Platelet-Rich Plasma (PRP) Mitigates Kidney Dysfunction in Alloxan-Induced Diabetic Mice via Modulation of Renal Iron Regulatory Genes.

Kidney dysfunction is a prevalent complication of diabetes mellitus, contributing significantly to diabetes-related morbidity and mortality. We aim to explore whether platelet-rich plasma administration can modulate iron regulation mechanism within the kidney, thereby mitigating renal dysfunction associated with diabetes. Albino mice with an average body weight of 20 ± 5 g were randomly divided into five groups (N = 50; n = 10): Control Group, PRP Group, diabetic group (DG), treated group A (TA), and treated group B (TB). A single intraperitoneal dose of alloxan (160 mg/kg of body weight) was administered to mice in the DG and in both treated groups. Upon confirmation of diabetes, the DG was left untreated, while PRP treatment (0.5 ml/kg of body weight) was administered to the TA and TB groups for two and four weeks, respectively. Histological examinations of kidney tissues revealed notable signs of damage in DG, which were subsequently improved upon PRP treatment. Likewise, PRP treatment restored the changes in liver enzymes, oxidative stress biomarkers and serum electrolytes in both treated groups. Furthermore, there was an observed upregulation of iron regulatory genes, such as Renin, Epo, Hepc, Kim1, and Hfe, in the DG, accompanied by a downregulation of Tfr1 and Fpn; however, Dmt1 and Dcytb1 expression remained unaltered. Treatment with PRP restored the expression of iron regulatory genes in both treated groups. This study concluded that PRP treatment effectively restored the renal histochemistry and the expression of renal iron regulatory genes in an alloxan-induced diabetic mice model.

Effect of heterologous platelet-rich plasma on liver and modulation of glucose metabolism and Wnt signalling pathways in diabetic mice.

BACKGROUND: The current study was designed to highlight the effects of heterologous platelet-rich plasma (PRP) on deteriorated hepatic tissues and impaired glucose metabolism of alloxan-induced diabetic mice. METHODS: 30 male mice were divided into a control (CG), PRP (PG), diabetic (DG), and two treated groups (T1G and T2G). PG was given PRP treatment (0.5 ml/kg body weight) twice a week for four weeks. DG, T1G and T2G were given alloxan (150 mg/kg) to induce diabetes. After confirmation, PRP treatment was given to T1G and T2G for two and four weeks respectively while DG was left untreated. Upon completion of the said experimental period, liver samples were taken for histological and gene expression analyses. RESULTS: The study found that the liver tissue of the DG group showed signs of damage, including hepatocyte ballooning, sinusoid dilatation, and collagen deposition. However, these changes were significantly reduced in both T1G and T2G groups. The expression of several genes related to liver function was also affected, with upregulation of Fbp1 and Pklr, and downregulation of Pck1 in the DG group. PRP treatment restored Fbp1 expression and also increased the expression of glycolytic pathway genes Hk1 and Gck, as well as Wnt signalling pathway genes Wnt2, Wnt4, and Wnt9a in both treated groups. CONCLUSION: Current study revealed that heterologous PRP may partly alleviate high glucose levels in diabetics possibly by mediating glucose metabolism via inhibition of Wnt signalling pathway.