Plant-based diets and risk of type 2 diabetes: systematic review and dose–response meta-analysis

We followed the Preferred Reporting Items for Systematic Reviews and Meta-Analysis 2020 guidance⁽³²⁾ to perform this review, and we registered the systematic review in PROSPERO database (no. CRD42022382022).

We performed online literature searches in PubMed/MEDLINE and EMBASE databases up until 10 July 2025, by using the MeSH terms and keywords related to ‘plant-based diet’, ‘vegetarian diet’, ‘vegan diet’ and ‘type 2 diabetes’. Details about the search terms are reported in online Supplementary Table S1↗. We also used citation chasing techniques to identify relevant studies through screening of reference lists as well as backwards and forward citations of included studies⁽³³⁾. We imported retrieved articles into Rayyan online application and duplicates were removed. Two authors (AM and TF) independently screened publication titles and abstracts and evaluated full-text publications for inclusion in the review. In case of disagreement, both authors performed a second review of the full text to determine eligibility for inclusion through a consensus-based discussion. If the two authors still disagreed, a third author (MV) was sought to resolve disagreement.

We defined the following study inclusion criteria according to the Population, Exposure, Comparison, Outcome and Study Design (PECOS) statement: (1) adult population (not pregnant women); (2) adherence to a plant-based, vegetarian or vegan diet; (3) subjects with low adherence to investigated dietary patterns; (4) assessment of T2D risk in relationship to plant-based, vegetarian or vegan diet adherence (outcome assessment may be based on clinical data related to the diagnosis or treatment of T2D, or on biochemical data after blood sampling) and (5) observational study design (cohort, cross-sectional or case–control). We did not apply any language restrictions. When necessary, we also contacted authors of included studies to retrieve additional information for data analysis when not published in the report.

We assessed the quality of included studies using the Risk of Bias for non-randomised studies of exposures tool⁽³⁴⁾. Seven domains were considered including: (1) bias due to confounding; (2) bias in selecting participants in the study; (3) bias in exposure classification; (4) bias due to departures from intended exposures; (5) bias due to missing data; (6) bias in outcome measurement and (7) bias in the selection of reported results. Online Supplementary Table S2↗ reports criteria for risk of bias evaluation. Two authors (AM and TF) performed the assessment, with any disagreements resolved by consultation with a third author (MV).

We (AM and SP) extracted the following data from eligible studies using a standardised spreadsheet in Excel software: (1) study type; (2) first author name; (3) publication year; (3) country; (4) period of observation; (5) follow-up period; (6) type of exposure assessment; (5) outcome of interest; (6) estimation unit of adherence; (7) exposure categories; (8) dose for each category of exposure (for studies that used dietary indices); (8) number of cases with T2D; (9) sample size at baseline, overall and divided by exposure category; age (10) and sex (11) of participants at baseline; (12) risk estimates, either hazard ratio (HR), odds ratio (OR), and risk ratio (RR), with their 95 % confidence interval (CI) and covariates from the most adjusted multivariable model. For studies that used dietary indices, we used the risk estimate that compared the highest with the lowest percentiles, which represent the best (highest percentile) and poorest (lowest percentile) adherence to the plant-based dietary pattern. For studies that compared an a priori defined dietary pattern, we considered the study risk estimates comparing diets that are most restrictive of animal-based foods (e.g. vegan and vegetarian diets) with the least restrictive, such as omnivorous diet.

First, we performed a forest-plot meta-analysis comparing vegetarian pattern/plant-based diet v. non-vegetarian dietary pattern and risk of T2D, using the non-vegetarian pattern as reference and comparing the highest v. the lowest category of exposure.

We then assessed the shape of the association between plant-based diet exposure and risk of T2D using a dose–response meta-analysis based on the one-stage approach^(35,36). In this approach, we used the mean/median levels or the midpoint of each exposure category, depending on data availability, and if the highest and the lowest exposure boundaries were ‘open’, a 20 % higher or lower value from the closest cutpoint^(37–39). We carried out this analysis by using a restricted cubic spline with three knots at fixed cutpoints (tenth, fiftieth and ninetieth percentiles) and a restricted maximum likelihood random effects model^(40,41). We used Stata-SE software (v19.0, Stata Corp., 2025) for all data analyses, specifically the ‘meta’, ‘mkspline’ and ‘drmeta’ routines.

We stratified all analyses using definitions of plant-based diets. Specifically, for vegetarian diets, analyses were stratified by type of vegetarianism (e.g. vegan and lacto-ovo-vegetarian), while for studies that defined adherence to plant-based dietary patterns using plant-based dietary indices, the results were divided by index type, that is, overall PDI, hPDI and uPDI. Specifically, hPDI emphasises consumption of vegetables, legumes and whole grains, while uPDI emphasises the intake of refined grains, sweets and sugar-sweetened beverages of plant origin⁽¹⁴⁾. Whenever possible, we also stratified the data by geographic region (namely Asian and Western countries, to account for differences in ethnic origin). We eventually performed sensitivity analyses by restricting the assessment to studies with cohort design only, with a duration of follow up equal to or above 10 years and excluding studies at high risk of bias.

