption in the past 30 d where participants answered yes v. no (Supplementary Table S1). For example, participants answered questions about their households if they ‘worried whether food would run out before we got money to buy more’; ‘the food we bought just didn't last, and didn't have money to get more’; ‘we couldn't afford to eat balanced meals’ and ‘you or other adults in family ever cut the size of your meals or skip meals because there wasn't enough money for food?’. Among those who answered ‘yes’, participants answered often true, sometimes true, v. never true (3 d or more v. <3 d). Affirmative responses were summed, ranged from 0 to 10, and categorised as high food security (0), marginal food security (1–2), low food security (3–5) and very low food security (6–10) based on USDA coding(Reference Coleman-Jensen, Rabbit and Hashad29).

Outcome assessment: sleep duration and sleep disturbances

Participants answered the following question regarding sleep duration, ‘On average, how many hours of sleep do you get in a 24 h period?’. Responses were reported in hours using whole numbers and rounded up values equal to or greater than 30 min to the nearest hour and rounded down values less than 30 min to the nearest hours. Based on the recommendation of the National Sleep Foundation categories(Reference Hirshkowitz, Whiton and Albert30) that have been previously validated(Reference Watson, Badr and Belenky31), the following sleep duration categories were used: very short sleep (<6 h), short sleep (<7 h), recommended sleep (7–9 h) and long sleep (≥9 h). Categories of very short and short were not mutually exclusive.

Participants answered the following four questions regarding sleep disturbances: (1) ‘In the past week, how many times did you have trouble falling asleep?’; (2) ‘In the past week, how many times did you have trouble staying asleep?’; (3) ‘In the past week, how many times did you take medication to help you fall asleep or stay asleep?’ and (4) ‘In the past week, how many days did you wake up feeling rested?’ A response of 3 d/times or more a week indicated a self-reported sleep disturbance: trouble falling asleep, trouble staying asleep, sleep medication use and waking up feeling unrested. We also defined insomnia symptoms as having trouble falling or staying asleep 3 or more nights per week v. less than 3 nights per week in efforts to capture people with moderate to severe rather than occasional insomnia symptoms.

Potential confounders

Confounders were based on a priori literature. Since the NHIS uses self-reported data for sex where it is unclear how participants perceived this question, we combined sex and gender, hereafter, sex/gender (women/men). We included race (White, African American or Black, Hispanic/Latinx or Asian) and ethnicity (non-Hispanic/Latinx or Hispanic/Latinx), which we combined since these categories are mutually exclusive; therefore, race/ethnicity consisted of NH-White, NH-Black, Hispanic/Latinx and NH-Asian. Other potential socio-demographic confounders included age (18–30, 31–50 or ≥50), educational attainment (<high school, high school, some college or ≥college graduate), annual household income (<$35 000, $35 000–$74 999 and ≥$75 000), employment status (employed/in labour force or unemployed/not in labour force), occupational class (professional/management, support services or labourers), marital status (married/living with partners/co-habitating, divorced/widowed or single/no live-in partner) and region of residence (Northeast, Midwest, South and West). We did not consider health behaviours, such as smoking status, or clinical characteristics, such as severe psychological distress, because they are considered potential mediators of the relationship between food security status and sleep health(Reference Liu, Njai and Greenlund21,Reference Spadola, Guo and Johnson32) .

Potential modifiers: sex/gender and race/ethnicity

Sex/gender was assessed in a binary manner and dichotomised between women v. men. Race/ethnicity was categorised as NH-White alone, NH-Black alone, Hispanic/Latinx of any race and NH-Asian.

Statistical analyses

Descriptive statistics were computed; continuous variables were presented as means and standard errors (se), and categorical variables were presented as weighted percentages after applying direct age standardisation using the 2010 US Census as the standard population. We compared the four levels of food security status (very low, low, marginal and high) across socio-demographic, health behaviours and clinical characteristics for all participants.

To test associations between food security and sleep dimensions, we used Poisson regression with robust variance as a valid approach to directly estimate prevalence ratios (PRs)(Reference Barros and Hirakata33) and 95 % confidence intervals (CIs) of very low, low, marginal v. high food security for each sleep dimension overall and by race/ethnicity and by sex/gender. This model with adjusted variances is used for either count or binary data for cross-sectional (or longitudinal) studies to provide accurate point and interval estimates, correct standard errors when over or under-dispersion is observed and directly estimate PRs(Reference Barros and Hirakata33). Unlike odds ratios estimated from logistic regression models, PRs do not overestimate associations with outcomes of high prevalence (e.g. poor sleep health). PRs are also easier to interpret and communicate(Reference Barros and Hirakata33).

We also compared very low, low, marginal and high food security among minoritised racial/ethnic groups to NH-White participants with high food security. The overall model was adjusted for the following confounders: age, race/ethnicity, sex/gender, educational attainment, annual household income, employment status, occupational class, region of residence, marital/co-habitating status and employment status. To test for differences by race/ethnicity and by sex/gender and food security status, we added respective interaction terms (e.g. food security status*race/ethnicity; food security status*sex/gender) to the overall model. Analyses were conducted using SAS version 9.4 for Windows (Cary, North Carolina), and a two-sided P-value of 0⋅05 was used to determine statistical significance.

Results

Study population characteristics

Among 177 435 participants, the majority (82⋅9 %) lived in households with high food security status followed by marginal (6⋅8 %), low (5⋅7 %) and very low (4⋅5 %) (Table 1). The mean age was 47⋅2 ± 0⋅09 years. Approximately 52⋅0 % were women and 68⋅4 % self-identified as NH-White, 11⋅4 % as NH-Black, 14⋅6 % as Hispanic/Latinx and 5⋅6 % as NH-Asian. NH-Black participants lived in higher percentage of households with very low food security status (23⋅9 %) compared with high food security status (9⋅7 %), while NH-White and NH-Asian participants lived in higher percentage of households with high food security status (71⋅3 and 6⋅0 %, respectively) compared to a very low food security status (54⋅4 and 2⋅4 %, respectively) (Table 1).

