Seed Oil Ameliorates Bisphenol-A-induced Adipokines Dysfunctions and Dyslipidemia

Overview

Journal Food Sci Nutr

Specialty Biotechnology

Date 2023 Jun 16

PMID 37324904

Authors

Patrick M Aja

Chukwu D Chiadikaobi

Peter C Agu

Boniface A Ale

Onyedika G Ani

Ezebuilo U Ekpono

Hilary A Ogwoni

Joshua N Awoke

Patience N Ogbu

Lucy Aja

Felix E Nwite

Oliver U Ukachi

Obasi U Orji

Peter C Nweke

Chinedu O Egwu

Ejike U Ekpono

Gift O Ewa

Ikechuku O Igwenyi

Deusdedit Tusubira

Christian E Offor

Ekenechukwu K Maduagwuna

Esther U Alum

Daniel E Uti

Amobichukwu Njoku

Victor A Atoki

Chinaza G Awuchi

Affiliations

Soon will be listed here.

Abstract

This study demonstrated the therapeutic potentials of seed oil (CMSO) capable of alleviating BPA-induced dyslipidemia and adipokine dysfunction. In this study, we evaluated the effects of CMSO on adipokine dysfunctions and dyslipidemia in bisphenol-A (BPA)-induced male Wistar rats. Six-week-old 36 albino rats of 100-200 g weight were assigned randomly to six groups, which received varied doses of BPA and/or CMSO. The administration of BPA and CMSO was done at the same time for 42 days by oral intubation. The adipokine levels and lipid profile were measured in adipose tissue and plasma using standard methods. BPA induced significant ( < .05) increases in triglycerides, cholesterol, leptin, LDL-C, and atherogenic and coronary risk indices in adipose tissue and plasma, as well as a decrease in adiponectin and HDL-C levels in Group II animals. BPA administration significantly ( < .05) elevated Leptin levels and reduced adiponectin levels. BPA plus CMSO reduced triglycerides, cholesterol, leptin, LDL-C, and atherogenic and coronary risk indices while increasing adiponectin levels and HDL-C in adipose tissue and plasma ( < .05). The results showed that BPA exposure increased adipose tissue as well as serum levels of the atherogenic index, triglycerides, cholesterol, coronary risk index, LDL-C, leptin, and body weight with decreased adiponectin levels and HDL-C. Treatment with CMSO reduced the toxicities caused by BPA in rats by modulating the body weight, adiponectin/leptin levels, and lipid profiles in serum and adipose tissue. This study has shown that CMSO ameliorates BPA-induced dyslipidemia and adipokine dysfunctions. We suggest for further clinical trial to establish the clinical applications.

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