On any given night in the USA, it is estimated that approximately 34 000 youth are homeless and unaccompanied(Reference Henry, de Sousa and Roddey1). These individuals are not part of a homeless family, and many leave home for the first time around an age of 14·8 years(Reference Tyler, Schmitz and Ray2). Unfortunately, once on the street, these youth are often subjected to victimisation, abuse and crime(Reference Keeshin and Campbell3–Reference Sullivan, Burnam and Koegel5). Unsurprisingly then, whether a consequence of or contributor to homelessness, homeless youth are also more likely to experience poor mental health compared with housed peers(Reference Votta and Farrell6): an estimated 23–74 % of unaccompanied homeless youth have at least one mental disorder, the most common being major depressive disorders, anxiety, conduct disorder, post-traumatic stress disorder and bipolar disorders(Reference Whitbeck, Hoyt and Bao7,Reference Chen, Thrane and Whitbeck8) .
On the street, homeless youth are challenged to find adequate resources(Reference Dachner and Tarasuk9). Competing demands such as generating income, obtaining transportation and finding housing leave little time for food acquisition, compromising the youths’ ability to meet their nutritional needs(Reference Dachner and Tarasuk9). As a result, many homeless youth do not consume adequate amounts of food and/or nutrients(Reference Tarasuk, Dachner and Poland10–Reference Tse and Tarasuk12). Previous diet studies in homeless youth indicate a low consumption of fruit, vegetables and whole grains, resulting in inadequate intakes of several vitamins and minerals (vitamins A, C, D3 and E as well as Ca and Mg)(Reference Yarcusko, Slesnick and Hatsu11,Reference Hatsu, Gunther and Hade13,Reference Fallaize, Seale and Mortin14) , which can be harmful during periods of substantial growth and development like adolescence. Furthermore, when food is available, it is typically inexpensive, energy-dense packaged or fast food(Reference Dachner and Tarasuk9,Reference Booth15,Reference Crawford, Yamazaki and Franke16) . Difficulties meeting nutritional needs may also be compounded in homeless youth with poor mental health(Reference Narendorf, Cross and Santa Maria17,Reference Klein, Woods and Wilson18) , as studies have found these individuals generally consume more calories, carbohydrates, added sugars and fats than their peers without mental health disorders(Reference Firth, Stubbs and Teasdale19). Limited evidence exists considering the intake of essential fatty acids among homeless youth, but it may be hypothesised that intakes of n-3 PUFA, specifically the long-chain n-3 PUFA, EPA and DHA, are low due to the large amount of processed and packaged foods consumed by this population.
Mental health has been associated with PUFA, especially DHA, because of the role fatty acids play in the brain(Reference Chianese, Coccurello and Viggiano20). Grey matter and synapses are highly saturated in DHA and other n-3 PUFA(Reference Chianese, Coccurello and Viggiano20), and approximately 4·6 mg of DHA are used by the brain each day(Reference Rapoport, Rao and Igarashi21). Since body concentrations of PUFA are generally conserved in adulthood(Reference Bazinet and Layé22), this amount plus DHA needed by other organ systems must be replenished by food or by the conversion of α-linolenic acid (ALA) or EPA to DHA. However, conversion of ALA to EPA and DHA is small in humans (estimated at 10 % in males and 14 % in females) and is dependent on the background diet of the individual(Reference Arterburn, Hall and Oken23–Reference Cholewski, Tomczykowa and Tomczyk25). Seafoods (e.g. fatty fish and shellfish) are the primary source of the long-chain n-3 FA EPA and DHA in the human diet(Reference Cholewski, Tomczykowa and Tomczyk25), but these foods are generally expensive(Reference Kennedy, Luo and Ausman26), require preparation and mostly unavailable in places where homeless youth access food. Therefore, extensive barriers exist for adequate n-3 PUFA consumption in homeless youth. Considering the impact of diet on mental health, several studies, but not all, have shown that a higher consumption of fish rich in n-3 PUFA was associated with fewer depressive symptoms(Reference Berger, Smesny and Kim27–Reference Tanskanen, Hibbeln and Tuomilehto29). Additionally, postmortem studies have found that individuals with severe depression have lower DHA concentrations in their orbitofrontal cortex compared with controls without mood disorders(Reference McNamara, Hahn and Jandacek30). Although there is evidence to support a correlation between PUFA status and mental health in the general population, it is not known if this association is present among homeless youth(Reference Messamore, Almeida and Jandacek31).