We assessed heterogeneity among included studies using the τ², I² and H² statistics in the forest plots⁽⁴²⁾ when comparing vegetarian/non-vegetarian patterns. For the dose–response analysis, we assessed the influence of variation across included studies with the graphical overlay of study-specific trends using predicted curves in the dose–response analysis risk^(43,44). Finally, we assessed publication bias with the presence of small-study effects through graphical presentation in funnel plots and Egger’s test⁽⁴⁵⁾, and the trim-and-fill analysis⁽⁴⁶⁾.

The Preferred Reporting Items for Systematic Reviews and Meta-Analysis flow chart of the literature search is presented in Figure 1. We retrieved 1363 articles after removal of duplicates, and we excluded 1289 articles after title and abstract screening. After full-text assessment of the remaining seventy-four articles, we further excluded forty-three articles because the outcome was not T2D (n 9); the exposure assessment did not include plant-based diet (n 9); the study design was based on a Mendelian randomisation method (n 2); some data were missing (n 3); the publication type (n 15) was wrong or there was a population overlap with some of the studies included (n 5). Two articles were added through backwards citation searching of included studies.

Summary characteristics of the thirty-three articles eventually included in this review are reported in Table 1^(47–79). One article⁽⁷⁰⁾ included three studies (Nurses’ Health Study, Nurses’ Health Study 2 and Health Professionals Follow-Up Study) and another⁽⁶¹⁾ included two cohorts (Centre for Cardiometabolic Risk Reduction in South-Asia and National Health and Nutrition Examination Survey), resulting in a total of thirty-six included studies. Overall, studies were published between 1999 and 2025, with most from Asia (n 14), followed by North America (n 13), Europe (n 7) and Central America (n 2). Of the thirty-six studies included in our analysis, nineteen are cohort^{(49,50,52,53,55–57,62–65,67,69,70,72,73,75)} and seventeen cross-sectional^{(47,48,51,54,58–61,66,68,71,74,76–79)}. Regarding prospective studies, the duration of follow-up ranged from 2 to more than 20 years.

Sixteen studies defined adherence to plant-based dietary patterns using a plant-based dietary index, fifteen of them calculated an overall PDI, eleven studies a hPDI and seven studies an uPDI. The remaining twenty studies defined adherence to vegetarian or vegan diets using a priori-defined dietary patterns. Eight studies evaluated specific vegetarian patterns, including vegan, lacto-ovo vegetarian, pesco-vegetarian and semi-vegetarian, while twelve did not stratify the analyses by type of vegetarianism. Specifically, in three studies, the term ‘vegetarian’ referred to a single group of participants adhering to any plant-based dietary patterns, namely vegan, lacto-ovo vegetarian, lacto-vegetarian and ovo-vegetarian⁽⁵⁵⁾; and vegan, lacto-ovo vegetarian, lacto-vegetarian, pesco-vegetarian and semi-vegetarian in Centre for Cardiometabolic Risk Reduction in South-Asia and National Health and Nutrition Examination Survey cohorts⁽⁶¹⁾. In nine studies, no definition for vegetarian diet was reported.

Among the studies that assessed adherence using a plant-based dietary index, all but two provided data suitable for dose–response meta-analysis. In one study, exposure doses based on dietary habits assessment were not available⁽⁷⁶⁾; another study did not provide the estimated risk of T2D for each exposure category⁽⁵³⁾.

Results of study quality assessment by risk of bias are reported in online Supplementary Table S3↗. Overall, fourteen of the included studies were judged at high risk of bias^{(47,51,55,58,59,61,63,66,68,71,73–75,77)}, while five studies were at overall moderate risk of bias^{(48,52,54,70,78)}. Concerning individual domains, six studies were considered at moderate risk of bias due to lack of control for BMI^{(58,60,61,66,77,78)} and additional two were considered at high risk of bias due to confounding, since they did not implement any multivariable model but reported crude data^(51,71). Seven studies were considered at moderate risk of selection bias, because participant selection was linked to a predominantly plant-based diet^{(51,54,55,58,73–75)}. Regarding information bias, the risk of exposure misclassification was moderate for five studies^{(47,48,51,61,78)} because details about questionnaire validation were not specified, while it was high for five studies^{(55,59,66,68,77)} in which vegetarian status was self-reported. As regards bias in departure from intended exposure, six studies were at high risk of bias because exposure levels were not reported^{(51,55,59,66,68,77)}. Two studies excluded participants due to missing data ≥ 20 %^(63,74). Outcome identification was based on self-report in six studies^{(52,58,64,70,73,74)}, and additional five studies outcome assessment was based on self-report only without external validation, or was not based on international guidelines^{(47,59,66,68,75)}, thus they were considered at high risk of bias. Overall, 58 % of studies were considered at moderate/high risk of bias. Considering high risk of bias only and division by study design, the proportion was much lower in cohort than cross-sectional studies, with respectively 21 % (4/19) and 62 % (10/16).

