Study population

Observations were drawn from the Health and Retirement Study (HRS) and Health Care and Nutrition Study (HCNS). The HRS is a biennial panel survey of older Americans funded by the US National Institute on Aging and the US Social Security Administration^{(Reference Hauser and Weir31)}. The HCNS is a mail-out supplement of the HRS measuring food consumption in a subsample of HRS respondents⁽³²⁾. Self-report measures were drawn from the cleaned RAND HRS data file^{(Reference Bugliari, Carroll and Hayden33)} and longitudinal measurement of dried blood spots (DBS) were taken from the 2012 and 2016 HRS. In 2016, a Venous Blood Study (VBS) was conducted on a subsample of HRS respondents and measured a variety of biomarkers not available in the HRS DBS data, with a 65 % final completion rate among eligible cases^{(Reference Crimmins, Faul and Thyagarajan34)}. The HRS protocol includes a spoken confidentiality statement, oral or implied consent at first contact, and written informed consent at each interview. The University of Michigan’s Institutional Review Board approved the HRS and HCNS protocol^{(Reference Weir, Langa and Ofstedal35)}. Response rates for the 2012 HRS and 2013 HCNS were 89·1 %^{(Reference Sonnega, Faul and Ofstedal36)} and 65 %⁽³²⁾, respectively, and the HRS and HCNS were conducted in English or Spanish, based on the preference of the respondent.

The initial dataset included 2766 respondents who had valid cystatin C measurement in 2012. Participants were excluded from analyses if they were under the age of 65 years (n 1259), had missing information on cystatin C in 2016 (n 471), daily energy intakes fell outside the common allowable range of 500 to 3500 kcal/d (2092 to 14644 kj/d) for women and 800 to 4000 kcal/d (3347 to 16736 kj/d) for men (n 56)^{(Reference Willett37)}. Respondents who reported race/ethnicity other than non-Hispanic/Latino White, non-Hispanic/Latino Black, or Hispanic/Latino (n 22) were also excluded. These restrictions resulted in an analytic sample of 958 respondents, which included 63·6 % of the age-eligible sample. Of the 958 respondents included in primary analyses, 733 were also measured in the 2016 HRS VBS. A flow chart depicting participant selection in our study is provided in Supplementary Fig. 1.

Biomarker assessment

DBS were collected during an enhanced face-to-face interview requiring special informed consent, with consent rates of 87 % in 2012^{(Reference Crimmins, Faul and Kim38)} and 86·7 % in 2016^{(Reference Crimmins, Faul and Kim39)}. The DBS samples were assayed for five biomarkers including cystatin C at the University of Washington Department of Medicine Dried Blood Spot Laboratory^{(Reference Crimmins, Faul and Kim38)}. Cystatin C (mg/l) was assayed by ELISA using the BioVendor Human cystatin C ELISA kit (mg/l)^{(Reference Cystatin40)}. We chose to analyse cystatin C in its original metric rather than transform to estimated glomerular filtration rate (eGFR) as the majority of eGFR equations include both cystatin C and serum creatinine^{(Reference Stevens, Coresh and Schmid16)}, and creatinine was not available for analysis in the 2012 HRS DBS.

Other biomarkers available in the 2012 HRS DBS were included as covariates in multivariate analyses. Glycosylated haemoglobin (HbA1c; %) was assayed using a Bio-Rad Laboratories Variant II High-Pressure Liquid Chromatography System⁽⁴¹⁾. Percentages of HbA1c were categorised to represent clinical thresholds of normal (<5·7 %; reference), pre-diabetic (5·7 %–6·4 %), and diabetic (≥ 6·5 %)⁽⁴²⁾. Total cholesterol (mg/dl) was measured using a microtiter plate assay, and the C-reactive protein (ug/ml) assay was performed using ELISA^{(Reference Crimmins, Faul and Kim38)}. Total cholesterol was categorised to represent desirable (<200 mg/dl; reference), borderline high (200–239 mg/dl), and high (≥ 240 mg/dl)⁽⁴³⁾. To standardise biomarker values across differing assays and laboratories, values equivalent to the National Health and Nutrition Examination Survey (NHANES) were created by assuming the distributions of HRS DBS assays were similar to values reported in NHANES. Values for both HRS DBS and NHANES assays were calculated for each percentile, then transformed into the NHANES scale^{(Reference Crimmins, Faul and Kim38)}. The 2012 and 2016 measures of cystatin C were constructed to be equivalent to the 1999–2002 NHANES scale, HbA1c and total cholesterol were compared with NHANES 2013–2016 values, and NHANES 2015–2016 was referenced for C-reactive protein^{(Reference Crimmins, Faul and Kim38)}. The HRS recommends use of the equivalent assays for analytic purposes, and further description of the calculation of equivalent values is available^{(Reference Crimmins, Faul and Kim38)}.

