Hostname: page-component-77c89778f8-rkxrd Total loading time: 0 Render date: 2024-07-20T21:59:18.209Z Has data issue: false hasContentIssue false
  • English
  • Français

Diet quality, diet-related factors and disability status among male adults of reproductive age in the USA

Published online by Cambridge University Press:  03 July 2023

Andrea L Deierlein Open the ORCID record for Andrea L Deierlein [Opens in a new window] ,
Jaqueline Litvak Open the ORCID record for Jaqueline Litvak [Opens in a new window] ,
Chang Liu  and
Cheryl R Stein
Andrea L Deierlein*
Affiliation:
School of Global Public Health, New York University, New York, NY, USA
Jaqueline Litvak
Affiliation:
School of Global Public Health, New York University, New York, NY, USA
Chang Liu
Affiliation:
School of Global Public Health, New York University, New York, NY, USA
Cheryl R Stein
Affiliation:
Department of Child and Adolescent Psychiatry, New York University Grossman School of Medicine, New York, NY, USA
*
*Corresponding author: Email ald8@nyu.edu
Rights & Permissions [Opens in a new window]

Abstract

Objective:

To examine diet quality and diet-related factors among male adults of reproductive age with and without disabilities.

Design:

Cross-sectional data from the National Health and Nutrition Examination Surveys, 2013–2018.

Setting:

Disability was reported as serious difficulty hearing, seeing, concentrating, walking, dressing and/or running errands due to physical, mental or emotional conditions. Diet quality was assessed by the Healthy Eating Index (HEI)-2015 and diet-related factors included self-rated diet healthfulness, food security and food assistance programmes. Multivariable linear regression estimated differences in HEI-2015 scores. Multivariable Poisson regression estimated adjusted prevalence ratios (aPR) and 95 % CI for diet-related factors.

Participants:

In total, 3249 males, 18–44 years; of whom, 441 (13·4 %) reported having disabilities.

Results:

Compared with males without disabilities, those with disabilities had a 2·69-point (95 % CI: –4·18, –1·20) lower mean total HEI-2015 score and approximately one-third to half of a point lower HEI-2015 component scores for greens and beans, total protein foods, seafood and plant proteins, fatty acids and added sugars. Males with any disabilities were more likely to have low food security (aPR = 1·57; 95 % CI: 1·28, 2·92); household participation in food assistance programmes (aPR = 1·61; 95 % CI: 1·34, 1·93) and consume fast food meals during the previous week (1–3 meals: aPR = 1·11; 95 % CI: 1·01–1·21 and 4 or more meals: aPR = 1·18; 95 % CI: 1·01–1·38) compared with males with no disabilities.

Conclusions:

Factors affecting diet and other modifiable health behaviours among male adults of reproductive age with disabilities require further investigation. Health promotion strategies that are adaptive to diverse populations within the disability community are needed.

Keywords

DisabilityMalesHealthy Eating IndexNutrition
Type
Research Paper
Information
Public Health Nutrition , Volume 26 , Issue 10 , October 2023 , pp. 1976 - 1985
Check for updates
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
© The Author(s), 2023. Published by Cambridge University Press on behalf of The Nutrition Society

Diet plays an influential role for overall health and chronic disease development throughout the life course. Nutrient intakes during adolescence and early adulthood are particularly important for reproductive health outcomes(Reference Panth, Gavarkovs and Tamez1), mental health and cognitive function(Reference Parletta, Milte and Meyer2) and cardiometabolic health risk factors(Reference Steffen, Van Horn and Daviglus3). Persons with disabilities often report poorer health status and have higher rates of chronic health conditions compared with their counterparts without disabilities(Reference Deierlein, Litvak and Stein4,Reference Deierlein, Sun and Prado5) . There are numerous contributors to these health disparities, including socio-economic status, lifestyle behaviours, healthcare access and receipt of preventive healthcare services(Reference Reichard, Stolzle and Fox6Reference Horner-Johnson, Dobbertin and Lee8). Additionally, an increased risk of household food insecurity is consistently associated with disability status(Reference Schwartz, Buliung and Wilson9); however, there remains limited investigation of dietary intakes and other diet-related factors among persons with disabilities, especially young adults.

Findings from descriptive studies of nutrient intakes or nutritional behaviours among small convenience samples of adults with physical disabilities (e.g. spinal cord injury)(Reference Groah, Nash and Ljungberg10,Reference Tomey, Chen and Wang11) , adults with intellectual or developmental disabilities(Reference Brown, Marciniak and Garrett12,Reference Zwack, McDonald and Tursunalieva13) and Paralympic athletes(Reference Joaquim, Juzwiak and Winckler14) suggest that many of these individuals do not meet dietary recommendations for some vitamins and minerals, while exceeding recommendations for other nutrients, like Na, fat and alcohol. The U.S. National Health and Nutrition Examination Surveys (NHANES) is a nationally representative program of studies that uniquely collects information on both disability status and dietary intakes(15). Among adults (ages 20 years and older) in NHANES 2007–2010, nutrient intakes from food and dietary supplements were compared between those with and without disabilities and across five categories of disability (based on nineteen questions about difficulties with activities)(Reference An, Chiu and Zhang16). Adults with disabilities, especially those with disabilities related to activities of daily living, were more likely to have dietary intakes that fell outside of national recommendations compared with those without disabilities. Differences between males and females or age categories were not examined(Reference An, Chiu and Zhang16).

