Background: Obesity can influence on carcinogenesis through alterations in adipokines and subsequent inflammatory changes. This meta-analysis was aimed to comprehensively assess the association between circulating adipokines and risk of obesity-related cancers.
Methods: Pubmed and Embase were searched up to October 2017 for observational studies investigating the relationship between adipokines and cancers. Pooled odds ratio and the corresponding 95% confidence interval was estimated through the meta-analysis using a random-effects model. Findings A total of 93 observational studies (adiponectin = 60, high molecular weight adiponectin = 9, leptin = 39, IL-6 = 16, TNF-α = 10, and resistin = 17) were included. Adiponectin was significantly associated with decreased risk of cancer (pooled OR 0.70, 95% CI 0.60-0.80; I2 = 71.9%; Pheterogeneity <0.01). Leptin was significantly associated with increased risk of cancer (1.26, 1.05-1.51; I2 = 65.7%; Pheterogeneity <0.01). For each 5 μg/ml increase in adiponectin and 5 ng/ml increase in leptin, the pooled OR was 0.88 (0.83-0.93; I2 = 80.2%; Pheterogeneity <0.01) and 1.05 (1.01-1.09; I2 = 67.9%; Pheterogeneity<0.01)), respectively. There was nonlinear dose-response association (Pnonlinearity for adiponectin = 0.01; Pnonlinearity for leptin = 0.003).IL-6 (1.09, 0.94-1.25), TNF- α (1.65, 0.99-2.74), and resistin (1.28, 0.78-2.11) was not associated with risk of cancer. By cancer site and type, highest category of adiponectin was associated with decreased risk of breast (OR 0.74, 0.60-0.91), colorectal (0.74, 0.60-0.91), and endometrial cancer (0.49, 0.34-0.72). Higher leptin was associated with increased risk of endometrial (1.88, 1.24-2.87) and kidney cancer (2.07, 1.51-2.83).
Conclusion: Our study suggests that adiponectin and leptin may play a role in the etiology of cancer.
Keywords: Adipokine; Cancer; Inflammation; Meta-analysis; Obesity.
Copyright © 2019. Published by Elsevier Ltd.