In the 2016 VBS, 50·5 ml of blood was collected in six tubes by a standard phlebotomy service with tube processing done within 48 h of collection. Available assays germane to our study of cystatin C include creatinine (mg/dl), blood protein (g/dl), albumin (g/dl), alanine aminotransferase (u/l), aspartate aminotransferase (u/l), bilirubin (total, mg/dl), blood urea nitrogen (BUN; mg/dl), LDL cholesterol (mg/dl), and TAG (mg/dl). Complete description of laboratory equipment, assays, and quality control procedures are available^{(Reference Crimmins, Faul and Thyagarajan34)}.

Dietary intake

An energy-adjusted version of the AHEI-2010 was examined as a measure of dietary quality. A modified Harvard FFQ^{(32,Reference Willett, Sampson and Stampfer44)} was used to measure dietary intake in the HCNS, and calculated energy and nutrient totals were based on standard nutrient tables⁽⁴⁵⁾. This FFQ was not validated in the HCNS sample, but a validation study of a similar FFQ demonstrated an average energy-adjusted Pearson’s correlation of .46 for comparative validity between nutrient intake on the FFQ and multiple 24-h dietary recall interviews in a sample of older biracial adults^{(Reference Morris, Tangney and Bienias46)}. Respondents used common portion sizes to report average total consumption of each food item over the past 12 months, which were converted to average servings per day. To adjust for extraneous variation in estimates of dietary intake related to total energy intake, we used an energy-adjusted version of the AHEI-2010. Residuals were estimated by regressing the original AHEI-2010 components on total energy intake, producing residuals that reflect the difference between intake of the specific AHEI-2010 component and what would be expected given the respondent’s total energy intake^{(Reference Willett, Howe and Kushi47)}. We also adjusted for energy intake in our primary statistical models to account for potential effects of energy intake in addition to diet composition as represented by the energy-adjusted AHEI-2010 scores. Deciles of residuals for each AHEI-2010 component were calculated with a range from 0 to 9, resulting in a summed energy-adjusted AHEI-2010 score ranging from 0 to 90, with higher scores indicating better dietary quality.

Racial/ethnic variation in the separate components of the AHEI-2010 (non-energy-adjusted), macronutrient density, and micronutrients relevant to CKD were examined to support primary analyses. AHEI-2010 components included daily servings of vegetables, fruit, whole grain, sugar-sweetened beverages, nuts and legumes, red/processed meats, and alcohol, % daily energy from trans-fat, mg/d of long-chain (n-3) fatty acids (EPA + DHA), and % daily energy from PUFA^{(Reference Chiuve, Fung and Rimm30)}. Macronutrient density for daily carbohydrate, protein, and fat intake was calculated as the estimated percent of daily energy content coming from each macronutrient source (% kcal). Intake of specific macronutrients and micronutrients related to health and kidney function were examined to support primary analyses and can be found in Supplementary Table 2. Please note that energy-adjusted AHEI-2010 was used in the primary analyses to produce statistical estimates adjusted for potential measurement error in self reports of dietary intake, while the separate components of non-energy-adjusted AHEI-2010 and macronutrient density were only included in supplementary analyses to provide readers with additional indicators of racial/ethnic variation in dietary intake.

Race/ethnicity, interview language and nativity

Respondents’ race/ethnicity was self-reported. Respondents who reported only a single race (i.e. non-Hispanic/Latino White or non-Hispanic/Latino Black/African American) or Hispanic/Latino ethnicity were identified as that race/ethnicity. When a respondent reported both one of the possible racial categories and Hispanic/Latino ethnicity, the individual was identified as Hispanic/Latino. For brevity, we refer to non-Hispanic/Latino White and non-Hispanic/Latino Black/African American respondents as White or Black respondents throughout the remainder of the manuscript. To further adjust models for covariates related to race/ethnicity, an indicator of whether the core 2012 HRS interview was conducted in Spanish (Spanish/English) was included to adjust for potential language issues related to completion of the HRS and HCNS, and an indicator of whether the respondent was born in the USA (born in the USA/not born in the USA) was included as a measure of nativity.