Beginning in 2013, NHANES added a disability questionnaire with six specific questions about difficulties related to hearing, seeing, concentrating, walking, dressing and/or running errands due to physical, mental or emotional conditions. In previous analyses, we examined diet quality and diet-related factors by disability status among female adults of reproductive age (18–44 years) in NHANES 2013–2018(Reference Deierlein, Litvak and Stein17). Despite few differences in diet quality scores between females with and without disabilities, those with any disabilities were more likely to rate their diet health as poor, have low food security, participate in food assistance programmes and consume frozen foods(Reference Deierlein, Litvak and Stein17). There has been little focus on the nutritional health of male adults of reproductive age or how it may differ from that of their female counterparts. For the current analyses, our objective was to address this gap by examining diet quality and diet-related factors among male adults of reproductive age in NHANES 2013–2018.

Methods

Study population

Data were from 3754 male adults aged 18–44 years who participated in NHANES cycles 2013–2014, 2015–2016 and 2017–2018. NHANES is conducted by the National Center for Health Statistics and collects socio-demographic, lifestyle, clinical, laboratory and nutrition information from individuals of all ages during interviews and medical exams(15). For the current analyses, males were excluded if they had missing (n 286) or unreliable dietary data (n 15 flagged as unreliable by NHANES) or were missing information on covariates (n 25). There were 3249 males included in the final analytic sample. Informed consent was obtained from all participants, and approval for the studies was obtained from the National Center for Health Statistics Research Ethics Review Board. Descriptions of NHANES and data collection procedures are described elsewhere(15). The current study was exempted from human subjects review by the New York University Institutional Review Board.

Disability status

The disability questionnaire consisted of six questions regarding self-reported difficulty (yes or no) with activities due to physical, mental or emotional conditions: (1) ‘deaf or serious difficulty hearing’; (2) ‘blind or serious difficulty seeing even when wearing glasses’; (3) ‘serious difficulty concentrating, remembering, or making decisions’; (4) ‘serious difficulty walking or climbing stairs’; (5) ‘difficulty dressing or bathing’ and (6) ‘difficulty doing errands alone such as visiting a doctor’s office or shopping’. Self-reported disability status was dichotomised as none or any disabilities. To be consistent with previous NHANES analyses among female adults of reproductive age(Reference Deierlein, Litvak and Stein4,Reference Deierlein, Litvak and Stein17) , any disabilities were further categorised as four disability types: sensory (questions 1 and 2); cognitive (question 3); movement (question 4) and self-care (questions 5 and 6). Associations for males who reported any disabilities, only one type of disability and two or more types of disabilities were compared with males with no disabilities.

Diet quality

The dietary interview component of NHANES, What We Eat in America, is conducted by the U.S. Department of Agriculture and U.S. Department of Health and Human Services(15). It consists of two 24-h dietary recalls, during which participants report food and beverage consumption within the previous 24 h. The first 24-h dietary recall was collected during an in-person interview by trained staff who were fluent in Spanish and English. The second 24-h dietary recall was administered by telephone approximately 3–10 d after the first recall(15). Approximately 18 % of males did not complete the second 24-h dietary recall (n 591); therefore, only food and beverage intakes (excluding vitamin and supplement use) collected from the first 24-h dietary recall were included.

Diet quality specific to the first 24-h dietary recall was assessed using The Healthy Eating Index (HEI)-2015. HEI-2015 is a measure of diet quality based on adherence to the 2015–2020 Dietary Guidelines for American(Reference Krebs-Smith, Pannucci and Subar18), which most reflects the U.S. dietary recommendations at the time of NHANES data collection. Better HEI scores are associated with reduced chronic disease risk and mortality in male adults and the general population(Reference de Koning, Chiuve and Fung19,Reference Panizza, Shvetsov and Harmon20) . HEI-2015 scores were calculated using the simple HEI scoring algorithm method with publicly available SAS code from the National Cancer Institute’s Epidemiology and Genomics Research Program(21,Reference Kirkpatrick, Reedy and Krebs-Smith22) . For these analyses, all HEI scores should be interpreted as representing dietary intakes and diet quality on a given day.