Table 1. Age-standardised socio-demographic, health behaviour and clinical characteristics between very low, low, marginal and high food security, National Health Interview Survey, 2013–2018 (N 177 435)a

se, standard error.

a Notes: All estimates are weighted for the survey's complex sampling design. All estimates are age-standardised to the US 2010 population, except for age. Percentage may not sum to 100 due to missing values or rounding.

b Meets PA guidelines defined as ≥150 min/week of moderate intensity or ≥75 min/week of vigorous intensity or ≥150 min/week of moderate and vigorous intensity.

c Insomnia symptoms defined as either trouble falling or staying asleep 3+ days a week.

d Kessler 6-psychological distress scale score ≥13.

e Dyslipidaemia defined as high cholesterol in the 12 months prior to interview. Available for survey years 2011–2017.

f Hypertension defined as ever told by a doctor had hypertension.

g Prediabetes defined as ever told by a doctor had prediabetic condition.

h Type 2 Diabetes Mellitus defined as ever told by a doctor or health professional that you have diabetes or sugar diabetes.

i ‘Ideal’ cardiovascular health includes never smoking/quit >12 months prior to interview, BMI 18⋅5 to <25 kg/m2, meeting physical activity guidelines, and no prior diagnosis of dyslipidemia, hypertension, or prediabetes.

Most participants (64⋅4 %) reported the recommended hours of sleep (7–9 h). The prevalence of recommended sleep was greatest in households with high food security status (66⋅7 %) compared with marginal (55⋅9 %), low (53⋅1 %) and very low (42⋅7 %). The most reported sleep problem was waking up feeling unrested (43⋅0 %) followed by insomnia symptoms (33⋅2 %), trouble staying asleep (27⋅4 %), trouble falling asleep (20⋅1 %) and taking sleep medications ≥3 nights per week (9⋅8 %). The prevalence of sleep disturbances was highest among those living in households with very low food security status and subsequently decreased as food security status increased. For example, those living in households with very low and low food security status had a higher percentage of very short sleep (23⋅6 and 15⋅5 %, respectively) compared to those with high food security status (7⋅7 %) (Table 1).

A higher percent of NH-Black (7⋅9 %) and Hispanic/Latinx (5⋅1 %) lived in households with very low food security compared with NH-White (3⋅1 %) participants (Fig. 1). Likewise, a higher percent of NH-Black (9⋅9 %) and Hispanic/Latinx (9⋅2 %) lived in households with low food security compared with NH-White (3⋅6 %) and NH-Asian (3⋅2 %) (Fig. 1).

Fig. 1. Food security status by race/ethnicity between very low, low, marginal and high food security, National Health Interview Survey, 2013–2018 (N 177 435).

NH-Black (24⋅3 %) and Hispanic/Latinx (20⋅5 %) participants reported higher percentage of being worried whether food would run out before they got money to buy more compared with NH-White (9⋅5 %) participants (Supplementary Table S1). Women reported a higher percentage living in households with very low food security (59⋅1 %) compared with 40⋅9 % of men (Supplementary Figure S2).

Participants living in households with very low and low food security status had a higher percentage of very short sleep (9⋅7 and 8⋅6 %, respectively), short sleep (6⋅0 and 6⋅6 %, respectively) and long sleep (7⋅4 and 8⋅4 %, respectively) compared with recommended sleep (2⋅5 and 4⋅2 %, respectively) (Supplementary Figure S3).

Food insecurity and sleep health

Overall, participants living in households with very low food security v. high food security had a higher prevalence of very short sleep (PR = 2⋅61 [95 % CI 2⋅44–2⋅80]), trouble falling asleep (PR = 2⋅21 [95 % CI 2⋅12–2⋅30]) and using sleep medication (PR = 2⋅22 [95 % CI 2⋅07–2⋅37]), after adjustment (Table 2). Similar patterns emerged with low and marginal v. high food security where point estimates were higher in low v. high compared with marginal v. high food security (Table 2).

Table 2. Prevalence ratios of sleep health among participants reporting very low, low and marginal compared with high food security by sex/gender and race/ethnicity, National Health Interview Survey, 2013–2018 (N 177 435)

Overall model adjusted for age (18–30, 31–50, ≥50), sex/gender (women or men), race/ethnicity (NH-White, NH-Black, Hispanic/Latinx and NH-Asian/PI), educational attainment (<high school, high school graduate, some college, ≥college), annual household income (<$35 000, $35 000–$74 999, $75 000+), occupational class (professional/management, support services, labourers), region of residence (Northeast, Midwest, South, West), marital/co-habiting status(married/living with partner or co-habitating, divorced/widowed/separated, single/no live-in partner) and employment status (unemployed, employed).

Reference level: high food security.

Note. All estimates are weighted for the survey's complex sampling design. Boldface indicates statistically significant results at the 0⋅05 level.

a Insomnia symptoms defined as either trouble staying or falling asleep 3+ times a week.

Interaction term between food security status and race/ethnicity was statistically significant (P-value < 0⋅00001) but was not between food security status and sex/gender (P-value = 0⋅1059).