The objective of this project was to quantify long-chain PUFA dietary intake and erythrocytes status among homeless youth, as well as determine whether n-3 PUFA relates to depression and anxiety. Our central hypothesis is that depression and anxiety will be inversely associated with intake and biological levels of n-3 PUFA (i.e. EPA, docosapentaenoic acid and DHA). Though homeless youth are subject to poor diet quality and stressful environmental factors, no known research to date has explored the association of n-3 PUFA and mental health in this population.
Methods
Study population and eligibility
This cross-sectional, observational study utilised survey data and biological samples from 114 homeless and unaccompanied youth recruited from a drop-in center in a large midwestern city in the USA who have been described previously in a study of other nutritional vulnerabilities(Reference Hatsu, Gunther and Hade13). This additional analysis is the first to analyse biological samples collected during this study. Homeless individuals, as defined in the McKinney-Vento Homeless Assistance Act (2002)(32), included ‘those who lack a fixed, regular and adequate nighttime residence’. Eligibility for study inclusion were: (1) meeting the criteria for homelessness, as defined by the McKinney-Vento Act (2002); (2) being aged 18 to 24 years; and (3) understanding and signing an informed consent form. Exclusion criteria for the study included self-reported pregnancy due to the physiological and dietary changes that occur during this time.
Participants were recruited by flyer and word-of-mouth. After providing informed consent, potential participants completed a screening questionnaire, and those who met the inclusion criteria were enrolled in the study. Participants completed questionnaires on sociodemographic factors, homeless experience, dietary intake and mental health status, as well as provided a venous blood sample for fatty acid quantification. Participants were compensated $25 following the completion of all questionnaires, assessments and biological sampling.
Ethical approval
The current study was conducted according to the guidelines laid down in the Declaration of Helsinki and all procedures involving human participants were approved by the Ohio State Behavioral and Social Sciences IRB (Protocol #2015H0265). Written informed consent was obtained from all participants.
Measures
Sociodemographic measures
Self-administered paper questionnaires were used to collect demographic data such as age, sex, race, ethnicity, education and employment status. Homeless characteristics, such as the age of first homelessness and length of current homelessness, were also recorded.
Nutrient intake
The Block Food Frequency Questionnaire for Adults(Reference Block, Woods and Potosky33), which is based on approximately 127 food items, was used to quantify the nutrient intake of all participants. A trained interviewer introduced the self-administered questionnaire, answered questions and read the questionnaire to the participant if literacy was limited.
Mental and overall health assessments
The Beck Depression Inventory Second Edition (BDI-II)(Reference Beck34) and the Beck Anxiety Inventory (BAI)(Reference Beck, Epstein and Brown35) were completed by each participant to assess depression and anxiety symptoms, respectively. These are both validated twenty-one question, self-reported inventories for individuals at least 13 years of age to characterise symptom severity, not to diagnose(Reference Beck34,Reference Beck, Epstein and Brown35) . Responses for both inventories were rated and totaled, with possible final scores ranging from 0–63. Higher scores on these assessments indicate more severe symptoms of depression and anxiety, respectively(Reference Beck34). Specifically, the predetermined cut-off used were as follows: depression (0–13: minimal, 14–19: mild, 20–28: moderate, 29–63: severe) and anxiety (0–7: minimal, 8–15: mild, 16–25: moderate, 26–63: severe)(Reference Beck34,Reference Beck, Epstein and Brown35) .