The HEI-2015 has thirteen components, nine adequacy components and four moderation components that are summed for an overall score ranging from 0 to 100 points(Reference Krebs-Smith, Pannucci and Subar18). A higher total HEI-2015 score indicates better diet quality(Reference Krebs-Smith, Pannucci and Subar18). The nine adequacy components (total sxity points) are: total fruits (five points), whole fruits (five points), total vegetables (five points), greens and beans (five points), total protein foods (five points), seafood and plant proteins (five points), whole grains (ten points), dairy (ten points) and fatty acids (ratio of polyunsaturated fats and monounsaturated fats to saturated fat, ten points). With the exception of the fatty acids component, adequacy components were scored based on nutrient density per 1000 calories (e.g. cups of whole fruit per 1000 calories). For all of the adequacy components, a higher score indicates higher intakes of that component. The four moderation components (total forty points) are: refined grains (ten points), Na (ten points), added sugars (ten points) and saturated fats (ten points). The refined grains and Na components were scored based on amounts per 1000 calories; the saturated fats and added sugars components were scored based on percentage of total energy intakes. For all of the moderation components, a higher score indicates lower intakes of that component(Reference Krebs-Smith, Pannucci and Subar18).

Diet-related factors

Several factors related to diet were examined. Participants rated the healthfulness of their overall diet as excellent, very good, good, fair or poor (Diet Behaviour and Nutrition questionnaire). Adult food security status was based on responses to the ten-item U.S. Food Security Survey Module (FFQ)(Reference Bickel, Nord and Price23). Responses were categorised as full (no affirmative responses to any of the ten items), marginal (1–2 affirmative responses) or low/very low (three or more affirmative responses) food security(Reference Bickel, Nord and Price23). Participation in governmental food assistance programmes was based on receipt of ‘Supplemental Nutrition Assistance Program (SNAP) or Food Stamp benefits’ within the previous year (self or someone in the household, yes or no) (Food Security questionnaire)(24). SNAP is a federal program that provides monthly benefits for low-income households to purchase food(24). Participants responded to questions regarding their frequency of consumption of different types of meals or foods (Diet Behaviour and Nutrition questionnaire): total number of meals (breakfast, lunch or dinner) prepared away from home during the previous 7 d (e.g. restaurants, fast food places, food stands, grocery stores, vending machines; categorised as none, 1–3 meals and 4 or more meals); number of meals prepared away from home from a fast food or pizza place during the previous 7 d (none, 1–3 meals and 4 or more meals); number of times that ready-to-eat foods from grocery stores were consumed in the past 30 d (e.g. salads, soups, chicken and sandwiches; categorised as none, 1–4 times and five or more times) and number of times that frozen meals or frozen pizzas were consumed in the past 30 d (none, 1–four times and five or more times). In NHANES 2017–2018 questions were added (Diet Behaviour and Nutrition questionnaire) regarding participants’ status as the main meal planner/preparer for their household (yes or no) or if they shared in the planning or preparing of meals with someone else (yes or no), and participants’ status as the main food shopper (yes or no) or if they shared in food shopping with someone else (yes or no).

Socio-demographic characteristics

Age (years), race and ethnicity (categorised in NHANES as non-Hispanic white, non-Hispanic Black, Mexican American, Other Hispanic and Other Race including multi-racial), educational status (< high school graduate, high school graduate/some college and college graduate), ratio of family income to poverty (expressed as a percentage, <= 100 %, 101–200 %, 201–300 % and > 300 %), marital status (single, married/living with partner) and cigarette smoking (never, former and current) were self-reported. During an in-person medical exam, participants’ weight (kilograms, kg) and height (meters, m) were measured by trained health technicians using standardised procedures while participants wore examination gowns and no shoes(15). BMI (BMI, kg/m2) was calculated using these measurements.

Statistical analysis

Unweighted counts, means with standard errors (se, continuous variables) and proportions (categorical variables) were calculated. Bivariate associations of disability status (no disabilities, any self-reported disabilities, only one self-reported disability, two or more self-reported disabilities) and participant characteristics, total HEI-2015 scores and diet-related factors were tested using χ 2 tests (categorical variables) and t tests (continuous variables). Multivariable linear regression estimated associations of disability status and continuous HEI-2015 total and component scores. Multivariable Poisson regression estimated associations (prevalence ratios, PR, and 95 % CI) of disability status and categorical diet-related factors. The reference for all models was male adults with no disabilities. Models were adjusted for age, race and ethnicity, education, marital status, BMI and smoking status based on previous literature(Reference An, Chiu and Zhang16,Reference Deierlein, Litvak and Stein17) and directed acyclic graph analysis(Reference Greenland, Pearl and Robins25). Ratio of family income to poverty was missing for 301 (9 %) males. Multivariable regression models were examined with and without adjustment for this variable. There were no appreciable differences in the magnitude or precision of effect estimates; therefore, final models did not include this variable. Statistical significance was set at P < 0·05. All analyses were statistically weighted as required for the complex survey design of NHANES using Stata version 15.1(26).

Results

Of 3249 male adults of reproductive age, 441 (13·4 %, weighted) reported having any disability: 290 (8·3 %) reported having only one type of disability and 151 (5·1 %) reported having two or more types of disabilities. Some differences were observed in the distributions of socio-demographic characteristics by disability status. Males with any disabilities were less likely to be college graduates, from households with higher incomes and married or living with a partner; they were more likely to be current smokers (Table 1).

Table 1 Distributions of socio-demographic characteristics and health behaviours among adult males of reproductive age (18–44 years) with and without self-reported disabilities, national health and nutrition examination surveys (NHANES), 2013–2018 (n 3249)

se, standard error; NR, not reported.