Food insecurity and sleep health by sex/gender

Men living in households with very low v. high food insecurity had a higher prevalence of trouble staying asleep (PR = 2⋅11 [95 % CI 1⋅98–2⋅25]) and insomnia symptoms (PR = 2⋅00 [95 % CI 1⋅89–2⋅11]) than women (PR = 1⋅90 [95 % CI 1⋅82–1⋅99]; PR = 1⋅80 [95 % CI 1⋅74–1⋅87], respectively), after adjustment (Table 2). Both men and women living in households with very low, low and marginal v. high food security status had a similar prevalence of sleep duration, trouble falling asleep, waking up feeling unrested and using sleep medications. For example, very low v. high food security was associated with an over two-fold time the prevalence of very short sleep among men (PR = 2⋅62 [95 % CI 2⋅36–2⋅91]) and women (PR = 2⋅61 [95 % CI 2⋅41–2⋅82]) (Table 2).

Food insecurity and sleep health by race/ethnicity

Living in households with very low v. high food security status was associated with very short sleep duration among NH-Asian (PR = 3⋅64 [95 % CI 2⋅67–4⋅97]), NH-White (PR = 2⋅73 [95 % CI 2⋅50–2⋅99]), Hispanic/Latinx (PR = 2⋅65 [95 % CI 2⋅30–3⋅07]) and NH-Black (PR = 2⋅03 [95 % CI 1⋅80–2⋅31]) adults, after adjustment (Table 2). Similar patterns emerged with very low v. high food security status and short sleep duration across racial/ethnic groups.

Living in households with low v. high food security status was associated with very short sleep duration among NH-Asian (PR = 2⋅04 [95 % CI 1⋅38–3⋅02]), NH-White (PR = 1⋅97 [95 % CI 1⋅80–2⋅16]), Hispanic/Latinx (PR = 1⋅54 [95 % CI 1⋅32–1⋅81]) and NH-Black (PR = 1⋅44 [95 % CI 1⋅26–1⋅64]), after adjustment. Similar patterns emerged with low v. high food security status and short sleep duration across racial/ethnic groups, although the point estimate was higher in NH-Black than Hispanic/Latinx participants. There was no statistically significant modification by race/ethnicity for low v. high food security and long sleep duration.

Living in households with marginal food security status was associated with very short sleep duration among NH-Asian (PR = 1⋅80 [95 % CI 1⋅29–2⋅52]), NH-White (PR = 1⋅72 [95 % CI 1⋅56–1⋅89]), Hispanic/Latinx (PR = 1⋅24 [95 % CI 1⋅06–1⋅46]) and NH-Black (PR = 1⋅19 [95 % CI 1⋅03–1⋅38]) counterparts with high food security, after adjustment. Similar patterns emerged with marginal v. high food security status and short sleep duration across racial/ethnic groups. There was no interaction by race/ethnicity for marginal v. high food security and long sleep duration.

Hispanic/Latinx participants who lived in households with very low v. high food security status had 2⋅47 (95 % CI 2⋅24–2⋅73) times the prevalence of trouble falling asleep, 2⋅18 (95 % CI 1⋅97–2⋅31) times the prevalence of trouble staying asleep, 2⋅12 (95 % CI 1⋅95–2⋅31) times the prevalence of insomnia symptoms and 2⋅76 (95 % CI 2⋅32–3⋅29) times the prevalence of using of sleep medications, after adjustment. NH-Asian participants who lived in households with very low v. high food security status had 2⋅69 (95 % CI 2⋅05–3⋅55) times the prevalence of trouble staying asleep, after adjustment (Table 2).

Food insecurity and sleep health by minoritised racial/ethnic groups compared with NH-White participants with high food security

Compared with NH-White participants with high food security, NH-Black participants who lived in households with very low (PR = 2⋅81 [95 % CI 2⋅50–3⋅16]), low (PR = 1⋅94 [95 % CI 1⋅72–2⋅19]) and marginal (PR = 1⋅66 [95 % CI 1⋅44–1⋅92]) food security had a higher prevalence of very short sleep duration (Table 3). Among Hispanic/Latinx participants, living in households with very low food security was associated with a higher prevalence of very short (PR = 2⋅22 [95 % CI 1⋅92–2⋅56]) and short sleep duration (PR = 1⋅50 [95 % CI 1⋅39–1⋅61]) as well as more sleep disturbances. For example, Hispanic/Latinx living in households with very low food security had an 83 % (PR = 1⋅83 [95 % CI 1⋅67–2⋅01]) higher prevalence of trouble falling asleep compared with NH-Whites with high food security. Among NH-Asian participants, living in households with very low (PR = 3⋅75 [95 % CI 2⋅83–4⋅95]), low (PR = 2⋅07 [95 % CI 1⋅41–3⋅02]), marginal (PR = 1⋅81 [95 % CI 1⋅32–2⋅47]) and high (PR = 1⋅18 [95 % CI 1⋅05–1⋅32]) food security was associated with a higher prevalence of very short sleep duration.

Table 3. Prevalence ratios of sleep health among minoritised racial/ethnic groups reporting very low, low, marginal and high compared with NH-White participants with high food security, National Health Interview Survey, 2013–2018 (N 177 435)

Model adjusted for age (18–30, 31–50, ≥50), sex/gender (women or men), educational attainment (<high school, high school graduate, some college, ≥college), annual household income (<$35 000, $35 000–$74 999, $75 000+), occupational class (professional/management, support services, labourers), region of residence (Northeast, Midwest, South, West), marital/co-habiting status(married/living with partner or co-habitating, divorced/widowed/separated, single/no live-in partner) and employment status (unemployed, employed).

Reference level: NH-White with high food security.

Note. All estimates are weighted for the survey's complex sampling design. Boldface indicates statistically significant results at the 0⋅05 level.

a Insomnia symptoms defined as either trouble staying or falling asleep 3+ times a week.

