Nerve Guidance Conduits (NGCs) are crucial for reducing trauma during nerve repair, directing axonal growth, and preventing scar tissue formation. In this study, tubular functional NGCs were developed Show more
Nerve Guidance Conduits (NGCs) are crucial for reducing trauma during nerve repair, directing axonal growth, and preventing scar tissue formation. In this study, tubular functional NGCs were developed based on vertically aligned electrospun poly(lactic-co-glycolic acid) (PLGA) nanofibers (vNGC). They were functionalized by conjugating them with bioactive mimetic peptides: a laminin-derived peptide (LD-BP) to promote vascularization, and nerve growth factor (NGF-BP) and brain-derived neurotrophic factor (BDNF-BP) mimetic peptides to support neural differentiation. The vascular differentiation of HUVECs in response to LD-BP, and the neuronal differentiation of PC12 cells in response to NGF-BP and BDNF-BP, were assessed. The results demonstrated that this approach enabled the fabrication of tubular vNGCs with various diameters, and that vertically aligned PLGA nanofibers significantly improved their structural integrity. Furthermore, BP-conjugated vNGCs outperformed non-conjugated control groups in promoting both vascular and neural differentiation. Importantly, peptide conjugation did not induce cytotoxicity or significantly alter the biodegradability of the vNGCs, supporting their suitability for biomedical applications. Finally, bifunctional vNGCs (BiF-vNGCs), conjugated with LD-BP, NGF-BP, and BDNF-BP, were tested in a rat model of sciatic nerve injury. The BiF-vNGCs showed superior performance compared to unmodified vNGC, Control and s-Control groups, effectively promoting vascularization and neural regeneration in vivo, offering a viable alternative to conventional nerve regeneration methods. Show less
The polymorphisms/mutations of genes encoding proteins and enzymes involved in lipoprotein metabolism play important roles in the development of diabetic dyslipidemia. The aim of our study was to inve Show more
The polymorphisms/mutations of genes encoding proteins and enzymes involved in lipoprotein metabolism play important roles in the development of diabetic dyslipidemia. The aim of our study was to investigate the effects of LPL (rs320), LIPC (rs2070895), SCARB1 (rs5888), LCAT (rs2292318), CETP (rs708272), ADIPOQ (rs1501299), RETN (rs3745367), PON1 (rs662), and MNSOD (rs4880) gene polymorphisms on lipid metabolism and diabetic dyslipidemia. This case-control study included 217 patients with diabetic dyslipidemia and 212 healthy age- and gender-matched individuals. Genomic DNA isolation was performed from blood samples, and genotype analysis was performed using melting curve analysis on a LightCycler® 480 Instrument. The chi-square test was used to compare genotype distribution and allele frequencies between the groups. Significant associations were observed between LPL (rs320) (p<0.001), LIPC (rs2070895) (p<0.001), SCARB1 (rs5888) (p<0.001), LCAT (rs2292318) (p<0.001), CETP (rs708272) (p<0.001), ADIPOQ (rs1501299) (p=0.01), RETN (rs3745367) (p<0.001), and MNSOD (rs4880) (p<0.001) polymorphisms and diabetic dyslipidemia. However, no association was observed between PON1 (rs662) polymorphisms and diabetic dyslipidemia (p=0.611). LPL (rs320), LIPC (rs2070895), SCARB1 (rs5888), LCAT (rs2292318), CETP (rs708272), ADIPOQ (rs1501299), RETN (rs3745367), and MNSOD (rs4880) polymorphisms play an important role in basic molecular metabolism in diabetic dyslipidemia. Therefore, these polymorphisms may be used as a predictive marker for diabetic dyslipidemia in high-risk patients. Show less