* Percentages were adjusted for NHANES survey weights.

Reference is males with no disabilities.

Reference is males with only one type of disability.

§ n 301 (9 %) males missing information on household income.

|| Cell sizes <= 10.

Among male adults of reproductive age without disabilities, the mean unadjusted total HEI-2015 score was 48·16 (se = 0·38) compared with mean unadjusted scores of 43·68 (se = 0·73), 44·12 (se = 0·82) and 42·97 (se = 1·43) among males with any disabilities, only one type of disability and two or more types of disabilities, respectively (Table 2). These observed differences remained after adjusting for covariates. The adjusted mean total HEI-2015 scores among males with any disabilities, only one type of disability and two or more types of disabilities were lower than the score for males without disabilities by 2·69 points (95 % CI: –4·18, –1·20), 2·28 points (95 % CI: –3·87, –0·68) and 3·37 points (–6·14, –0·60), respectively. Compared with males with no disabilities, those with any disabilities had lower adjusted mean scores for greens and beans, total protein foods, seafood and plant proteins, fatty acids and added sugars (Table 2). In models stratified by number of types of disabilities, differences in adjusted mean HEI component scores tended to be greater (indicative of lower diet quality) for males with two or more types of disabilities than males with only one type of disability, when compared with males with no disabilities. Males with two or more disabilities had lower scores for total vegetables, greens and beans, total protein foods, seafood and plant proteins and added sugars, compared with males with no disabilities (Table 2).

Table 2 Unadjusted means and adjusted mean differences in total and component Health Eating Index (HEI)-2015 scores for a given day by disability status, categorised as no disabilities, any disability, only one disability, and two or more disabilities, among male adults of reproductive age (18–44 years) in the National Health and Nutrition Examination Surveys (NHANES), 2013–2018

se, standard error; CI, confidence interval.

* Unadjusted mean.

Mean difference in HEI-2015 scores from linear regression models adjusted for age, race and ethnicity, education, marital status, BMI and smoking status, reference group for all models is males with no disabilities.

Differences in distributions of diet-related factors were also observed by disability status (Table 3). Greater proportions of males with any disabilities were more likely report poor or fair self-rated diet health; very low or low food security status; household participation in food assistance programmes during the previous year; consume at least one fast food meal during the previous week and consume frozen foods or pizza at least once during the previous month. After adjustment for covariates (Table 4), some of these observed differences in diet-related factors by disability status remained. Males with any disabilities were more likely to have very low/low food security status (aPR, 1·57; 95 % CI: 1·28, 2·92); household participation in food assistance programmes (aPR, 1·61; 95 % CI: 1·34, 1·93) and consume at least one meal from fast food/pizza places during the past 7 d (1–3 meals: aPR, 1·11; 95 % CI: 1·01, 1·21 and 4 or more meals: aPR, 1·18; 95 % CI: 1·01, 1·38) compared with males with no disabilities. In models that stratified by number of types of disabilities, associations were similar for males with one disability and males with two or more disabilities compared with those with no disabilities. Diet-related factors of self-rated diet health; consumption of meals prepared away from home, ready-to-eat foods, and frozen meals/pizza and status as main food shopper and main meal planner/preparer were not associated with disability status.

Table 3 Distributions of diet-related factors among male adults of reproductive age (18–44 years) with and without self-reported disabilities, National Health and Nutrition Examination Surveys (NHANES), 2013–2018

* Percentages were adjusted for NHANES survey weights.

Reference is males with no disabilities.

Reference is males with only one disability.

§ Only collected in NHANES 2017–2018.

Table 4 Unadjusted and adjusted* Poisson regression models estimating associations of selected diet-related factors and disability status, categorised as no disabilities, any disability, only one disability and two or more disabilities, among male adults of reproductive age (18–44 years) in the National Health and Nutrition Examination Surveys (NHANES), 2013–2018

PR, prevalence ratio; aPR, adjusted prevalence ratio; REF, reference.

* Models adjusted for age, race and ethnicity, education, marital status, smoking status and BMI.

Reference for all models is males with no disabilities.

Collected only during NHANES 2017–2018.

Discussion

Among U.S. male adults aged 18–44 years, overall diet quality scores were poor regardless of disability status. Compared with males without disabilities, those with any disabilities had a nearly three-point lower mean total HEI-2015 score and approximately one-third to half of a point lower HEI-2015 component scores for greens and beans, total protein foods, seafood and plant proteins, fatty acids and added sugars. Males with any disabilities were more likely to have very low/low food security status, household participation in food assistance programmes and consume at least one weekly meal from a fast food/pizza place compared with males without disabilities.