Compared with NH-White participants living in households with high food security, minoritised racial/ethnic groups had lower sleep disturbances. For example, NH-Black (PR = 0⋅79 [95 % CI 0⋅76–0⋅83]), Hispanic/Latinx (PR = 0⋅72 [95 % CI 0⋅69–0⋅75]) and NH-Asian (PR = 0⋅55 [95 % CI 0⋅52–0⋅59]) participants living in households with high food security status had less insomnia symptoms.

Discussion

In our large nationally representative, racially/ethnically diverse sample of the US population, the prevalence of food insecurity was highest among NH-Black adults followed by Hispanic/Latinx, NH-White and NH-Asian adults. We also found that living in households with lower food security status was associated with poorer sleep health, which aligned with our hypothesis. While we observed a similar prevalence of sleep duration among women and men living in households with very low v. high food security status, there was a higher prevalence of sleep disturbances among men compared with women contrary to our hypothesis. Also inconsistent with our hypothesis, we reported stronger associations between food insecurity and very short as well as short sleep duration among NH-Asian and NH-White adults than Hispanic/Latinx and NH-Black adults. However, stronger associations were observed among Hispanic/Latinx living in households with very low v. high food security status and sleep disturbances (e.g. trouble falling asleep). Furthermore, we found a ‘dose response’ relationship between very low, low and marginal food security status and sleep duration among minoritised racially/ethnically adults (e.g. NH-Black adults) v. NH-White adults living in households with high food security status, consistent with our hypothesis.

Similar to prior literature, we observed participants living in households with lower v. higher food security status was associated with poorer sleep health(Reference Ding, Keiley and Garza17) including in studies of college students(Reference Becerra, Bol and Granados20) and adolescents(Reference Nagata, Palar and Gooding25) as well as studies using objectively measured sleep dimensions(Reference Troxel, Haas and Ghosh-Dastidar16). For example, a study using data from BRFSS (Behavioral Risk Factor Surveillance System) across twelve states found that the prevalence of insufficient sleep was significantly higher among food insecure individuals(Reference Liu, Njai and Greenlund21). A meta-analysis of eight cross-sectional studies reported food insecurity v. security was associated with increased odds of sleep disorders, such as insomnia symptoms(Reference Arenas, Thomas and Wang34). Another recent meta-analysis found severity of food insecurity levels to be associated with poorer sleep quality, including trouble falling asleep, trouble staying asleep and shorter sleep duration(Reference Mazloomi, Talebi and Kazemi35).

Even though few studies have examined the food security status–sleep health relationship by sex/gender, our findings corroborate the currently scant prior literature(Reference Ding, Keiley and Garza17). For example, a NHANES (National Health and Nutrition Examination Survey) study found women but not men with very low v. high food security reported significantly shorter sleep duration(Reference Ding, Keiley and Garza17). Our NHIS study expands on these results by demonstrating this association among individuals with very low v. high food security and higher prevalence of both very short and short sleep duration. This demonstrates that individuals on the margins of society (i.e. very low food security; very short sleep) are most impacted by disadvantage. Moreover, our findings further expand on these results by illustrating both women and men, and not only women(Reference Ding, Keiley and Garza17), with very low v. high food security status had a higher prevalence of shorter sleep duration. Because of our larger sample size (177 435 v. 10 901), our study was more likely able to detect meaningful differences among men. Therefore, the threshold appeared different for men, which is important to consider when designing interventions.

While there were stronger associations of sleep duration (e.g. very short sleep) among NH-White and NH-Asian adults living in households with very low v. high food security status compared with Hispanic/Latinx and NH-Black adults, we observed both higher levels of food insecurity and poor sleep health measures among NH-Black and Hispanic/Latinx adults. Of note, we reported NH-Asian adults with very low v. high food security status had the highest prevalence of very short sleep duration compared with other racial/ethnic groups. This finding fills a gap in the literature by demonstrating an association between food insecurity v. security and poorer sleep among NH-Asians. Nevertheless, due to the diversity of this group (e.g. South Asian; East Asian), future studies should be replicated among subgroup Asian populations to identify groups most impacted. Another interesting finding and in alignment with our hypothesis, Hispanic/Latinx living in households with very low v. high food security status had a higher prevalence of sleep disturbances including trouble falling asleep, trouble staying asleep and insomnia symptoms. Our results are consistent with the few studies that have examined the food security status and sleep health relationship by racial/ethnic groups in a large population(Reference Whinnery, Jackson and Rattanaumpawan24). For example, a study among 2172 adults with obesity and high levels of food insecurity had more trouble falling asleep among minoritised racial/ethnic groups including NH-Black, Hispanic and NH-Asian as well as other racial/ethnic groups(Reference Narcisse, Long and Felix22). Given the documentation of both food insecurity and poor sleep health disproportionately impacting minoritised racial/ethnic groups(Reference Odoms-Young and Bruce18,Reference Grandner36) , these results are unsurprising. Similarly, another study among first-generation US College students comprised of approximately 40 % of minoritised racial/ethnic groups found those food insecure v. secure had higher odds of poorer sleep quality measured via the Pittsburgh Sleep Quality Index(Reference El Zein, Shelnutt and Colby37). A recent study among American Indian/Alaskan Native youth also found that higher food insecurity was associated with more sleep disturbances(Reference Dong, D'Amico and Dickerson38).

