The US Department of Agriculture (USDA) defines food security as having reliable access to adequate food for a healthy lifestyle⁽Reference Coleman-Jensen, Gregory and Rabbitt¹⁾. Food insecurity is a worldwide public health concern linked to detrimental health, psychological and social outcomes⁽Reference Laraia^2–Reference Gundersen and Ziliak⁴⁾. In the most recent federal survey of food insecurity conducted in 2017, the national prevalence of food insecurity was estimated as 11·8 % (15 million households), with 7·3 % reporting low food security (e.g. reduced quality, variety or desirability of diet, with little to no indication of reduced food intake) and 4·5 % reporting very low food security (e.g. disrupted eating patterns and reduced food intake due to reduced availability of food)⁽Reference Coleman-Jensen, Gregory and Rabbitt¹⁾. An additional 10·6 % of households with children, and 6·6 % of those without children, reported marginal food security, defined as anxiety over the availability of food or shortage of food with little evidence of changes in diet or food intake⁽Reference Coleman-Jensen, Rabbitt and Gregory⁵⁾.

Food insecurity status is associated with obesity and obesity-related co-morbidities and has been extensively researched in diverse populations⁽Reference Coleman-Jensen, Gregory and Rabbitt^1, Reference Ashby, Kleve and McKechnie^6–Reference Epstein, Jankowiak and Lin⁸⁾. In a 2012 survey of 66 500 adults in twelve US states, food insecurity was associated with a 32 % increase in the odds of obesity, reflecting a prevalence of 35·1 % among those with food insecurity compared with 25·2 % in food-secure adults⁽Reference Pan, Sherry and Njai⁹⁾. Adult food insecurity is a risk factor for diabetes and CVD, conditions especially impacted by poor diet quality⁽Reference Laraia^2, Reference Gundersen and Ziliak^4, Reference Seligman, Bindman and Vittinghoff¹⁰⁾, and is also associated with poorer management of chronic health conditions, leading to adverse health outcomes⁽Reference Gundersen and Ziliak^4, Reference Shalowitz, Eng and McKinney^11–Reference Berkowitz, Gao and Tucker¹³⁾. The literature on the relationship between food insecurity and body weight is somewhat inconsistent and appears to be moderated by gender, with a linear relationship between degree of food insecurity and body weight consistently observed for women, compared with mixed findings among men⁽Reference Franklin, Jones and Love¹⁴⁾. There is also some evidence that the relationship between food insecurity and weight might be curvilinear, with lower BMI at both very high and very low levels of food insecurity⁽Reference Franklin, Jones and Love¹⁴⁾.

One explanation for the relationship between obesity and food insecurity is that persons who experience food insecurity rely on energy-dense processed foods as these foods are typically cheaper, more readily accessible and less perishable than nutrient-dense foods such as fruits, vegetables and dairy products⁽Reference Berkowitz, Berkowitz and Meigs^3, Reference Lyles, Wolf and Schillinger^12, Reference Berkowitz, Gao and Tucker^13, Reference Drewnowski and Specter¹⁵⁾. In a nationally representative sample of US adults aged 18–64 years, adult food insecurity status predicted both obesity risk and poorer overall dietary quality when other demographic factors, including household poverty, were controlled⁽Reference Bhattacharya, Currie and Haider¹⁶⁾. Adults who experience food insecurity report unhealthy food choices relative to food-secure peers, including higher fat and fruit juice intakes, and lower fruit, vegetable and dairy consumption⁽Reference Berkowitz, Gao and Tucker^13, Reference Hanson and Connor^17, Reference Mello, Gans and Risica¹⁸⁾. Another potential explanation involves the cyclical nature of food insecurity, which can be characterized by periods of relative availability of food, or even of overeating, followed by periods of scarcity⁽Reference Seligman, Bindman and Vittinghoff^10, Reference Drewnowski and Specter¹⁵⁾. Food insecurity has also been linked to disordered eating behaviours, including binge eating and dietary restraint, both of which involve irregular eating patterns and are risk factors for excessive energy intake and weight gain⁽Reference Becker, Middlemass and Taylor¹⁹⁾. Irregular eating habits can contribute to obesity and impede weight-loss efforts⁽Reference Seligman, Bindman and Vittinghoff^10, Reference Drewnowski and Specter¹⁵⁾, and are particularly dangerous and detrimental to weight loss following bariatric surgery, when diverging from a regular eating schedule can lead to dehydration and malnutrition.