Few studies have assessed dietary intakes among adults with disabilities. Inadequate intakes of select food groups (e.g. fruits and vegetables) or micronutrients have been reported in descriptive studies of adults with impaired vision(Reference Gawlik, Zwierzchowska and Rosołek27), paraplegia(Reference Burri and Neidlinger28) and cerebral palsy(Reference Brown, Marciniak and Garrett12). In analyses of U.S. national survey data, adults with any disabilities reported less frequent fruit and vegetable consumption during the previous month compared with those without disabilities (P < 0·05)(Reference An and Chiu29) and did not meet U.S. dietary guidelines for saturated fat, cholesterol and Na (excess consumption) or for fibre, vitamins A, C and D, Ca and potassium (insufficient consumption)(Reference An, Chiu and Zhang16). Smaller studies among male disabled adult populations show comparable nutritional disparities and are consistent with findings in the current study. Male adults with lower limb amputations in the United Kingdom (mean age = 46 years, n 46) had higher intakes of sugars, total and saturated fat and Na compared with national health recommendations (P < 0·05 for all comparisons)(Reference Westerkamp, Strike and Patterson30). In the U.S. (Chicago, Illinois), dietary intakes were assessed in healthy, community-dwelling male adults with chronic spinal cord injury (ages 20–59 years, n 95)(Reference Tomey, Chen and Wang11). Only one-third of the participants had intakes within national dietary recommendations for saturated fat, Na and fruits and vegetable intakes, while 18 %, 16 % and 12 % met recommendations for total fat, dairy products and fibre, respectively(Reference Tomey, Chen and Wang11). Additionally, they had significantly lower scores for HEI components (earlier version of HEI, not specified by authors) related to grains, fruit, dairy, total fat and having a varied diet (P < 0·05 for all comparisons) when compared with scores of male adults in NHANES 1999–2000(Reference Tomey, Chen and Wang11). Though direct comparisons of findings from previous studies and the current study cannot be made, collectively, they suggest that malnutrition is a concern among adults with disabilities. In the current study, low diet quality scores among males with disabilities may be at least partially attributed to greater prevalence of food insecurity, participation in government food assistance programmes and consumption of fast foods, all of which have been associated with lower diet quality(Reference Hanson and Connor31Reference Barnes, French and Mitchell33).

There has been little inquiry regarding whether nutritional health (encompassing food security, physical and economic access to food, dietary behaviours and dietary intakes) varies between males and females with disabilities, especially younger adult populations. Similar to the current findings for male adults of reproductive age with disabilities, their female counterparts (in NHANES 2013–2018) were also more likely to report low household food security and participation in food assistance programmes; however, diet quality did not markedly vary by disability status among females(Reference Deierlein, Litvak and Stein17). Differences for several other diet-related factors were observed. Females with disabilities were more likely to perceive poor dietary health, more likely to consume frozen foods and less likely to be the main meal planners/preparers or main food shoppers for their households(Reference Deierlein, Litvak and Stein17); males with disabilities were more likely to consume fast food meals on a weekly basis. The contrasting associations for diet quality and diet-related factors between female and male adults of reproductive age with disabilities (compared with their respective counterparts without disabilities) suggest they have different needs that should be identified and addressed within nutrition interventions. These needs may be related to social determinants of health, as well as eating and lifestyle behaviours, attitudes and beliefs or nutrition knowledge. Studies have explored how psychological, social, physical and environmental variables influence nutritional and other health behaviours among females with disabilities,(Reference Nosek, Hughes and Robinson-Whelen34Reference Robinson-Whelen, Hughes and Taylor36) and subsequent health promotion strategies have proven successful(Reference Robinson-Whelen, Hughes and Taylor36,Reference Nosek, Robinson-Whelen and Ledoux37) . For example, a disability- and gender-responsive weight management pilot intervention for women with mobility impairments improved their diet, physical activity and self-efficacy for diet and physical activity, as well as reduced body weight and waist circumference(Reference Nosek, Robinson-Whelen and Ledoux37). Continued research is necessary to understand barriers and facilitators of achieving healthy dietary intakes (and other health behaviours) and to develop health promotion strategies that are adaptive to diverse populations within the disability community.

Diet is a modifiable health behaviour. Greater attention should be paid to helping individuals with disabilities meet nutritional recommendations, beginning early in life and persisting throughout the life course. Disparities in overweight and obesity by disability status are apparent during childhood and continue into adulthood(Reference Liou, Pi-Sunyer and Laferrere38,Reference Rimmer, Rowland and Yamaki39) . Adolescents and adults of reproductive age with disabilities are more likely to have chronic health conditions, including type 2 diabetes, hypertension and depression, compared with those without disabilities(Reference Deierlein, Litvak and Stein4,Reference Deierlein, Sun and Prado5,Reference Rimmer, Rowland and Yamaki39,Reference Flygare Wallén, Ljunggren and Carlsson40) . All of these health conditions may be ameliorated or prevented with dietary modifications(Reference Schulze, Martínez-González and Fung41). Dietary screening and counseling may be overlooked during healthcare visits due to prioritisation of other healthcare needs or lack of healthcare provider knowledge on these topics. Several strategies have been proposed to address health promotion and wellness among persons with disabilities within the healthcare system, which should emphasise healthy eating and food access and availability(Reference Lee, O’Neal and Cameron42). These strategies include providing educational and practical training for primary care physicians and rehabilitation medicine specialists to support patients in wellness activities(Reference Morris and Jenkins43,Reference McColl, Gupta and Smith44) ; incorporating registered dietitian nutritionists into healthcare teams to provide individualised counseling for patients and their caregivers(Reference Deierlein, Litvak and Stein17) and establishing hospital-led, community-based programmes to transition patients from hospital care to independently managing their health and well-being(Reference Carroll, Hall and Feldman45). In-person and telehealth interventions for self-esteem, physical activity and weight management have also been developed in various populations with disabilities(Reference Rimmer, Wang and Pellegrini46,Reference Scott and Havercamp47) and should be tested for their effectiveness in improving dietary intakes.

