Survey description

NHANES is a nationally representative, continuous, cross-sectional survey of non-institutionalised civilian US residents that uses a complex, stratified, multistage probability sampling design. Detailed descriptions of the survey design and operations are available elsewhere^(18,19) . Briefly, data collection occurred in three phases. Phase I included a household interview where socio-demographic and health-related information was collected using a Computer-Assisted Personal Interview system. Phase II occurred approximately 3 weeks following the household interview and included a health examination in the Mobile Examination Center, consisting of anthropometric measurements, physical examination, laboratory tests and an in-person 24-h dietary recall. Lastly, Phase III included a second 24-h dietary recall via telephone approximately 3–10 d after the health examination.

Our analytic sample combined data from the 2011–2012 and 2013–2014 NHANES cycles, the most recent survey years available for dietary supplement use data. During these cycles, Hispanics, non-Hispanic blacks and non-Hispanic Asians were over-sampled. Of the 3068 participants ≥60 years who provided at least one reliable 24-h dietary recall, we excluded participants who were missing body weight or height information (n 52) and those who had BMI (kg/m²) < 18·5 (n 47) due to small sample size. Underweight individuals had different socio-demographic and health-related characteristics than healthy-weight individuals in our preliminary analysis; therefore, they were not combined with healthy-weight individuals. Finally, our analytical sample was 2969 older adults. Sample sizes varied among characteristics of interest because certain variables (e.g. depression and low bone mass) were only collected among a subset of study participants.

Anthropometric, socio-demographic and health-related characteristics

Weight and height were collected by trained health technicians during the health examination in the Mobile Examination Center. BMI was calculated as weight (kg) divided by height squared (m²). Body weight status was classified as follows: healthy weight (BMI 18·5–24·9 kg/m²), overweight (BMI 25–29·9 kg/m²) and obese (BMI ≥ 30 kg/m²)⁽²⁰⁾.

Self-reported race and Hispanic origin were categorised as non-Hispanic white, non-Hispanic black, non-Hispanic Asian, Hispanic and other races as defined in the NHANES protocol. The ‘other’ race group was included in the total estimates but not reported separately. Educational attainment was categorised as less than high school, high school diploma or general equivalency diploma, some college or associate degree, and college graduate or above. The family poverty–income ratio is a ratio of annual family income to the poverty guideline established by the Department of Health and Human Services⁽²¹⁾. We categorised family poverty–income ratio as ≤130, 131–350 and >350 % because family poverty–income ratio ≤ 130 % is used as a cut-off to determine financial eligibility for federal assistance programmes such as the Supplemental Nutrition Assistance Program^{(Reference Oliveira22)}. Supplemental Nutrition Assistance Program participation status was collected at the household level and categorised as participating if the household participated in Supplemental Nutrition Assistance Program in previous 12 months. Older adults were further asked whether they received community/government meals delivered to home (e.g. Meals on Wheels) and whether they ate meals at a senior/community centre, which we combined into one variable, government/community meal participation, and dichotomised as yes or no. Adult food security status was measured using the ten adult-specific items of the U.S. Food Security Survey Module^{(Reference Bickel, Nord and Price23)}. Based on the number of affirmative responses, a dichotomous adult food security variable was constructed as food-secure (<3) or food-insecure (3–10).

A self-reported rating of overall health, asked via a single question in the Current Health Status questionnaire, was used in this analysis; five response categories were collapsed into three categories as either excellent/very good, good or fair/poor^{(Reference Gandhi, Lim and Davis24)}. Self-rated overall oral health condition was also measured by a single item in the Oral Health questionnaire: ‘Overall, how would you rate the health of your teeth and gums?’ Responses were classified in the same manner as self-rated overall general health condition (i.e. excellent/very good, good or fair/poor). Depression was assessed using the Patient Health Questionnaire-9, a nine-item screening instrument that asks the frequency of depression symptoms over the past 2 weeks^{(Reference Kroenke, Spitzer and Williams25)}. A total score is based on the sum of the points in each item; a score of ≥10 represented depression. Participants who had missing data on one or more item were not included in the analysis for depression.