Food insecurity may influence sleep through several proposed mechanisms, including biological, psychological and social. Adults who are food insecure v. secure are less likely to access and consume fruits, vegetables and protein and are more likely to consume sugar-sweetened beverages. Lower diet quality, inadequate nutrient intake and poor nutrition likely contributes to shorter sleep duration(Reference Lee, Deason and Rancourt7). Being food insecure may also lead to poor sleep through restricted caloric intake where hunger may interfere with sleep quality(Reference Pot39). Worrying about when one's next meal is and/or ability to afford one's next meal as well as other psychological distress may negatively impact sleep(Reference Goldstein, Gaston and McGrath9,Reference Arenas, Thomas and Wang34) . During public health crises, such as the ongoing COVID-19 pandemic, psychological distress is heightened and disproportionately impacts minoritised racial/ethnic groups(Reference Morales, Morales and Beltran40), which may further impact sleep. In fact, a recent study found that psychological distress was exacerbated during the pandemic where people with food insecurity v. security had higher anxiety and depression(Reference Fang, Thomsen and Nayga41). Moreover, a recent meta-analysis comprised of 250 studies from 49 countries estimated higher levels of sleep disturbances during the COVID-19 pandemic compared to before, disproportionately impacting those infected with COVID-19, older adults, children and healthcare workers(Reference Jahrami, Alhaj and Humood42). Another meta-analysis reported similar levels of heighted sleep disturbances as well as circadian disruptions during other infectious disease outbreaks (e.g. Influenza, Ebola and Zika)(Reference Yuan, Zheng and Wang43). Heightened levels of stress activate the HPA axis producing a range of neuroendocrine hormones, such as corticotropin-releasing hormone, and thus may impact sleep(Reference Vgontzas and Chrousos8). The mental and emotional toll of living in poverty may also activate the HPA axis(Reference Asarnow44). Other societal mechanisms that may impact sleep include food deserts or swamps where minoritised racial/ethnic groups are more likely to live in areas with limited to no access to fresh and healthy foods(Reference Odoms-Young and Bruce18,Reference Zhang and Debarchana45) and environmental pollution, such as noise, that impact optimal sleep(Reference Johnson, Jackson and Williams46). Climate change may also impact sleep through food insecurity where climate change has been shown to disrupt agricultural systems and food supply by, for example, rising temperatures resulting in crop failure and constraining supply(Reference Hasegawa, Sakurai and Fujimori47).

There were several limitations to our study including the cross-sectional study design that limits ability to infer causality. We also relied on self-reported data with known measurement error, including sleep, which has been shown to be non-differential across racial/ethnic groups(Reference Jackson, Ward and Johnson48,Reference Jackson, Patel and Jackson49) . Future studies should also include objective measures. The food security status questions were based on a respondent answering on behalf of the household, and therefore, we were unable to understand intra-household dynamics in terms of who is affected by food insecurity. There is also potential for residual confounding since we adjusted for some measures relatively crudely, such as employment status v. a more refined occupational measure that is not available in the NHIS. Additionally, the response rate is relatively low although it is comparable or higher than other national surveillance systems used to monitor the health of the US population. Furthermore, we were unable to account for transgender and non-binary individuals as the NHIS uses a binary definition of sex/gender. Future research should examine the intersection of multiple social categories including race/ethnicity, sex/gender, age and annual household income. Moreover, future research should replicate this study among indigenous populations as they are considered among the most vulnerable, yet least studied populations facing food insecurity(Reference Gundersen50). Longitudinal studies with participants of all age ranges can enhance our understanding of the prospective impact of food insecurity across the life course as well as help elucidate causal mechanisms.

Despite these limitations, our study had important strengths including utilising a nationally representative dataset with a large sample size. Our results are generalisable to the NH-White, NH-Black, Hispanic/Latinx and NH-Asian US populations. Furthermore, our racially/ethnically diverse sample allowed us to examine the relationship between food security status and sleep health among NH-Asians, which is limited in current research as most studies do not consider racial/ethnic differences in food security status and sleep health(Reference Ding, Keiley and Garza17,Reference Becerra, Bol and Granados20,Reference Liu, Njai and Greenlund21) and even fewer include NH-Asians(Reference Narcisse, Long and Felix22Reference Whinnery, Jackson and Rattanaumpawan24). Another strength includes using multiple dimensions of sleep health beyond sleep duration (e.g. insomnia symptoms, waking up feeling unrested) as well as additional parameters within sleep duration (e.g. very short, short). Additionally, we used a recommended scale(Reference Coleman-Jensen, Rabbitt and Hashad28), where short survey forms of HFSSM have been validated(Reference Blumberg, Bialostosky and Hamilton51), to assess multiple domains of food security status, such as food access, food intake and food affordability, whereas most studies only ask one(Reference Nagata, Palar and Gooding25) or three questions(Reference Narcisse, Long and Felix22).