The major strength of this study is the use of U.S. survey data that collects information on disability status, detailed dietary intakes and other variables related to diet and health behaviours. Limitations include the cross-sectional study design and most of the study variables were self-reported. Questions about disability status only asked about whether or not there were serious difficulties with functional domains; they did not establish specific cause or severity of disability. Due to limited sample sizes, associations could not be examined by type of disability or other socio-demographic factors. Caution should be used when interpreting the HEI-2015 scores. These scores were calculated from a single 24-h dietary recall and are subject to biases related to self-reported data, including errors related to misreporting(Reference Ahluwalia, Dwyer and Terry48). HEI-2015 scores based on 24-h recall data are similar to those from observed intakes(Reference Kirkpatrick, Dodd and Potischman49); however, these scores represent diet quality for a specific day rather than usual or habitual diet quality over time (e.g. variability by days, months and seasons)(Reference Kirkpatrick, Reedy and Krebs-Smith22,Reference Ahluwalia, Dwyer and Terry48) . Lastly, the simple scoring algorithm method used to generate HEI-2015 scores does not account for measurement error, episodic food intakes, skewness or the correlation between dietary constituents and energy intakes(Reference Kirkpatrick, Reedy and Krebs-Smith22).

Conclusions

Male adults of reproductive age with disabilities had lower diet quality and were more likely to report low food security, household use of food assistance programmes and weekly consumption of fast foods compared with those without disabilities. This is of concern because health behaviours and general health status during adolescence and early adulthood greatly influence fecundity and reproductive outcomes, personal short- and long-term physical and mental health, as well as the health and development of future generations. Factors affecting dietary intakes and related behaviours among male adolescents and adults of reproductive age with disabilities require further investigation. Health promotion and wellness programmes that include flexible strategies for overcoming barriers to healthy eating are necessary for reducing the existing health disparities faced by all individuals with disabilities.

Acknowledgements

Not applicable.

Financial support

This research was funded by a grant from the New York University (NYU) Research Challenge Fund Program. NYU had no role in the design, analysis or writing of this article.

Conflict of interest

The authors have no conflicts of interest to declare.

Authorship

A.D.: Conceptualisation, methodology, funding acquisition, writing – original draft and formal analysis; J.L.: formal analysis, writing – review and editing; C.L.: formal analysis, writing – review and editing and visualisation; C.S.: funding acquisition, writing – review and editing.

Ethics of human subject participation

This study was conducted according to the guidelines laid down in the Declaration of Helsinki, and all procedures involving research study participants were approved by the from the National Center for Health Statistics Research Ethics Review Board. Written informed consent was obtained from all subjects. The current study was exempted from human subjects review by the New York University Institutional Review Board.