The prevalence of adult obesity has continued to increase in recent years and with it the prevalence of co-morbidities including type 2 diabetes, heart disease and hypertension⁽Reference Martin and Ferris^20, Reference Van Gaal and Maggioni²¹⁾. Bariatric surgery is currently the most effective treatment for achieving significant, long-term weight loss and improvement in obesity-related metabolic and cardiovascular co-morbidities (e.g. type 2 diabetes, hypertension, obstructive sleep apnoea)⁽Reference Gloy, Briel and Bhatt^22–Reference Sarkhosh, Switzer and El-Hadi²⁵⁾. However, as many as 30 % of patients do not achieve or maintain their predicted weight loss and behavioural adherence to postoperative dietary recommendations is a major predictor of postsurgical success⁽Reference Chang, Stoll and Song²⁶⁾. Current postoperative bariatric guidelines emphasize the importance of eating a diet high in fresh fruits and vegetables and particularly high in protein; an average protein intake of 60–120 g/d is recommended both for weight loss and long-term weight maintenance⁽Reference Aills, Blankenship and Buffington^27–Reference Ziegler, Sirveaux and Brunaud²⁹⁾. In addition, bariatric surgery patients require lifelong oral vitamin and mineral supplementation, with poor adherence increasing the risk for malnutrition and other complications⁽Reference Parrott, Frank and Rabena^30, Reference Tucker, Szomstein and Rosenthal³¹⁾. Use of protein supplements is also recommended: restricted stomach volume, malabsorption (in the case of gastric bypass) and the relatively high rate of postoperative intolerance for animal protein make it difficult for many patients to meet the recommended high protein intake with food alone⁽Reference Aills, Blankenship and Buffington²⁷⁾. Use of protein supplements after surgery may be associated with improved weight-loss outcomes⁽Reference Andreu, Moizé and Rodríguez³²⁾. It seems very likely that food insecurity would negatively affect bariatric patients’ ability to maintain these dietary changes over the long term; by definition, individuals with low and very low food security lack reliable access to the amount and types of foods they need to maintain a healthy lifestyle. Despite the universally acknowledged importance of dietary adherence for post-bariatric weight-loss maintenance, the prevalence and features of food insecurity have not been studied in this population.

The purpose of the present study was to assess the prevalence of self-reported food insecurity in a pre-bariatric surgery sample and to explore demographic, clinical and behavioural correlates of food insecurity in this population. Three groups of exploratory hypothesis tests were conducted. The first series of tests involved demographic correlates: participant gender, age, ethnicity, education attainment, adjusted gross income and population density of participants’ zip codes of residence, and participation in food assistance programmes and Medicare/Medicaid. The second series of tests involved clinical correlates: BMI at programme entry and obesity-related co-morbidities (type 2 diabetes, heart disease/hypertension and obstructive sleep apnoea). The third series of tests involved participant-reported perceptions and behaviours related to food and nutritional supplement purchases.