Biochemical assessment and lipid extraction
Fatty acid profiles were determined using gas chromatography after lipid extraction and methylation of erythrocytes. Erythrocytes fatty acids are not sensitive to short term dietary changes, have little biological variability compared with plasma fatty acids and represent PUFA status over several months(Reference Harris and Thomas36), making them an appropriate biomarker of long-chain PUFA intake for this study. Additionally, the sum of erythrocytes EPA + DHA, known as the n-3 Index, is a potential risk factor for chronic disease, including bipolar disorder in adolescents(Reference Harris37,Reference McNamara, Jandacek and Tso38) . A non-fasted venous blood sample (40 ml) was taken from each participant and filled into vials containing anticoagulants. The sample was centrifuged within 1-h post-collection, and erythrocytes were aliquoted into microcentrifuge tubes. Specimens were stored at −80oC until analysis.
Using standard procedures previously described by Harris et al. (Reference Harris, Lemke and Hansen39), fatty acids were extracted and methylated from erythrocytes samples. At the time of analysis, aliquots of erythrocytes were thawed on ice and 50 µl transferred to a glass tube containing 500 µl 14 % boron trifluoride (BF3) in methanol with butylated hydroxytoluene (Sigma Aldrich, St. Louis, MO). The sample was vortexed for 30 s followed by the addition of 500 µl of hexane and heating at 100oC in a bead bath for 10 min. After cooling to room temperature, 500 µl deionised water was added, and the samples were vortexed. They were then centrifuged for 3 min at 3000 g and 25oC. The top hexane phase containing the fatty acid methyl esters was transferred into a glass vial using a glass pipette and stored at −20oC until gas chromatography. The samples were analysed on a gas chromatograph (Shimadzu, Columbia, MD) using a 30-m capillary column (Omegawax™ 320, Supelco-Sigma). Retention times were compared with authentic standards for fatty acid methyl esters (Supelco-Sigma, St. Louis, MO and Matreya, Inc., Pleasant Gap, PA), and fatty acids were reported as a percentage of total fatty acids identified in the sample.
Statistical analysis
Descriptive statistics (reported as means and standard deviation or as proportions) were used to summarise participants’ psychological well-being (from the BDI-II and BAI questionnaires) as well as their long-chain PUFA intake and erythrocytes PUFA status. Independent sample t-tests were used to determine differences in means by sex. The sex-based subgroup analysis was predicated on previous research that showed sex-based differential nutrient intake and diet quality among homeless youth(Reference Hatsu, Gunther and Hade13), as well as the sex differences in the regulation and metabolism of n-3 fatty acids(Reference Childs, Romeu-Nadal and Burdge40). Depression and anxiety scores from the BDI-II and BAI were initially categorised into minimal, mild, moderate or severe for descriptive purposes, with the categories further collapsed into three groups (minimal, mild and moderate/severe) for modeling purposes. Dietary fatty acid intake was energy adjusted for use in linear regression models. Linear regression models were used to determine associations of dietary and erythrocytes n-3 PUFA status (dependent variables) with psychological well-being (independent variables: 3-level BDI-II and 3-level BAI in separate models), adjusting for age, sex, age first homeless and number of months without shelter, based on prior research(Reference Hatsu, Gunther and Hade13). To test for moderation of psychological well-being effects by sex, interactions between BDI-II/BAI and sex were added to these models. Statistical analyses were conducted using R (https://www.R-project.org). Because sample size was determined by the feasibility of recruitment, it was determined that a sample size of 114 would detect a large effect size (f2 = 0·337) at 0·90 power and an α of 0·05(Reference Faul, Erdfelder and Buchner41).