References

Panth, N, Gavarkovs, A, Tamez, M et al. (2018) The influence of diet on fertility and the implications for public health nutrition in the United States. Front Public Health 6, 211.Google Scholar
Parletta, N, Milte, CM & Meyer, BJ (2013) Nutritional modulation of cognitive function and mental health. J Nutr Biochem 24, 725743.Google Scholar
Steffen, LM, Van Horn, L, Daviglus, ML et al. (2014) A modified Mediterranean diet score is associated with a lower risk of incident metabolic syndrome over 25 years among young adults: the CARDIA (Coronary Artery Risk Development in Young Adults) study. Br J Nutr 112, 16541661.Google Scholar
Deierlein, AL, Litvak, J & Stein, CR (2022) Preconception health and disability status among women of reproductive age participating in the National Health and Nutrition Examination Surveys, 2013–2018. J Womens Health (Larchmt) 31, 13201333.Google Scholar
Deierlein, AL, Sun, Y, Prado, G et al. (2023) Socioeconomic characteristics, lifestyle behaviors, and health conditions among males of reproductive age with and without disabilities, NHANES 2013–2018. Am J Mens Health. Published online: 18 July 2023. doi: 10.1177/15579883221138190 Google Scholar
Reichard, A, Stolzle, H & Fox, MH (2011) Health disparities among adults with physical disabilities or cognitive limitations compared to individuals with no disabilities in the United States. Disabil Health J 4, 5967.Google Scholar
Horner-Johnson, W & Dobbertin, K (2014) Usual source of care and unmet health care needs: interaction of disability with race and ethnicity. Med Care 52, S40S50.Google Scholar
Horner-Johnson, W, Dobbertin, K, Lee, JC et al. (2014) Disparities in health care access and receipt of preventive services by disability type: analysis of the medical expenditure panel survey. Health Serv Res 49, 19801999.Google Scholar
Schwartz, N, Buliung, R & Wilson, K (2019) Disability and food access and insecurity: a scoping review of the literature. Health Place 57, 107121.Google Scholar
Groah, SL, Nash, MS, Ljungberg, IH et al. (2009) Nutrient intake and body habitus after spinal cord injury: an analysis by sex and level of injury. J Spinal Cord Med 32, 2533.Google Scholar
Tomey, KM, Chen, DM, Wang, X et al. (2005) Dietary intake and nutritional status of urban community-dwelling men with paraplegia. Arch Phys Med Rehabil 86, 664671.Google Scholar
Brown, MC, Marciniak, CM, Garrett, AM et al. (2021) Diet quality in adults with cerebral palsy: a modifiable risk factor for cardiovascular disease prevention. Dev Med Child Neurol 63, 12211228.CrossRefGoogle ScholarPubMed
Zwack, CC, McDonald, R, Tursunalieva, A et al. (2022) Exploration of diet, physical activity, health knowledge and the cardiometabolic profile of young adults with intellectual disability. J Intellect Disabil Res 66, 517532.Google Scholar
Joaquim, DP, Juzwiak, CR & Winckler, C (2019) Diet quality profile of track-and-field paralympic athletes. Int J Sport Nutr Exerc Metab 29, 589595.Google Scholar
Centers for Disease Control and Prevention (CDC) & National Center for Health Statistics (NCHS) National Health and Nutrition Examination Survey Data. Hyattsville, MD: U.S. Department of Health and Human Services, Centers for Disease Control and Prevention. https://www.cdc.gov/nchs/nhanes/index.htm (accessed February 2022).Google Scholar
An, R, Chiu, CY, Zhang, Z et al. (2015) Nutrient intake among US adults with disabilities. J Hum Nutr Diet 28, 465475.Google Scholar
Deierlein, AL, Litvak, J & Stein, CR (2022) Dietary quality and diet-related factors among female adults of reproductive age with and without disabilities participating in the National Health and Nutrition Examination Surveys, 2013–2018. J Acad Nutr Diet 123, 263275.Google Scholar
Krebs-Smith, SM, Pannucci, TE, Subar, AF et al. (2018) Update of the healthy eating index: HEI-2015. J Acad Nutr Diet 118, 15911602.CrossRefGoogle ScholarPubMed
de Koning, L, Chiuve, SE, Fung, TT et al. (2011) Diet-quality scores and the risk of type 2 diabetes in men. Diabetes Care 34, 11501156.Google Scholar
Panizza, C, Shvetsov, Y, Harmon, B et al. (2018) Testing the predictive validity of the healthy eating index-2015 in the multiethnic cohort: is the score associated with a reduced risk of all-cause and cause-specific mortality? Nutrients 10, 452.CrossRefGoogle ScholarPubMed
National Cancer Institute Epidemiology and Genomics Research Program SAS Code. https://epi.grants.cancer.gov/hei/sas-code.html (accessed February 2022).Google Scholar
Kirkpatrick, SI, Reedy, J, Krebs-Smith, SM et al. (2018) Applications of the Healthy Eating Index for Surveillance, Epidemiology, and Intervention Research: considerations and Caveats. J Acad Nutr Diet 118, 16031621.Google Scholar
Bickel, G, Nord, M, Price, C et al. (2000) Guide to Measuring Household Food Security, Revised. Alexandria, VA: USDA Food and Nutrition Service.Google Scholar
United States Department of Agriculture Food and Nutrition Service Supplemental Nutrition Assistance Program (SNAP). https://www.fns.usda.gov/snap/supplemental-nutrition-assistance-program-snap (accessed July 2022).Google Scholar
Greenland, S, Pearl, J & Robins, JM (1999) Causal diagrams for epidemiologic research. Epidemiology 10, 3748.CrossRefGoogle ScholarPubMed
StataCorp (2019) Stata Statistical Software: Release 15. College Station, TX: StataCorp LLC.Google Scholar
Gawlik, K, Zwierzchowska, A & Rosołek, B (2019) Effects of lifestyles of people with visual impairments on cardiometabolic risk markers. J Vis Impair Blindness 113, 433442.Google Scholar