The USDA report on household food insecurity in the USA in 2016 by Coleman-Jensen et al. identifies a higher prevalence of food insecurity in households that are low-income, headed by a single parent, or reporting a Black non-Hispanic or Hispanic ethnicity⁽Reference Coleman-Jensen, Gregory and Rabbitt¹⁾. This is consistent with literature reviews that also reported similar demographic correlates of food insecurity along with a strong relationship with being female and having less than a college education level⁽Reference Gundersen and Ziliak^4, Reference Franklin, Jones and Love¹⁴⁾. We expected to replicate these demographic correlates of food insecurity in the study population. We predicted that living in a city centre would be associated with food insecurity, as the cities represented in our sample are predominantly low-income. Analyses comparing rural v. urban/suburban zip codes were exploratory. Because the relationship between food insecurity and body weight might differ between men and women, we explored this relationship separately for women, hypothesizing that a positive relationship between food insecurity and BMI would be identified in the female sub-sample. Analyses regarding co-morbid diagnoses were exploratory; although type 2 diabetes and hypertension are more common in adults with food insecurity⁽Reference Laraia^2, Reference Gundersen and Ziliak^4, Reference Seligman, Bindman and Vittinghoff¹⁰⁾, obesity-related co-morbidities are very common in pre-bariatric populations and so we did not have specific hypotheses regarding their association with food insecurity in this sample. Finally, we developed five questions related to food shopping behaviours; because they were derived from the literature on shopping and eating behaviours associated with food insecurity in general samples, we expected to find that endorsement of all five questions was higher in food-insecure participants.

Our sample was broken down into food-secure, marginally food-secure and food-insecure groups. The USDA Statistical Supplement and other literature have identified marginally food-secure people as having characteristics more similar to food-insecure groups than food-secure groups⁽Reference Gundersen and Ziliak^4, Reference Coleman-Jensen, Rabbitt and Gregory^5, Reference Franklin, Jones and Love¹⁴⁾. We expected to broadly replicate this finding, hypothesizing that marginally food-insecure participants would show demographic, clinical and behavioural features that were either more similar to food-insecure participants or that fell between food-secure and food-insecure participants.

The present study is the first exploration of the demographic, clinical and behavioural correlates of food insecurity in a bariatric sample. A better understanding of the demographic correlates of food insecurity specific to presurgical bariatric populations might help to guide programming and clinical decision making aimed at identifying and assisting patients who might be at risk for food insecurity. Exploring the relationship of food insecurity category with continuous BMI and common obesity-related co-morbidities is a first step in beginning to quantify the potential impact of food insecurity on health status in this population. The five behavioural questions were included to better understand food shopping behaviours and beliefs about the accessibility of post-bariatric vitamins and supplements through which food insecurity might affect bariatric dietary adherence and outcomes, with the goal of developing causal hypotheses for future studies with prospective or experimental (e.g. intervention) designs.

Methods

Measures

Food insecurity screening

Participants responded to the ten-item USDA adult food security survey module⁽Reference Coleman-Jensen, Gregory and Rabbitt^1, Reference Bickel, Nord and Price³³⁾. The measure includes three screening items and seven items designed to assess household food insecurity for adult respondents. Although this measure is usually administered by an interviewer, we modified the items for self-report. Standard administration involves reading the questions and response options aloud to the participant, often over the telephone; the text of the items and response options was given to participants with no changes to the wording and no additions to or deletions from any item⁽Reference Bickel, Nord and Price³³⁾. A bariatric psychologist was available during administration to answer participants’ questions about the items and survey as needed. An affirmative answer (e.g. ‘often true’ or ‘sometimes true’) to each item is scored as 1 (for two items assessing the frequency of behaviours associated with food insecurity, responses of ‘never’ or ‘only one or two months’ are scored as negative and responses of ‘some months but not every month’ and ‘almost every month’ are scored as affirmative). The adult food security survey module yields a score ranging from 0 to 10. The continuous score is used to create four food security categories. A score of 0 is scored as food secure, 1–2 as marginally food secure, 3–6 as low food security and 7–10 as very low food security⁽Reference Bickel, Nord and Price³³⁾. Given the relatively low base rate of very low food security in our sample, we grouped participants with low and very low food security into a single category, as recommended in the USDA guide⁽Reference Coleman-Jensen, Gregory and Rabbitt^1, Reference Coleman-Jensen, Rabbitt and Gregory⁵⁾. The ten-item continuous score (used in correlational analyses with BMI) demonstrated good internal consistency: α = 0·84.