Results
Participant characteristics
The average age of study participants was 21·4 ± 1·8 years, and 70 % of participants were male. About half of the participants (49 %) identified as Black/African American, 28 % identified as White and 17 % identified as ‘other’. The average BMI (Body Mass Index) for the sample was 27·8 ± 8·3 kg/m2, though females had a significantly higher BMI (32·5 ± 9·9 kg/m2) compared with males (25·8 ± 6·7 kg/m2; P = 0·007). Approximately two-thirds of participants (62 %) had a high school diploma or GED, 27 % had no diploma and only 4 % had an associate, technical or vocational degree (Table 1). Most youth were first homeless after the age of 18 (75 %), with the average age of first homelessness being 18·2 ± 3·1 years. However, 18 % were homeless between the ages of 15 and 17 and a further 6 % at 14 years of age or younger. About 42 % of study participants reported having been homeless for over 4 months. Reasons for current homelessness included financial instability and unemployment, arguments with family and friends, being thrown out and personal choice.
* BMI.
† General educational development test.
Dietary fatty acid intake
Table 2 shows the dietary fatty acid profile obtained from self-reported FFQ data (not energy-adjusted). The typical daily intake of select n-3 PUFA were 24·65 ± 26·77 g linoleic acid (LA)/d, 0·20 ± 0·23 g arachidonic acid (ARA)/d, 0·06 ± 0·13 g EPA/d and 0·11 ± 0·24 g DHA/d. Males and females had similar PUFA intakes except for ARA; males reported consuming significantly more ARA than females (0·24 ± 0·24 v. 0·13 ± 0·18 g/d; P = 0·043).
ARA, arachidonic acid; LA, linoleic acid; ALA, α-linolenic acid; DPA, docosapentaenoic acid.
* P < 0·05.
† Two-sample t-test of fatty acid intake.
Fourteen participants had no dietary intake data hence n 100.
Erythrocytes fatty acid profile
The mean erythrocytes EPA + DHA composition (the n-3 index) was 2·42 % (EPA: 0·28 ± 0·17 % and DHA: 2·14 ± 0·57 %). Mean compositions for ALA and docosapentaenoic acid n-3 were 0·54 ± 0·63 % and 1·77 ± 0·33 %, respectively. There were no significant differences in fatty acid percentages by sex except DHA, with females having a higher mean concentration of DHA than males (females: 2·37 ± 0·70 %; males: 2·04 ± 0·48 %; P = 0·005) (Table 3).
LA, linoleic acid; GLA, γ-linolenic acid; ALA, α-linolenic acid; EDA, eicosadienoic acid; DGLA, dihomo-γ-linolenic acid; ARA, arachidonic acid; DTA, docosatetraenoic acid; DPA, docosapentaenoic acid.
† Two-sample t-test of fatty acid erythrocytes status.
** P < 0·01.
Mean CV from duplicate or triplicate samples was 3·4 % for LA, 6·6 % for ALA, 2·7 % for EPA and 2·9 % for DHA. ALA was below the limit of detection (LOD) for fourteen participants, and EPA was below the LOD for twenty-seven participants. Not all participants that had ALA below LOD also had EPA below LOD.
Depression and PUFA
About 41 % of participants reported having minimal depression, 32 % had mild depression and 27 % had moderate or severe depression (Table 4). Furthermore, females reported more severe depression symptoms than males (average BDI-II scores 20·4 ± 15·2 v. 12·2 ± 10·9; P = 0·007). Unadjusted and adjusted analyses did not yield any significant associations between depression category and dietary intakes of n-3 PUFA (energy-adjusted) (Table 5). However, significant moderation of this relationship existed by sex for dietary EPA and DHA as well as erythrocytes DHA and n 3-index. Specifically, among females, as depression outcomes increased, PUFA intake and status decreased. This significant moderation persisted (Diet EPA: P = 0·017, Diet DHA: P = 0·008; erythrocytes DHA: P = 0·007, n 3-index P = 0·009), even after adjusting for confounders (age, age first homeless and months without shelter) (Fig. 1 and online Supplementary Table 2). This relationship, however, was not noted among males.
n 113; Males n 80, females n 33. Missing BDI/BAI score from one participant.
