Study population

In 2006 and 2008, the MTC was established. This study includes 115 312 female teachers from twelve states in Mexico. Details of the cohort’s characteristics have been previously reported^{(Reference Lajous, Ortiz-Panozo and Monge16)}. Briefly, the MTC had two recruiting phases. The first phase began in 2006 with 27 979 teachers from two states: Jalisco and Veracruz. Participants responded to a baseline questionnaire concerning socio-demographic characteristics, reproductive history, lifestyle (e.g. physical activity and tobacco use) and diet, as well as medical conditions. The second phase began in 2008–2010 when we recruited an additional 87 334 teachers from ten other states and were asked to answer the baseline questionnaire as well. Follow-up questionnaires were distributed every 3–4 years to update information on medical conditions and risk factors (e.g. lifestyle factors). In this study, we used the first follow-up cycle in 2011–2013, with an 83 % response rate.

In the current analysis, we excluded women with prevalent hypertension (n 13 340). We then excluded participants with implausible energy intake (500 > kcal > 3500 (n 9679))^{(Reference Rhee, Sampson and Cho17)} or an incomplete semi-quantitative FFQ (responded to ≤ 50 % of items (n 3598) and/or empty staple section (n 4654)). We also excluded women with myocardial infarction, stroke or cancer (n 2036) and pregnant women at baseline (n 1080) because these conditions may result in changes in diet. Participants who did not respond to the follow-up questionnaire were also excluded (n 13 543). The final analytical sample included 67 383 participants.

The present study was developed and performed according to the Declaration of Helsinki guidelines. The Research, Ethics, and Biosecurity Committee at the National Institute of Public Health (INSP, by its Spanish acronym) evaluated and approved the study protocol and informed consent forms. Additionally, we obtained written informed consent from all women.

Dietary assessment

We collected dietary information with a 140-item semi-quantitative FFQ, previously validated among women in Mexico City^{(Reference Hernandez-Avila, Romieu and Parra18)}. Over a 1-year period, they obtained four 4-d 24-h recalls, corresponding to 16 d of diet recall in batches of 4 d to account for all seasons. Pearson correlation coefficients for total energy, carbohydrate, protein and total fat intakes between the FFQ and 24-h dietary recalls were fairly strong, 0·52, 0·57, 0·32 and 0·63, respectively. Participants reported the average frequency of consumption over the previous year of each food item in a commonly used unit or portion size, which we converted to daily intake values. The consumption frequencies ranged from never, once a month or less, two to three times a month, once a week, two to four times a week, five to six times a week, once a day, two to three times a day, four to five times a day and six or more times a day. In the FFQ, we asked participants the frequency of consumption of half an avocado. We defined a serving of avocado as consumption of half an avocado (defined following the serving size reported by the National Health and Nutrition Examination Survey)^{(Reference Fulgoni, Dreher and Davenport2)}. Nutrient and energy intake per day was calculated by multiplying the nutrient and energy content of the specified pre-defined portion sizes by the reported daily intake value using the USA Department of Agriculture food-composition database⁽¹⁹⁾, which was complemented with a database used in the National Health and Nutrition Survey (ENSANUT, by its Spanish acronym) in Mexico (personal communication).

Hypertension assessment

In both the baseline and follow-up questionnaires, we asked participants to report whether a clinician had made a diagnosis of elevated blood pressure in the previous years, if they received treatment and the year of diagnosis. We defined an incident case of hypertension when participants reported having a diagnosis and undergoing treatment. We evaluated the validity of self-reported hypertension diagnosis in a random subsample of 101 participants who reported having elevated blood pressure, using a structured phone interview in which we confirmed the diagnosis, treatment and year of diagnosis. We confirmed the presence of hypertension in 79 % of participants who had previously reported having a diagnosis of elevated blood pressure and being under treatment (positive predictive value: 79 %; 95 % CI 65, 90 %) (moderately high)^{(Reference Catzin-Kuhlmann, Juarez-Armenta and Ortiz-Panozo20)}.

Covariates

We defined covariates by using self-reported information from the baseline (2006–2008) questionnaire. We used internet access at home and the type of insurance women used for serious conditions (public, private or other) as proxies for socio-economic status^{(Reference Hirko, Lajous and Ortiz-Panozo21)}. We defined ethnicity as whether or not women or her parents spoke an indigenous language. We defined menopause using an algorithm that considered post-menopausal status if they had 1) no menstruation over the past 12 months prior or 2) surgical menopause (reported oophorectomy) or were over 51 years old, given that over 90 % of women in the cohort have reached menopause at age 51. If they stopped menstruating because of a hysterectomy, chemotherapy or radiation, menopausal status was classified as unknown. We defined family history of hypertension as self-reported hypertension diagnosis in parents, siblings or children. We defined type 2 diabetes as self-reported diagnosis undergoing treatment. We categorised smoking status as current, ever, never or unknown status. We categorised physical activity into tertiles of total metabolic equivalent of task based on self-reported multiple-choice frequencies of different activities per week. The correlation between the MTC questionnaire and the International Physical Activity Questionnaire^{(Reference Craig, Marshall and Sjöström22)} was 0·64 for moderate and vigorous physical activity (Pearson correlation coefficients: 0·64 (95% CI: 0·54, 0·97); intraclass correlation coefficient: 0·77 (95% CI: 0·64, 0·86)) (personal communication). We calculated BMI by dividing self-reported weight in kg by squared height in metres and categorised BMI into normal weight (< 25·0 kg/m²), overweight (25·0–30·0 kg/m²), obesity (≥ 30·0 kg/m²) and missing. We categorised multivitamin use during the last year as a yes/no question. Finally, we calculated total energy intake and assessed diet quality with the Healthy Eating Index 2015 (HEI-2015). Details on the development, scoring and components can be accessed in the National Institutes of Health’s research resources⁽²³⁾. Briefly, a score for each component of the HEI-2015 is calculated based on the frequency of consumption of the item or items in that component in the FFQ. The HEI-2015 contains thirteen components and sums 100 points (maximum score). Each component is scored on a density basis out of 1000 calories, except fatty acids, which is the ratio of unsaturated to SFA. We took avocado out from the calculation to get a HEI-2015 score without avocado. The validity of the HEI-2015 score has been discussed elsewhere, a study which included Hispanics^{(Reference Reedy, Lerman and Krebs-Smith24)}.