Demographics

Participants self-reported their age, gender, race/ethnicity and years of education on the Weight and Lifestyle Inventory (WALI)⁽Reference Wadden and Foster³⁴⁾, a commonly used instrument in pre-bariatric psychological assessment. Participants’ electronic medical records were accessed to obtain their insurance information and the zip code of their current address. Zip codes were used to identify whether participants lived in an urban or rural municipality, whether they lived in a city centre and whether their municipality’s median income was greater or less than $US 50 000. Urban v. rural areas were defined using the US Census Bureau definition of rural municipalities as having fewer than 2500 people per square mile, with any municipality with a population density greater than 2500 per square mile defined as urban⁽³⁵⁾ (1 mile² = 2·59 km²). Participants with zip codes within the boundaries of larger urban centres (defined as cities with population greater than 25 000) were coded as being city residents⁽³⁶⁾. The seven cities represented in this sample, i.e. Harrisburg, Lancaster, Lebanon, York, Bethlehem, State College and Reading, PA, are majority low-income with low access to food according to US Census Bureau 2010 statistics⁽³⁷⁾. Median zip code income was assessed using 2015 adjusted gross income data from tax returns; all municipalities in this data set had median income of either $US 25 000–49 999 or $US 50 000–74 999⁽³⁸⁾. Participants were also asked to report whether they used food assistance programmes (e.g. Supplemental Nutrition Assistance Program). Sample descriptives are presented in Table 1, and group comparisons for binary demographic variables are presented in Table 2. See Table 3 for group comparisons on age and BMI.

Table 1 Demographics of the current sample of adult bariatric surgery candidates, Central Pennsylvania, USA, December 2017–August 2018, and comparison with nationally representative bariatric surgery demographics

Table 2 Demographic correlates of food security status in the sample of adult bariatric surgery candidates, Central Pennsylvania, USA, December 2017–August 2018

*P < 0·05, **P < 0·001.

Table 3 One-way ANOVA and post hoc least significant difference test group comparisons: age and BMI by food security status in the sample of adult bariatric surgery candidates, Central Pennsylvania, USA, December 2017–August 2018

^a,bMean values in a row with unlike subscript letters were significantly different (P = 0·02).

*P < 0·05, **P < 0·001.

Additional food security items

Based on a literature review of food buying behaviours associated with food insecurity⁽Reference Epstein, Jankowiak and Lin^8, Reference Drewnowski and Specter^15, Reference Liese, Ma and Hutto³⁹⁾, we developed five questions that were included in the same survey as the ten US adult food security survey module items. For the full text of all added questions, see Table 4. These items shared the response format of the USDA items (e.g. ‘never’, ‘sometimes’, ‘often’ true) and assessed the following behaviours: eating fast food to save money, buying unhealthy food rather than healthy food because of the expense, lacking the time or transportation to buy groceries, and buying large amounts of food early in the month and running out. We also asked participants whether they felt that it would be a hardship to afford postsurgical vitamins and supplements.

Table 4 Shopping habits and bariatric-specific items by food security status in the sample of adult bariatric surgery candidates, Central Pennsylvania, USA, December 2017–August 2018

*P < 0·05, **P < 0·001.

BMI

BMI was calculated by dividing weight in kilograms by the square of height in metres (kg/m²). Weight and height were taken by programme staff (registered nurses, registered nutritionists or licensed practical nurses) with participants wearing light clothing and no shoes.

Medical co-morbidities

Research staff reviewed participants’ electronic medical charts for three medical co-morbidities commonly associated with obesity: type 2 diabetes, hypertension/heart disease and sleep apnoea. See Table 2 for the prevalence of each co-morbid diagnosis in our sample.