* Energy adjusted.
† Controlling for age, sex, age first homeless and months without shelter.
P < 0·05.
n varied for Dietary intake and erythrocytes data. Diet: Minimal (n 38), Mild (n 35), Moderate/Severe (n 26).
Erythrocytes: Minimal (n 47), Mild (n 36), Moderate/Severe (n 30).
Erythrocytes n 3-Index = erythrocytes EPA + DHA.
Anxiety and PUFA
Over half of participants (54 %) reported having minimal anxiety, 25 % had mild anxiety and the remaining 21 % had moderate or severe anxiety (Table 4). Like depressive symptoms, females reported having more severe anxiety symptoms compared with males (average BAI scores 14·0 ± 14·5 v. 8·04 ± 9·62; P = 0·03). No significant associations were found between erythrocytes status by anxiety category and n-3 PUFA intake (energy-adjusted) (Table 6). Similarly, no moderation by sex was found for this relationship (online Supplementary Table 2 and Supplementary Fig. 1).
† Energy adjusted.
‡ Controlling for age, sex, age first homeless and months without shelter.
n varied for dietary intake and erythrocytes data:
Diet: Minimal (n 38), mild (n 35), moderate/severe (n 26).
Erythrocytes: Minimal (n 47), mild (n 36), moderate/severe (n 30).
Erythrocytes n 3-Index = erythrocytes EPA + DHA.
Discussion
The current study had two aims: to characterise the long-chain PUFA dietary intake and erythrocytes status of homeless youth and to determine whether depression and anxiety relate to n-3 PUFA. As a vulnerable, understudied population, little is known about the dietary intake and erythrocytes status of n-3 fatty acids among homeless youth. ALA consumption of study participants generally met the adequate intakes set by the National Academy of Nutrition, with mean ALA intakes of 2·75 g/d for men (adequate intakes: 1·6 g/d) and 1·65 g/d for women (adequate intakes: 1·1 g/d)(Reference Trumbo, Schlicker and Yates42). However, the mean intakes of EPA and DHA for all participants were, respectively, 60 mg/d and 110 mg/d, which is well below the recommended 450–500 mg/d EPA and DHA(Reference Vannice and Rasmussen43). There were no significant differences in the intake of PUFA by sex except for ARA. Given that homeless youth have limited access and consumption of healthy foods including fish, a primary source of essential fatty acids in the American diet, this inadequate intake is unsurprising. Seafood, particularly fatty fish such as salmon, herring and mackerel, is typically expensive and requires preparation, and fish that is more affordable and accessible for homeless youth is typically white fish that is lower in PUFA(Reference Kennedy, Luo and Ausman26). Additionally, lower income and younger age have been associated with lower odds of consuming seafood(Reference Jahns, Raatz and Johnson44). This has negative implications for homeless youth, since essential PUFA cannot be synthesised de novo and must be consumed in the diet.
Given the youths’ low intakes of EPA and DHA, a low biological n-3 PUFA status is expected. Mean erythrocytes EPA + DHA composition in this homeless youth cohort (2·42 %) was lower than what has been found in healthy, housed adolescents as well as those with clinical depression: McNamara et al. recorded a erythrocytes EPA + DHA composition of 4·24 % for healthy adolescents and a composition of 3·10 % for those with depression(Reference McNamara, Strimpfel and Jandacek45), while Pottala et al. found compositions of 3·71 % and 3·47 %, respectively(Reference McNamara, Strimpfel and Jandacek45). Both of the aforementioned studies were conducted in urban Midwestern cities similar to the present study’s location. Although dietary intakes of n-3 PUFA are correlated with erythrocytes concentrations, additional factors may be contributing to the low biological statuses observed(Reference Orchard, Ing and Lu47). Prolonged psychological stress, depression or anxiety can stimulate dysfunction in the hypothalamic–pituitary–adrenal axis, releasing proinflammatory hormones that promote the oxidation of PUFA(Reference Thesing, Bot and Milaneschi48,Reference Schiavone, Jaquet and Trabace49) . Since homeless youth live in stressful environments and have high rates of depression and anxiety, these oxidative effects may contribute to the low n-3 PUFA status observed in the sample. Additionally, alcohol intake has been found to deplete DHA in the brain(Reference Collins50), and its effects on erythrocytes composition are unknown. Although alcohol intake was not accounted for in this study, its consumption among homeless youth may also contribute to the low biological levels observed.