Given study findings identified NH-Black, Hispanic/Latinx and NH-Asian adults most impacted by food insecurity, these results illuminate who needs most access to high-quality food and resources to reduce food insecurity–sleep disparities. Our descriptive findings inform the need for resource allocation to minoritised racial/ethnic groups along with policy, programme and research development, strengthening and/or enforcement(Reference Fleischhacker, Woteki and Coates52). While we did not sample children, it has been well-documented that food assistance programmes (e.g. Supplemental Nutrition Assistance Program (SNAP); National School Breakfast and Lunch Programs) are vital for low-income children and can also simultaneously reduce food insecurity among their parents. During the COVID-19 pandemic, the necessity of food nutrition programmes in schools and communities (e.g. SNAP) were highlighted(Reference Leddy, Weiser and Palar53,Reference Dunn, Kenney and Fleischhacker54) . Previous research has documented that food insecurity is higher in the summer months, particularly among racial/ethnic minoritised children(Reference Dunn, Kenney and Fleischhacker54). One study in Philadelphia, Pennsylvania projected that – during short-term emergencies that impact household food access (e.g. disaster, hurricane, pandemic) – 3 d of school closures could result in more than 400 000 missed meals for children(Reference Kinsey, Hammer and Dupuis55). As public health crises are likely to worsen due to issues related to climate change for instance, it is essential to seek other effective alternative strategies including the expansion of federal assistance programmes (including eligibility), local grocery stores, all year meal programmes and innovations (e.g. open to community members; food bank/pantry partnerships), community gardens and improving public transportation. Since previous studies have reported individuals living in rural and poor areas have limited access to food due to transportation(Reference Dumas, Harris and McMahon56), legislation can be used to improve transportation to help close the gap in food security. For example, an affordable and publicly run Grocery Bus line that was assimilated into the regular transit system in Austin, Texas intentionally connected a low-income Latinx community with insufficient transportation limiting supermarket access(Reference Dumas, Harris and McMahon56). Finally, policies mitigating climate change may also help improve food security status(Reference Hasegawa, Sakurai and Fujimori47). With this approach, we can build towards not only food security but also nutritional security where all people have access to sufficient, nutritious and high-quality food at all times(Reference Coleman-Jensen, Rabbitt and Hashad1).

Ultimately, we found that the prevalence of low food security was high among a racially/ethnically diverse sample of the US population with the highest prevalence among NH-Black adults. We also found that low v. high food security status was associated with multiple dimensions of poor sleep health. Rising economic and public health crises, as influenced by the COVID-19 pandemic and climate change, demonstrate the urgent need to address food insecurity among minoritised racial/ethnic groups as existing racial/ethnic disparities will likely persist and worsen(Reference Leddy, Weiser and Palar53). Therefore, there is an urgent need to address food insecurity by also addressing the known upstream determinants (e.g. policies mitigating climate change, distribution of food, prioritising people and not corporations), to improve sleep health and subsequent health outcomes.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/jns.2023.18.

Acknowledgements

The authors would like to thank the National Center for Health Statistics for designing, conducting and disseminating the survey along with data files. We would also like to thank all respondents who participated in the survey.

This work was funded by the Intramural Program at the NIH, National Institute of Environmental Health Sciences (Z1AES103325-01). The NIH had no role in the design, analysis or writing of this article.

C. J. designed research, provided administrative, technical and material support; W. J. and C. J. acquired data; W. J. analysed data; D. M., N. R. and W. J. interpreted data and conducted research; D. M. and N. R. wrote the paper; All authors read and approved the final manuscript.

The authors have nothing to disclose.

The National Institute of Environmental Health Sciences’ Institutional Review Board waived approval for this study as de-identified, publicly available data are not classified as human subjects’ research. The National Health Interview Survey is conducted according to the guidelines laid down in the Declaration of Helsinki and all procedures involving research study participants were approved by the National Center for Health Statistics’ Disclosure Review Board. Informed consent was obtained from each study participant to the NHIS.

Footnotes

Co-first authors and equally contributed.