Burri, BJ & Neidlinger, TR (2002) Dietary intakes and serum concentrations of vitamin E and total carotenoids of healthy adults with severe physical disabilities are lower than matched controls. J Am Diet Assoc 102, 18041806.Google Scholar
An, R & Chiu, C-Y (2015) Dietary intake among US adults with disability. Rehabil Res Pol Educ 29, 5974.Google Scholar
Westerkamp, EA, Strike, SC & Patterson, M (2019) Dietary intakes and prevalence of overweight/obesity in male non-dysvascular lower limb amputees. Prosth Orth Int 43, 284292.Google Scholar
Hanson, KL & Connor, LM (2014) Food insecurity and dietary quality in US adults and children: a systematic review. Am J Clin Nutr 100, 684692.Google Scholar
Andreyeva, T, Tripp, AS & Schwartz, MB (2015) Dietary quality of Americans by supplemental nutrition assistance program participation status: a systematic review. Am J Prev Med 49, 594604.CrossRefGoogle ScholarPubMed
Barnes, TL, French, SA, Mitchell, NR et al. (2016) Fast-food consumption, diet quality and body weight: cross-sectional and prospective associations in a community sample of working adults. Public Health Nutr 19, 885892.CrossRefGoogle Scholar
Nosek, MA, Hughes, RB, Robinson-Whelen, S et al. (2006) Physical activity and nutritional behaviors of women with physical disabilities: physical, psychological, social, and environmental influences. Womens Health Issues 16, 323333.Google Scholar
Nosek, MA, Hughes, RB, Howland, CA et al. (2004) The meaning of health for women with physical disabilities: a qualitative analysis. Fam Community Health 27, 621.CrossRefGoogle ScholarPubMed
Robinson-Whelen, S, Hughes, RB, Taylor, HB et al. (2006) Improving the health and health behaviors of women aging with physical disabilities: a peer-led health promotion program. Womens Health Issues 16, 334345.Google Scholar
Nosek, MA, Robinson-Whelen, S, Ledoux, TA et al. (2019) A pilot test of the GoWoman weight management intervention for women with mobility impairments in the online virtual world of Second Life(®). Disabil Rehabil 41, 27182729.Google Scholar
Liou, T-H, Pi-Sunyer, FX & Laferrere, B (2005) Physical disability and obesity. Nutr Rev 63, 321331.CrossRefGoogle ScholarPubMed
Rimmer, JH, Rowland, JL & Yamaki, K (2007) Obesity and secondary conditions in adolescents with disabilities: addressing the needs of an underserved population. J Adoles Health 41, 224229.Google Scholar
Flygare Wallén, E, Ljunggren, G, Carlsson, AC et al. (2018) High prevalence of diabetes mellitus, hypertension and obesity among persons with a recorded diagnosis of intellectual disability or autism spectrum disorder. J Intellect Disabil Res 62, 269280.Google Scholar
Schulze, MB, Martínez-González, MA, Fung, TT et al. (2018) Food based dietary patterns and chronic disease prevention. BMJ 361, k2396.Google Scholar
Lee, RE, O’Neal, A, Cameron, C et al. (2020) Developing content for the Food Environment Assessment Survey Tool (FEAST): a systematic mixed methods study with people with disabilities. Int J Environ Res Public Health 17, 7781.Google Scholar
Morris, DM & Jenkins, GR (2018) Preparing physical and occupational therapists to be health promotion practitioners: a call for action. Int J Environ Res Pub Health 15, 392.Google Scholar
McColl, MA, Gupta, S, Smith, K et al. (2017) Promoting long-term health among people with spinal cord injury: what’s new? Int J Environ Res Public Health 14, 1520.Google Scholar
Carroll, NW, Hall, AG, Feldman, S et al. (2020) Enhancing transitions from rehabilitation patient to wellness participant for people with disabilities: an opportunity for hospital community benefit. Front Public Health 8, 105.Google Scholar
Rimmer, JH, Wang, E, Pellegrini, CA et al. (2013) Telehealth weight management intervention for adults with physical disabilities: a randomized controlled trial. Am J Phys Med Rehabil 92, 10841094.Google Scholar
Scott, HM & Havercamp, SM (2016) Systematic review of health promotion programs focused on behavioral changes for people with intellectual disability. Intel Dev Disabil 54, 6376.Google Scholar
Ahluwalia, N, Dwyer, J, Terry, A et al. (2016) Update on NHANES dietary data: focus on collection, release, analytical considerations, and uses to inform public policy. Adv Nutr 7, 121134.Google Scholar
Kirkpatrick, SI, Dodd, KW, Potischman, N et al. (2021) Healthy Eating Index-2015 scores among adults based on observed v. recalled dietary intake. J Acad Nutr Diet 121, 22332241.e1.Google Scholar
Figure 0

Table 1 Distributions of socio-demographic characteristics and health behaviours among adult males of reproductive age (18–44 years) with and without self-reported disabilities, national health and nutrition examination surveys (NHANES), 2013–2018 (n 3249)

Figure 1

Table 2 Unadjusted means and adjusted mean differences in total and component Health Eating Index (HEI)-2015 scores for a given day by disability status, categorised as no disabilities, any disability, only one disability, and two or more disabilities, among male adults of reproductive age (18–44 years) in the National Health and Nutrition Examination Surveys (NHANES), 2013–2018

Figure 2

Table 3 Distributions of diet-related factors among male adults of reproductive age (18–44 years) with and without self-reported disabilities, National Health and Nutrition Examination Surveys (NHANES), 2013–2018

Figure 3

Table 4 Unadjusted and adjusted* Poisson regression models estimating associations of selected diet-related factors and disability status, categorised as no disabilities,† any disability, only one disability and two or more disabilities, among male adults of reproductive age (18–44 years) in the National Health and Nutrition Examination Surveys (NHANES), 2013–2018