Compared with housed youth, homeless youth are about twice as likely to suffer from depression(Reference Whitbeck, Hoyt and Bao7). Our study shows that one-quarter of homeless youth had moderate or severe depression, and females reported more depressive symptoms than males. These findings validate previous studies of depression prevalence among homeless youth in urban USA cites(Reference Whitbeck, Hoyt and Bao7,Reference Chen, Thrane and Whitbeck8,Reference Bender, Brown and Thompson51) . One study using the Mini International Neuropsychiatry Interview found that 31·3 % of homeless youth had depression(Reference Bender, Brown and Thompson51), while another study using the Center for Epidemiologic Studies Depression Scale (CES-D) found that 23 % of males and 39 % of females met the cut-off for clinical depression(Reference Whitbeck, Hoyt and Bao7). In addition to a high depression prevalence, this also suggests that homeless females may be disproportionally affected by depression. Previous research attempted to explain this observation with the suggestion that females may exhibit greater depressive symptomatology due to increased susceptibility to sexual or physical abuse on the streets compared with males(Reference Lim, Rice and Rhoades4), but further research is needed concerning this disparity.
The present study found that dietary intakes and erythrocytes status of n-3 PUFA were not associated with depression symptoms. It is unknown whether poor n-3 PUFA intake precedes depression or is a result of depression. However, several observational studies have found significant negative associations between fish intake and depression(Reference Berger, Smesny and Kim27,Reference Tanskanen, Hibbeln and Tuomilehto29,Reference Edwards, Peet and Shay52) , and mood has been shown to influence diet: individuals with depressive symptomology typically prefer more palatable, high fat, energy-dense foods, which are low in n-3 PUFA(Reference Macht, Gerer and Ellgring53). Biological levels of n-3 PUFA have also been previously negatively associated with depression. In a case–control study of adolescents aged 13–18 years, those with depression had significantly lower erythrocytes levels of DHA and ALA but not EPA than controls(Reference Pottala, Talley and Churchill46). Similarly, a small study of fourteen control and ten depressed adults by Edwards et al. found that EPA, DHA and ALA status were all significant predictors of depression(Reference Edwards, Peet and Shay52). Interestingly, among adolescents who were supplemented with n-3s as part of a krill oil trial, depression was not associated with biological levels of DHA, EPA or n-3 index(Reference van der Wurff, von Schacky and Bergeland54). The finding that the relationship of depression with n-3 PUFA intake and status is moderated by sex, where increased depression was associated with low n-3 PUFA among female youth is novel. A similar finding, however, has been noted in elderly Japanese women with overweight or obesity(Reference Tsujiguchi, Thi Thu Nguyen and Goto55).