Covariates

Analyses adjusted for relevant covariates including age, sex (female/male), marital status (partnered or married/single, divorced, or widowed) and retirement status (retired/not retired). Education (<12 years of education, 12 years of education, >12 years of education), household income and household assets accounted for socio-economic resources, and an indicator of food security status was included due to potential associations between dietary quality and food insecurity among older adults^{(Reference Hanson and Connor48)}. Food insecurity was assessed using the six-item short form of the US Household Food Security Survey Module⁽⁴⁹⁾ included in the HCNS, with missing responses to any of the food security items resulting in a missing food security score (food-insecure/food-secure). Covariates representing health behaviours included BMI (underweight (<18·5 kg/m²), normal weight (between 18·5 kg/m² and 25 kg/m²), overweight (between 25 kg/m² and 30 kg/m²), and obese (≥ 30 kg/m²)), vigorous physical activity (participation in activities such as sports, heavy housework, or a job that involves physical labour; no vigorous physical activity, vigorous physical activity <1 time per week, vigorous physical activity >1 time per week) and smoking status (current smoker/non-smoker). Multimorbidity was measured as a sum of seven items asking whether the respondent had been diagnosed with cancer (any malignant tumour excluding skin cancer), lung disease (such as chronic bronchitis or emphysema excluding asthma), heart disease (including myocardial infraction, CHD, angina, congestive heart failure or other heart problems), stroke, psychiatric problems or arthritis, as well as an indicator of depression. Depressive symptoms were identified using the Center for Epidemiological Studies Depression (CES-D) scale adapted in the HRS with responses to the eight depressive symptoms coded in a yes/no format with a cut-off of ≥ 4 indicating high depressive symptomatology^{(Reference Steffick50)}. Respondents with missing information on any of the seven multimorbidity items were coded as missing. Also, an indicator of self-reported diabetes-related kidney trouble or protein in urine was included as a covariate. Blood pressure was measured during in-person interviews in 2012 using an automated device validated against manual measurement^{(Reference Crimmins, Guyer and Langa51,Reference Guyer, Ofstedal and Lessof52)} . Three separate measurements of systolic and diastolic blood pressure were averaged, then classified (normal: <120 systolic and 80 diastolic; elevated: 120–129 systolic and <80 diastolic; stage 1 hypertension: 130–139 systolic or 80–89 diastolic; stage 2 hypertension: ≥ 140 systolic or ≥ 90 diastolic; hypertensive crisis: >180 systolic and/or >120 diastolic; hypotension: ≤ 90 systolic or ≤ 60 diastolic)⁽⁵³⁾. Finally, estimated daily energy intake, measured as average daily total kilocalorie (kcal) intake, was included to adjust for overall energy intake.

Statistical analyses

The primary aim of our secondary observational analysis was to estimate the association between change in cystatin C and dietary quality and identify whether this association varied by race/ethnicity. Change in cystatin C from 2012 to 2016 was modelled by regressing cystatin C measured in 2016 on cystatin C measured in 2012, described as the regressor variable method of analysing change scores^{(Reference Allison54)}, or a first-order autoregressive model. Model 1 estimated the change in cystatin C from 2012 to 2016 adjusted for all independent variables, and model 2 included interaction terms between energy-adjusted AHEI-2010 and race/ethnicity dummy variables, using White older respondents as the reference category. Supplementary models were used to identify whether there were pre-existing racial/ethnic differences in the association between energy-adjusted AHEI-2010 and baseline (2012) cystatin C.

Linear regression models were completed using maximum likelihood estimation with robust standard errors, providing treatment of missing data, adjustment of standard errors for non-normality, and adjustment for correlations between independent variables. Sample weights from the 2012 DBS and indicators of household clustering and geographic stratum from the HRS were used to adjust analyses for differential probabilities of sample selection related to the multi-stage, area-clustered, and stratified sample design of these studies. Mplus 8.4^{(Reference Muthén and Muthén55)} was used to estimate the linear regression models and produce Johnson–Neyman plots to identify regions of the energy-adjusted AHEI-2010 where the association between change in cystatin C and dietary quality significantly varied by race/ethnicity^{(Reference Johnson and Fay56)}. All continuous variables included as covariates were grand-mean-centred. To account for the strong right-skewness of C-reactive protein, household income, and household assets, these measures were log-transformed before inclusion as covariates in statistical models. In the linear regression models, energy-adjusted AHEI-2010 was rescaled by dividing the original energy-adjusted AHEI-2010 by a value of 10 to prevent potential estimation errors related to large variances. Multi-collinearity was not problematic with variance inflation factors for all predictor variables <4^{(Reference Hair, Black and Babin57)}. The α level of statistical significance used in our study was P < 0·05. As our study was a secondary analysis of observational data based on a large sample, formal power analysis was not required based on journal guidance.

SAS 9.4⁽⁵⁸⁾ was used to analyse weighted descriptive data and test bivariate associations adjusted for complex sampling design. Overall differences in continuous measures were compared across racial/ethnic groups using ANOVA, with least squares mean differences used for bivariate follow-up. Differences in categorical measures across racial/ethnic group were tested with the Rao–Scott χ² test. Significant overall χ² tests were partitioned into 2 × 2 contingency tables with Rao–Scott χ² tests used to test significance, with odds ratios (OR) used to identify the direction of association. The significance level for each follow-up test was adjusted using the Bonferroni correction.