Polypharmacy was defined as taking five or more prescription medications during the 30-d period prior to the household interview^{(Reference Kantor, Rehm and Haas26)}. Impairment in activities of daily living and instrumental activities of daily living was defined as having any form of difficulty with the following activities: getting in or out of bed; using fork, knife and cup; walking between rooms on same floor; dressing; preparing meals; managing money or doing house chores^{(Reference Vasquez, Batsis and Germain27)}. Osteoporosis and low bone mass were determined based on the femoral neck bone mineral density using the WHO criteria: osteoporosis was defined as a T-score ≤ −2·5 and low bone mass as a T-score between −1·0 and −2·5⁽²⁸⁾. Bone mineral density information was only available in 2013–2014. We identified cardio-metabolic risk factors as present based on the criteria for metabolic syndrome components: (1) elevated waist circumference (≥88 cm for women and ≥102 cm for men), (2) elevated blood pressure (systolic ≥130 mm Hg or diastolic ≥85 mmHg or both) or antihypertensive drug treatment, (3) elevated TAG (≥150 mg/dl) or drug treatment for elevated TAG, (4) reduced HDL-cholesterol (<40 mg/dl for men and <50 mg/dl for women) or drug treatment for reduced HDL-cholesterol and (5) elevated fasting glucose (≥100 mg/dl) or drug treatment for elevated glucose^{(Reference Alberti, Eckel and Grundy29)}.

Dietary assessment and estimation of usual intake distribution

The two 24-h recalls collected by trained NHANES interviewers probed participants on their consumption of foods and beverages as well as dietary supplements using the USDA’s Automated Multiple-Pass Method^{(Reference Blanton, Moshfegh and Baer30)}. Daily intakes of nutrients from foods/beverages and dietary supplements were calculated using USDA’s Food and Nutrition Database for Dietary Studies and NHANES Dietary Supplement Database, respectively. We examined selected micronutrients that were identified as ‘under-consumed nutrients’ by the Dietary Guidelines for Americans⁽³¹⁾ and/or that older adults may have increased risk of inadequacy for^{(Reference Russell32,Reference Ervin and Kennedy-Stephenson33)} : Ca (mg), Mg (mg), Zn (mg), vitamin A (retinol activity equivalents; mcg), folate (dietary folate equivalent; mcg), vitamin B₆ (mg), vitamin B₁₂ (mcg), vitamin C (mg), vitamin D (mcg) and vitamin E (α-tocopherol equivalents; mg).

Detailed information on dietary supplement use in the previous 30-d was collected during the household interview. For each dietary supplement reported, participants were asked to show containers to the trained interviewers (i.e. a product inventory) and to report information on the consumption frequency, the duration and the amount taken. If a participant used any dietary supplements during the 30-d period, the participant was classified as a supplement user.

The distributions of usual micronutrient intakes from foods alone and total intakes (i.e. foods and dietary supplements) were estimated using an adaptation of the National Cancer Institute method that produces means and standard errors and percentages of those meeting or exceeding the Dietary Reference Intakes established by the National Academies of Science, Engineering, and Mathematics, including % <estimated average requirement (EAR), % >adequate intake (AI) and % >tolerable upper intake level (UL). Briefly, an adaptation of the National Cancer Institute method used in this analysis can incorporate information about dietary supplements^{(Reference Bailey, Dodd and Gahche34)}; the nutrient intake from dietary supplements was added to the usual nutrient intake from foods to estimate total usual nutrient intake. These macros were previously used in the NHANES analysis by Bailey et al. ^{(Reference Bailey, Akabas and Paxson35)} Covariates in the usual intake models included day of the week of recalled day (Monday–Thursday v. Friday–Sunday), interview sequence of the dietary recall (first v. second) and dietary supplement use (yes v. no). Because vitamins A and E intakes from dietary supplements are not available in NHANES 2011–2014, only usual intakes from foods could be determined. The estimated percentage of individuals with usual intakes below the EAR was used to indicate the percentage of those at risk for nutrient inadequacy (i.e. the EAR cut-point method)⁽³⁶⁾. For nutrients with an AI (e.g. potassium), the percentage of individuals with intakes above the AI was used to estimate the proportion of the group at low risk of inadequacy. The estimated percentage of individuals with intakes exceeding the UL indicated the percentage who are potentially at risk of adverse effects from excess nutrient intake. The UL for folate apply only to synthetic forms obtained from supplements and fortified foods (i.e. folic acid); therefore, % >UL for folic acid was presented. The % >UL for Mg could not be determined as the UL apply only to a pharmacological agent that is not reported separately in NHANES.

The Healthy Eating Index-2015 (HEI-2015) assesses the alignment of diets with the Dietary Guidelines for Americans 2015–2020 and represents overall dietary quality^{(Reference Krebs-Smith, Pannucci and Subar37)}. The thirteen components of the HEI-2015 include total fruits (maximum of five points), whole fruits (5), total vegetables (5), greens and beans (5), whole grains (10), dairy (10), total protein foods (5), seafood and plant proteins (5), fatty acids (10), refined grains (10), Na (10), added sugars (10) and saturated fats (10); details can be found in Krebs-Smith et al. ^{(Reference Krebs-Smith, Pannucci and Subar37)}. Mean HEI-2015 component and total scores as well as mean total energy intakes were estimated using the Markov Chain Monte Carlo approach. The Markov Chain Monte Carlo method is an extension of the National Cancer Institute method that enables estimation of usual intake as well as simultaneous modelling of multiple food groups and nutrients^{(Reference Zhang, Midthune and Guenther38,Reference Reedy, Lerman and Krebs-Smith39)} ; the macros are publicly available⁽⁴⁰⁾. The covariates included in the model were day of the week and interview sequence of the dietary recall.