Forest plot analyses comparing the highest v. the lowest adherence to vegetarian/plant-based dietary patterns (Figure 2) showed a negative association with T2D independently from the type of pattern, with RR of 0·65 (95 % CI 0·42, 1·00, four studies, τ² = 0·16, I² = 81·57 %), 0·68 (95 % CI 0·57, 0·82, seventeen studies, τ² = 0·12, I² = 88·91 %), 0·84 (95 % CI 0·63, 1·13, three studies, τ² = 0·05, I² = 76·79 %) and 0·78 (95 % CI 0·57, 1·07, five studies, τ² = 0·10, I² = 74·74 %) for vegan, lacto-ovo-vegetarian, pesco-vegetarian and semi-vegetarian, respectively. For studies that defined adherence using a PDI (Figure 3), RR associated comparing extreme categories of intake was 0·76 (95 % CI 0·66, 0·87, fifteen studies, τ² = 0·06, I² = 92·28 %). When hPDI and uPDI are considered, RR were 0·75 (95 % 0·69, 0·82, eleven studies, τ² = 0·01, I² = 72·65 %) and 1·27 (95 % CI 1·00, 1·60, seven studies, τ² = 0·07, I² = 91·30 %), respectively.

In the dose–response meta-analysis, we were able to include results from fourteen studies, assessing adherence to plant-based indices reporting scores for each category of exposure, with higher scores indicating greater adherence. Overall, the analysis based on the assessment of overall PDI available in thirteen studies^{(49,52,56,57,60,62,64,65,69,70,79)} showed an inverse and almost linear relationship with T2D risk (Figure 4). Similarly, the analysis assessing the hPDI, based on eleven studies^{(49,52,57,62,64,65,69,70,72)}, indicated a substantially linear, negative association with T2D risk for increasing adherence to hPDI (Figure 4). Conversely, the meta-analysis of results of the seven studies^{(49,57,62,64,65,69,72)} measuring adherence to uPDI showed a linear positive association with T2D risk for increasing levels of uPDI adherence (Figure 4).

Stratified analyses by region showed substantially similar results in Western populations to those obtained from the overall analysis, when the highest v. the lowest adherence to vegetarian dietary patterns were compared. In Asian populations, only adherence to lacto-ovo-vegetarian diet showed a negative association with T2D risk, although only one study for each of the other dietary patterns (i.e. vegan, pesco-vegetarian and semi-vegetarian) was available for the analysis (online Supplementary Figures S1↗–S2↗). Stratified analysis by region considering the highest v. the lowest adherence to plant-based dietary patterns showed similar results in both Western and Asian populations, with lower T2D risk for PDI and hPDI, and higher risk of uPDI, although the number of studies carried out in Asia is more limited (online Supplementary Figures S3↗–S4↗).

Similarly, a negative linear association between increasing PDI and hPDI adherence and T2D risk emerged both in Western and in Asian populations, although levels of adherence were generally higher in the former. Consistent with the forest-plot analysis, uPDI showed a positive association with T2D risk in Western populations, while for Asia, two studies were available and the analysis could not be performed (online Supplementary Figure S5↗).

The analysis limited to cohort studies confirmed the overall RR comparing the highest v. the lowest adherence to vegetarian dietary patterns (online Supplementary Figure S6↗) as well as using plant-based dietary patterns (PDI, hPDI and uPDI), in both the forest plot (online Supplementary Figure S7↗) and in the dose–response meta-analysis (online Supplementary Figure S8↗).

Further restricting the analysis to cohort studies with more than 10 years of follow-up, we found a negative association between lacto-ovo-vegetarian (two studies) and semi-vegetarian diets (one study) and T2D risk, while one study for vegan diet showed null association (online Supplementary Figure S9↗). No studies were available for pesco-vegetarian diets with more than 10 years of follow-up. As regards plant-based patterns, results were almost identical to those in the main analysis in both the forest plot (online Supplementary Figure S10↗) and in the dose–response meta-analysis (online Supplementary Figure S11↗), although based on a lower number of studies.

Exclusion of the fifteen studies deemed at high risk of bias could allow an analysis only for lacto-ovo-vegetarian diet, showing a negative association with T2D risk, as no studies remained available for pesco-vegetarian and semi-vegetarian diets, and the one study on vegan diet showed null association (online Supplementary Figure S12↗). Finally, studies that assessed adherence using PDI, hPDI and uPDI showed almost identical results to those in the overall analysis, in both the forest plot (online Supplementary Figure S13↗) and in the dose–response meta-analysis (online Supplementary Figure S14↗), since no studies were judged at high risk of bias.

Funnel plots based on the different exposure assessment methods did not indicate risk of small-study effects, as also shown by results of Egger’s test (online Supplementary Figure S15↗), with no studies added in the trim-and-fill analysis. Finally, study-specific curves showed substantial homogeneous trends for all studies included in dose–response analyses except for one study in the overall PDI, showing a much steeper decrease in risk (online Supplementary Figure S16↗).