References

Coleman-Jensen, A, Rabbitt, MP, Hashad, RN, et al. (2022) Food Security in the U.S.: Overview: Economic Research Service. U.S. Department of Agriculture. Available from: https://www.ers.usda.gov/topics/food-nutrition-assistance/food-security-in-the-u-s/Google Scholar
Coleman-Jensen, A, Rabbitt, MP, Hashad, RN, et al. (2021) Household Food Security in the United States in 2020. U.S. Department of Agriculture, Economic Research Service. Report No.: 298.Google Scholar
Ma, C, Ho, SKM, Singh, S, et al. (2021) Gender disparities in food security, dietary intake, and nutritional health in the United States. Am J Gastroenterol 116, 584592.CrossRefGoogle ScholarPubMed
Abdurahman, AA, Chaka, EE, Nedjat, S, et al. (2019) The association of household food insecurity with the risk of type 2 diabetes mellitus in adults: a systematic review and meta-analysis. Eur J Nutr 58, 13411350.CrossRefGoogle ScholarPubMed
Ajjarapu, AS, Hinkle, SN, Li, M, et al. (2019) Dietary patterns and renal health outcomes in the general population: a review focusing on prospective studies. Nutrients 11, 121.CrossRefGoogle ScholarPubMed
Liu, Y & Eicher-Miller, HA (2021) Food insecurity and cardiovascular disease risk. Curr Atheroscler Rep 23, 24.CrossRefGoogle ScholarPubMed
Lee, S, Deason, K, Rancourt, D, et al. (2021) Disentangling the relationship between food insecurity and poor sleep health. Ecol Food Nutr 60, 580595.CrossRefGoogle ScholarPubMed
Vgontzas, AN & Chrousos, GP (2002) Sleep, the hypothalamic-pituitary-adrenal axis, and cytokines: multiple interactions and disturbances in sleep disorders. Endocrinol Metab Clin N Am 31, 1536.CrossRefGoogle ScholarPubMed
Goldstein, SJ, Gaston, SA, McGrath, JA, et al. (2020) Sleep health and serious psychological distress: a nationally representative study of the United States among White, Black, and Hispanic/Latinx adults. Nat Sci Sleep 12, 10911104.CrossRefGoogle ScholarPubMed
Bourke, CD, Berkley, JA & Prendergast, AJ (2016) Immune dysfunction as a cause and consequence of malnutrition. Trends Immunol 37, 386398.CrossRefGoogle ScholarPubMed
Besedovsky, L, Lange, T & Haack, M (2019) The sleep-immune crosstalk in health and disease. Physiol Rev 99, 13251380.CrossRefGoogle ScholarPubMed
Jackson, CL, Redline, S & Emmons, KM (2015) Sleep as a potential fundamental contributor to disparities in cardiovascular health. Annu Rev Public Health 36, 417440.CrossRefGoogle ScholarPubMed
Jackson, CL, Walker, JR, Brown, MK, et al. (2020) A workshop report on the causes and consequences of sleep health disparities. Sleep 43, 111.CrossRefGoogle ScholarPubMed
Jackson, CL, Powell-Wiley, TM, Gaston, SA, et al. (2020) Racial/ethnic disparities in sleep health and potential interventions among women in the United States. J Womens Health (Larchmt) 29, 435442.CrossRefGoogle ScholarPubMed
Morland, K, Wing, S, Diez Roux, A, et al. (2002) Neighborhood characteristics associated with the location of food stores and food service places. Am J Prev Med 22, 2329.CrossRefGoogle ScholarPubMed
Troxel, WM, Haas, A, Ghosh-Dastidar, B, et al. (2020) Food insecurity is associated with objectively measured sleep problems. Behav Sleep Med 18, 719729.CrossRefGoogle ScholarPubMed
Ding, M, Keiley, MK, Garza, KB, et al. (2015) Food insecurity is associated with poor sleep outcomes among US adults. J Nutr 145, 615621.CrossRefGoogle ScholarPubMed
Odoms-Young, A & Bruce, MA (2018) Examining the impact of structural racism on food insecurity: implications for addressing racial/ethnic disparities. Fam Community Health 41, S3S6. Suppl 2 Food Insecurity and Obesity.CrossRefGoogle ScholarPubMed
Jordan, ML, Perez-Escamilla, R, Desai, MM, et al. (2016) Household food insecurity and sleep patterns among Mexican adults: results from ENSANUT-2012. J Immigr Minor Health 18, 10931103.CrossRefGoogle ScholarPubMed
Becerra, MB, Bol, BS, Granados, R, et al. (2020) Sleepless in school: the role of social determinants of sleep health among college students. J Am Coll Health 68, 185191.CrossRefGoogle ScholarPubMed
Liu, Y, Njai, RS, Greenlund, KJ, et al. (2014) Relationships between housing and food insecurity, frequent mental distress, and insufficient sleep among adults in 12 US states, 2009. Prev Chronic Dis 11, E37.CrossRefGoogle ScholarPubMed
Narcisse, MR, Long, CR, Felix, H, et al. (2018) The mediating role of sleep quality and quantity in the link between food insecurity and obesity across race and ethnicity. Obesity (Silver Spring) 26, 15091518.CrossRefGoogle ScholarPubMed
Robson, SM, Lozano, AJ, Papas, M, et al. (2017) Food insecurity and cardiometabolic risk factors in adolescents. Prev Chronic Dis 14, E110.CrossRefGoogle ScholarPubMed
Whinnery, J, Jackson, N, Rattanaumpawan, P, et al. (2014) Short and long sleep duration associated with race/ethnicity, sociodemographics, and socioeconomic position. Sleep 37, 601611.CrossRefGoogle Scholar
Nagata, JM, Palar, K, Gooding, HC, et al. (2020) Food insecurity and health outcomes in young adults. J Adolesc Health 66, S12S13.CrossRefGoogle Scholar
Statistics DoHISNCfH (2016) 2015 National Health Interview Survey (NHIS) Public Use Data Release.Google Scholar
Coleman-Jensen, A (2021) Food Insecurity in U.S. Households in 2018 is Down from 2017, Continuing Trend and Returning to Pre-Recession (2007) Level. Food Assistance Branch, Economic Research Service in Research and Science, US Department of Agriculture. Available from: https://www.usda.gov/media/blog/2019/10/03/food-insecurity-us-households-2018-down-2017-continuing-trend-and-returningGoogle Scholar
Coleman-Jensen, A, Rabbitt, MP, Hashad, RN, et al. (2012) US Household Food Security Survey Module: Three-Stage Design with Screeners. Washington, DC: Economic Research Service, US Department of Agriculture.Google Scholar
Coleman-Jensen, A, Rabbit, MP, Hashad, RN, et al. (2022) How are food security and insecurity measured? Economic Research Services, US Department of Agriculture. Available from: https://www.ers.usda.gov/topics/food-nutrition-assistance/food-security-in-the-u-s/measurementGoogle Scholar
Hirshkowitz, M, Whiton, K, Albert, SM, et al. (2015) National Sleep Foundation's sleep time duration recommendations: methodology and results summary. Sleep Health 1, 4043.CrossRefGoogle ScholarPubMed