Although higher rates of anxiety are expected in homeless youth due to trauma, victimisation and unstable living conditions(Reference Tyler, Schmitz and Ray2), previous studies of homeless youth have reported that most participants experience minimal anxiety symptoms(Reference Saperstein, Lee and Ronan56). This supports the rates found in the present study: half of participants reported having minimal anxiety symptoms, with females reporting more severe anxious symptoms than males. Poor diets, particularly the Western diet, have been associated with anxiety(Reference Jacka, Pasco and Mykletun57), and homeless youth consume diets that are typically low in fruits, vegetables and fish but high in refined carbohydrates, saturated fat and fast food(Reference Hatsu, Gunther and Hade13). We observed no relationship between anxiety and n-3 PUFA intake and status, which is similar to prior findings. In a cross-sectional, community-based study of women over the age of 20 years, there was no relationship between ALA, EPA or DHA intake and anxiety disorders; however, these women consumed about twice as much n-3 PUFA as our participants(Reference Jacka, Pasco and Williams58). Similarly, anxiety symptoms were not related to plasma n-3 PUFA concentrations in a sample of middle-aged, housed adults(Reference Thesing, Bot and Milaneschi59).
The study strengths include the use of an objective blood biomarker of long-term fatty acid status in our assessment in addition to a validated self-reported measure of dietary intake to assess n-3 consumption. However, we acknowledge that there are limitations as well. A key limitation of this study, as with most research among homeless youth, is the cross-sectional nature of the data. Homeless youth are a transient, difficult-to-reach population, making longitudinal studies impractical. Therefore, the cross-sectional analysis can only suggest an association of depression and anxiety with n-3 PUFA intake and status; it fails to show causality. The difficult-to-reach characteristic of homeless youth also necessitated the use of an FFQ with this population, instead of using diet record or multiple administrations of 24 h dietary recalls, to determine usual dietary intake. FFQ are prone to random and systematic errors; however, they have been shown to be more valid for estimating long-chain PUFA in various populations(Reference Kobayashi, Jwa and Ogawa60–Reference Øverby, Serra-Majem and Andersen62). FFQ-derived dietary PUFA are not always correlated with blood levels(Reference Wan, Pan and Mori63). However, the inclusion of PUFA blood biomarker assessment, as done in the current study, provides an unbiased long-term measure of PUFA, devoid of recall bias. Second, the study sample is a convenience sample of homeless youth who utilise drop-in centres and therefore may not be representative of all youth experiencing homelessness in this midwestern city. Additionally, due to the small sample size, our findings may not be generalisable. Nonetheless, the findings in this study are significant as they add to the literature on the nutritional vulnerabilities of a transient and difficult to reach population. Larger studies are warranted to confirm these findings. As a vulnerable population, homeless youth disproportionately experience metal health challenges and lack adequate intake of foods including fruits, vegetable, whole grains and healthy fats(Reference Yarcusko, Slesnick and Hatsu11,Reference Hatsu, Gunther and Hade13,Reference Fallaize, Seale and Mortin14) . Current evidence continues to emphasise the importance of a healthy diet and nutrition in preventing metal health conditions and/or ameliorating the effects of these conditions(Reference Firth, Marx and Dash64–Reference Głąbska, Guzek and Groele67). The current study further highlights the mental health and dietary needs of homeless young adults, suggesting the need for increased focus on essential fatty acids intake among homeless youth, especially females.
Acknowledgements
The authors wish to thank the study participants for their time and effort.
This project was supported by the Ohio State University College of Education and Human Ecology; the National Center for Advancing Translational Sciences, Grant 8UL1TR000090-05 and the State Agricultural Experiment Station North Central Research Project NC1193: Promotion of Health and Nutrition in Diverse Communities of Emerging Adults with the Agricultural Experiment Stations in Ohio. Conceptualisation: I. E. H., T. S. O. and N. S.; study design and implementation: I. E. H., T. S. O., N. S. and S. M. R.; data analysis and interpretation: R. A., I. E. H., T. S. O., S. B. D., S. M. R.; writing – original draft: S. M. R. and S. B. D.; writing – review and editing: S. B. D., I. E. H., T. S. O., S. M. R., R. A. and N. S. All authors have read and agreed to the published version of the manuscript.
There are no conflicts of interest.
Supplementary material
For supplementary material/s referred to in this article, please visit https://doi.org/10.1017/S000711452300212X