Nutritional biomarkers

Whole-blood and serum samples were analysed at the CDC’s Laboratory for Nutritional Biomarkers; details on specimen processing and laboratory methods are described elsewhere^(41,42) . Whole-blood folate was measured by microbiologic assay, and serum folate was determined by isotope-dilution high-performance liquid chromatography coupled with tandem MS; erythrocytes folate was then calculated from the whole-blood folate by adjusting for erythrocytes volume and serum folate concentration. The cut-offs for folate deficiency used in the Dietary Reference Intake report for folate are <7 nmol/l for serum folate and <305 nmol/l for erythrocytes folate⁽⁴³⁾ and were also used in this analysis. Serum vitamin B₁₂ concentrations were assessed using electrochemiluminescence immunoassay on Elecsys, and the cut-off for vitamin B₁₂ deficiency was <150 pmol/l as recommended by the Biomarkers of Nutrition for Development expert panel^{(Reference Allen, Miller and de Groot44)}. Methylmalonic acid (MMA) serves as a functional measure of vitamin B₁₂ status and reflects vitamin B₁₂ stores. MMA increases when serum vitamin B₁₂ concentration is low, so >271 nmol/l has been used as the cut-off for vitamin B₁₂ deficiency^{(Reference Allen, Miller and de Groot44)}. Serum concentrations of MMA were analysed by liquid chromatography with tandem MS after derivatisation with butanol. As renal insufficiency independently affects serum MMA^{(Reference Vogiatzoglou, Oulhaj and Smith45)}, we adjusted serum MMA estimates (both mean concentration and prevalence of deficiency) for renal function. Renal function was determined by the estimated glomerular filtration rate (ml/min per 1·73 m²) calculated from the Chronic Kidney Disease Epidemiology Collaboration (CKD-EPI) equation^{(Reference Levey, Stevens and Schmid46,Reference Flamant, Haymann and Vidal-Petiot47)} and the presence of albuminuria, defined by a urinary albumin–creatinine ratio ≥30 mg/g^{(Reference Levey, Coresh and Balk48,49)} . Renal function was categorised as (1) normal renal function: and no albuminuria; (2) CKD stages 1–2: estimated glomerular filtration rate ≥ 60 and single assessment of albuminuria and (3) CKD stages 3–5: estimated glomerular filtration rate < 60 and single assessment of albuminuria. Vitamin D status was represented by serum 25-hydroxyvitamin D [25(OH)D], quantified using ultra-high-performance liquid chromatography-tandem MS. Vitamin D inadequacy was determined at <40 nmol/l as this concentration is consistent with the EAR⁽⁵⁰⁾. As vitamin D is produced in the skin by sunlight exposure, we adjusted vitamin D estimates for the season based on the month when blood was drawn: winter (November–March) and summer (April–October). Lastly, although the cut-offs do not differ between racial and Hispanic origin groups for any selected biomarkers, some physiological differences by race and Hispanic origin may affect biomarker levels^{(Reference Dawson-Hughes51)}; thus, we also presented biomarker estimates adjusted for race and Hispanic origin.

Statistical analysis

Statistical analyses were performed using SAS (version 9.4; SAS Institute, Inc.) and SAS-callable SUDAAN (version 11; RTI International) software programmes to account for the complex survey design by incorporating the NHANES 4-year Day 1 dietary sample weights. Standard errors for socio-demographic and health-related characteristics and nutritional biomarkers were constructed using Taylor series linearisation, and standard errors for HEI-2015 total and component scores and usual nutrient intakes were approximated by Fay’s Modified Balanced Repeated Replication technique using thirty-two sets of replicate weights. For mean concentrations and prevalence of deficiency for MMA and vitamin D, we used logistic regression to estimate predicted marginals, adjusted for renal function (MMA) and season (vitamin D). Satterthwaite-adjusted Wald χ ² tests were conducted to assess differences in the distribution of socio-demographic and health-related characteristics by body weight status within sex at two-sided P-value of <0·05. Differences in percentages and means regarding nutrient biomarkers, usual nutrient intakes and HEI-2015 scores by body weight status within sex were tested using pairwise t tests at a two-sided Bonferroni-adjusted P-value of <0·016 (i.e. 0·05/3 group comparisons).