Watson, NF, Badr, MS, Belenky, G, et al. (2015) Recommended amount of sleep for a healthy adult: a joint consensus statement of the American Academy of Sleep Medicine and Sleep Research Society. Sleep 38, 843844.Google ScholarPubMed
Spadola, CE, Guo, N, Johnson, DA, et al. (2019) Evening intake of alcohol, caffeine, and nicotine: night-to-night associations with sleep duration and continuity among African Americans in the Jackson Heart Sleep Study. Sleep 42, 17.CrossRefGoogle ScholarPubMed
Barros, AJ & Hirakata, VN (2003) Alternatives for logistic regression in cross-sectional studies: an empirical comparison of models that directly estimate the prevalence ratio. BMC Med Res Methodol 3, 113.CrossRefGoogle ScholarPubMed
Arenas, DJ, Thomas, A, Wang, J, et al. (2019) A systematic review and meta-analysis of depression, anxiety, and sleep disorders in US adults with food insecurity. J Gen Intern Med 34, 28742882.CrossRefGoogle ScholarPubMed
Mazloomi, SN, Talebi, S, Kazemi, M, et al. (2022) Food insecurity is associated with the sleep quality and quantity in adults: a systematic review and meta-analysis. Public Health Nutr 26, 111.Google ScholarPubMed
Grandner, MA (2020) Sleep, health, and society. Sleep Med Clin 15, 319340.CrossRefGoogle ScholarPubMed
El Zein, A, Shelnutt, KP, Colby, S, et al. (2019) Prevalence and correlates of food insecurity among U.S. College students: a multi-institutional study. BMC Public Health 19, 660.CrossRefGoogle Scholar
Dong, L, D'Amico, EJ, Dickerson, DL, et al. (2022) Food insecurity, sleep, and cardiometabolic risks in urban American Indian/Alaska native youth. Sleep Health 1, 410.Google Scholar
Pot, GK (2018) Sleep and dietary habits in the urban environment: the role of chrono-nutrition. Proc Nutr Soc 77, 189198.CrossRefGoogle ScholarPubMed
Morales, DX, Morales, SA & Beltran, TF (2021) Racial/ethnic disparities in household food insecurity during the COVID-19 pandemic: a nationally representative study. J Racial Ethn Health Disparities 8, 13001314.CrossRefGoogle ScholarPubMed
Fang, D, Thomsen, MR & Nayga, RM Jr (2021) The association between food insecurity and mental health during the COVID-19 pandemic. BMC Public Health 21, 607.CrossRefGoogle ScholarPubMed
Jahrami, HA, Alhaj, OA, Humood, AM, et al. (2022) Sleep disturbances during the COVID-19 pandemic: a systematic review, meta-analysis, and meta-regression. Sleep Med Rev 62, 101591.CrossRefGoogle ScholarPubMed
Yuan, K, Zheng, Y-B, Wang, Y-J, et al. (2022) A systematic review and meta-analysis on prevalence of and risk factors associated with depression, anxiety and insomnia in infectious diseases, including COVID-19: a call to action. Mol Psychiatry 27, 32143222.CrossRefGoogle ScholarPubMed
Asarnow, LD (2020) Depression and sleep: what has the treatment research revealed and could the HPA axis be a potential mechanism? Curr Opin Psychol 34, 112116.CrossRefGoogle ScholarPubMed
Zhang, M & Debarchana, G (2016) Spatial supermarket redlining and neighborhood vulnerability: a case study of Hartford, Connecticut. Trans GIS 20, 79100.CrossRefGoogle ScholarPubMed
Johnson, DA, Jackson, CL, Williams, NJ, et al. (2019) Are sleep patterns influenced by race/ethnicity - a marker of relative advantage or disadvantage? Evidence to date. Nat Sci Sleep 11, 7995.CrossRefGoogle ScholarPubMed
Hasegawa, T, Sakurai, G, Fujimori, S, et al. (2021) Extreme climate events increase risk of global food insecurity and adaptation needs. Nature Food 2, 587595.CrossRefGoogle ScholarPubMed
Jackson, CL, Ward, JB, Johnson, DA, et al. (2020) Concordance between self-reported and actigraphy-assessed sleep duration among African-American adults: findings from the Jackson Heart Sleep Study. Sleep 43, 111.CrossRefGoogle ScholarPubMed
Jackson, CL, Patel, SR, Jackson, WB 2nd, et al. (2018) Agreement between self-reported and objectively measured sleep duration among White, Black, Hispanic, and Chinese adults in the United States: multi-ethnic study of atherosclerosis. Sleep 41, 112.CrossRefGoogle ScholarPubMed
Gundersen, C (2008) Measuring the extent, depth, and severity of food insecurity: an application to American Indians in the USA. J Popul Econ 21, 191215.CrossRefGoogle Scholar
Blumberg, SJ, Bialostosky, K, Hamilton, WL, et al. (1999) The effectiveness of a short form of the household food security scale. Am J Public Health 89, 12311234.CrossRefGoogle Scholar
Fleischhacker, SE, Woteki, CE, Coates, PM, et al. (2020) Strengthening national nutrition research: rationale and options for a new coordinated federal research effort and authority. Am J Clin Nutr 112, 721769.CrossRefGoogle ScholarPubMed
Leddy, AM, Weiser, SD, Palar, K, et al. (2020) A conceptual model for understanding the rapid COVID-19-related increase in food insecurity and its impact on health and healthcare. Am J Clin Nutr 112, 11621169.CrossRefGoogle ScholarPubMed
Dunn, CG, Kenney, E, Fleischhacker, SE, et al. (2020) Feeding low-income children during the COVID-19 pandemic. N Engl J Med 382, e40.CrossRefGoogle ScholarPubMed
Kinsey, EW, Hammer, J, Dupuis, R, et al. (2019) Planning for food access during emergencies: missed meals in Philadelphia. Am J Public Health 109, 781783.CrossRefGoogle ScholarPubMed
Dumas, BL, Harris, DM, McMahon, JM, et al. (2021) Prevalence of municipal-level policies dedicated to transportation that consider food access. Prev Chronic Dis 18, E97.CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Age-standardised socio-demographic, health behaviour and clinical characteristics between very low, low, marginal and high food security, National Health Interview Survey, 2013–2018 (N 177 435)a

Figure 1

Fig. 1. Food security status by race/ethnicity between very low, low, marginal and high food security, National Health Interview Survey, 2013–2018 (N 177 435).

Figure 2

Table 2. Prevalence ratios of sleep health among participants reporting very low, low and marginal compared with high food security by sex/gender and race/ethnicity, National Health Interview Survey, 2013–2018 (N 177 435)

Figure 3

Table 3. Prevalence ratios of sleep health among minoritised racial/ethnic groups reporting very low, low, marginal and high compared with NH-White participants with high food security, National Health Interview Survey, 2013–2018 (N 177 435)

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