Statistical analyses

We summarised continuous and categorical variables as means ± standard deviation (sd) or median and interquartile range and percentages, respectively. We categorised responses to avocado consumption (servings) into never or ≤ 1 per month, 2–3 times per month, once a week, 2–4 times per week and 5 or more times per week. We used the lowest (never or ≤ 1 per month) category as a reference.

To calculate each participant’s person-time, we used the date of response in the baseline questionnaire and either the date of diagnosis of hypertension or the response date from the last follow-up questionnaire. We imputed the date of diagnosis to the midpoint between the date of response to the last questionnaire when they reported being free of hypertension and the date of response to the last follow-up questionnaire where they self-reported a hypertension diagnosis. We estimated age-adjusted and multivariable-adjusted incidence rate ratios (IRR) and 95 % CI using Poisson regression models with an offset equal to the natural logarithm of person-time^{(Reference Pedan25)}. To test for linear trend using the Wald test, we created a continuous variable equal to the value of each category of avocado consumption and the median value for the 5+/day category.

We selected confounders using previous knowledge on biological mechanisms and risk factors for avocado consumption and hypertension^{(Reference Hernán, Hernández-Díaz and Werler26)}. In the multivariable models we adjusted first for age (continuous); then for internet access (%), insurance for serious conditions (public, private, other), ethnicity (%), menopausal status (premenopausal, postmenopausal and unknown), family history of hypertension (%), smoking status (current, ever, never, unknown), physical activity (tertiles). We then added BMI status (normal, overweight, obesity, unknown) because we considered BMI a strong confounder of the association since BMI status could influence how much avocado a person consumes and BMI is a risk factor for hypertension. Afterwards, we added multivitamin supplementation (%) to control for a potential threshold effect of micronutrients (e.g. potassium and Mg), total energy intake (continuous) and the HEI-2015 score (continuous). We did not adjust for type 2 diabetes diagnosis in our main model because this disease can be both, a confounder and a mediator in the causal pathway. However, we added this covariate in a separate model. For missing variables on BMI and smoking status, we created a missing indicator category (8·7 % and 3·0 %, respectively)^{(Reference Toh, García Rodríguez and Hernán27)}. We also calculated the E-value to estimate the minimum strength of association that an unmeasured confounder would need to have with both, avocado consumption and hypertension, conditional on the measured covariates, to fully explain away the observed association^{(Reference Mathur, Ding and Riddell28,Reference VanderWeele and Ding29)} .

We also conducted several sensitivity analyses. First, we used a broader definition of the outcome, where we defined an incident hypertension case as having responded to any one of the three questions on high blood pressure described previously. This analysis was carried out considering that some participants could have been diagnosed but are either not treated^{(Reference González-Villalpando, Stern and Haffner30)}, not aware of taking medication or omitted certain questions on the questionnaire. Second, we ran two different analyses as another way to assess confounding (unmeasured and residual). (1) We ran the analysis among women without type 2 diabetes, since it may be a confounder in the association between avocado consumption and incident hypertension^{(Reference Colussi, Da Porto and Cavarape31)}. (2) We explored whether the association between avocado consumption and incident hypertension was due to avocado being a marker of a healthy diet and/or a healthy lifestyle. Thus, we ran the analysis excluding participants with the highest tertile of a ‘healthy lifestyle score’, composed of four proxies for a healthy lifestyle. The components were physical activity, diet quality, weight and smoking status. For each component, participants would score a point if they were normal weight (< 25 kg/m²), never smokers, in the highest tertile of physical activity and/or in the highest tertile of the HEI-2015 score. The total ‘healthy lifestyle score’ ranged from 0 to 4. We assumed that participants had a ‘true’ healthy lifestyle if they scored in the highest tertile of this score. However, since type 2 diabetes, BMI and a healthy diet and/or lifestyle could be mediators in the causal pathway between avocado consumption and hypertension, stratifying analyses by these variables could have induced selection bias. We also stratified for a ‘healthy diet’, defined as those who scored in the highest tertile of the HEI-2015 score. Finally, we ran another analysis using a food substitution model (log(h(t; x)) = log(h ₀(t)) + δ₁food_1(avocado) + δ₂food_{2(added fats)} + δ₃food_{3(other foods)} + δ₄total energy intake + α₃covariates) instead of a non-specified food substitution model (log(h(t; x)) = log(h ₀(t)) + α₁food_1(avocado) + α₂total energy intake + α₃covariates)^{(Reference Ibsen, Laursen and Würtz32)}. We modelled the substitution of 161 kcal of added fats (cream, margarine or butter) for the same amount of avocado (161 kcal = ½ avocado), adjusting only for those foods which could be confounders of the substitution of avocado and added fats (red meat, processed meats, fast foods and fruits and vegetables). This model was adjusted for age, internet access, insurance for serious conditions, ethnicity, menopausal status, family history of hypertension, smoking status, physical activity (tertiles), BMI, energy intake and multivitamin intake.

We used the Statistical Analysis System statistical software package version 9·4 (SAS Institute Inc.) to perform all analyses.