Participants were 174 bariatric surgery candidates at an academic medical centre and bariatric surgery centre of excellence in Central Pennsylvania who provided complete responses to the full ten-item USDA adult food security survey module. All patients participating in the preoperative programme were eligible for the study, and all were approached during their initial programme visit, when they completed self-report measures, for informed consent for their data to be used for research purposes. To date, 100 % of patients in the programme have consented to the present study. A total of 200 participants were administered the measure; twenty-six (13 %) either did not fill out the measure at all or provided incomplete data to calculate the food security risk score. When data were analysed, only six participants (3·4 %) had completed the presurgical programme and been approved for surgery, and five (2·9 %) had left the programme without being approved. The remaining participants (93·7 %) were still active in the presurgical programme.

Procedures

The USDA adult food security survey module questions, a question about food assistance utilization and five additional items about shopping behaviours/perceptions were embedded in a packet of self-report measures that included the WALI⁽Reference Wadden and Foster³⁴⁾. Data were collected at the outset of the presurgical programme; all patients who apply to enter the presurgical programme complete the packet of self-report measures in which the USDA adult food security survey module items were included, and all patients are approached to obtain their consent for questionnaire and medical chart data to be used in research. The institutional review board of Penn State College of Medicine provided approval for the measures and procedures employed in the present study.

Demographic information including age, gender, educational attainment, race/ethnicity and single parent status were obtained from responses to the demographics and household composition sections of the WALI. Participants’ zip codes and insurance coverage were obtained from electronic medical records. Zip codes were used to search a database maintained by the Center for Rural Pennsylvania, which lists urban and rural municipalities, and the Internal Revenue Service’s Individual Income Tax Statistics database of 2015 income tax return data, by zip code^{(36, 38)}. BMI was calculated from weight and height obtained at the first programme nutritionist visit. For most patients, this visit took place after the initial programme visit where they responded to the self-report survey measures.

Data analysis

Data were analysed using the statistical software package IBM SPSS Statistics version 25.0. To explore the demographic correlates of food insecurity in a bariatric population, we performed χ ² analyses for eight discrete binary variables: (i) White v. person of colour/non-White; (ii) college graduate v. non-graduate; (iii) single parent v. non-parent or co-parent; (iv) male- v. female-identified; (v) urban v. rural zip code; (vi) city centre v. suburban or rural zip code; (vii) median zip code income greater v. less than $US 50 000; and (viii) public v. commercial/employer insurance (commercial/employer-provided insurance v. Medicare, Medicaid). Cramer’s V effect sizes were produced for these analyses. We used one-way ANOVA to compare the food security groups on age and BMI. Because the relationship between food insecurity and obesity appears to differ for men and women, the analyses with BMI were conducted separately for men and women. Continuous relationships between food insecurity score (range 0–10) and age and BMI were computed using non-parametric Spearman’s ρ. To explore food shopping behaviours and perceptions about the affordability of ‘healthy’ food and bariatric supplies, we used χ ² and Cramer’s V.

We used the R package ‘pwr’ to estimate power to detect small and moderate effect sizes with P = 0·05⁽Reference Champely, Ekstrom and Dalgaard⁴⁰⁾. For χ ² with 2 df, there was adequate (85 %) power for medium effects (V = 0·30), but our sample was underpowered (65 %) for small effects (V = 0·20). For one-way ANOVA with 2 numerator df and 171 denominator df, there was adequate power (95 %) for moderate effect sizes (η = 0·09) and small-to-moderate effects (70 % for η = 0·045), but not small effects (36 % for η = 0·01). For correlational analyses there was power for moderate (r = 0·30, 98 %) and small-to-moderate (r = 0·20, 76 %), but not small (r = 0·10, 26 %) effects. Although these analyses were exploratory, we computed Bonferroni-corrected critical P values for each of the three groups of hypothesis tests (e.g. demographic correlates, P = 0·006; clinical correlates, P = 0·01; behavioural correlates, P = 0·01), and P values for all analyses are presented in Tables 2–4. We chose to focus our interpretations on findings that were significant at a more liberal P value of 0·05 and associated with moderate effect sizes.