Development of polypyrrole/collagen/nano-strontium substituted bioactive glass composite for boost sciatic nerve rejuvenation in vivo

Abstract

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A novel nerve conductor made out of polypyrrole (PPY), collagen (Coll) and nano-strontium substituted bioactive glass (n-Sr@BG) (PPY/Coll/n-Sr@BG) was fabricated by electrospinning. SEM demonstrated that the mean distances across of the pores in the nerve channels were under 15 mm and more prominent than 2 mm. These biocomposite films had biomimetic morphology, bigger porosity and moderately higher surface territory than customary nerve channels, consequently not just allowing the transportation of nerve development factor and glucose yet, in addition, hindering the section of lymphatic tissue and fibroblasts. The consistent filaments of the nerve can copy the characteristic ECM, which is valuable to cell bond, cell multiplication, and cell movement. PPY/Coll/n-Sr@BG demonstrated great cell fondness rate, which is useful for neurilemma cell cells bond, relocation and expansion. Its great viability empowers its wellbeing animal models. Sciatic nerve deformity was crossed over an animal model with PPY/Coll/n-Sr@BG in rodents. PPY/Coll and autotransplants were utilized as control gatherings. Contrasted with PPY/Coll and PPY/Coll/n-Sr@BG accomplished fundamentally increasingly viable recovery of sciatic nerve wounds following 24 weeks implantation and the mean distance across of muscle fibres occasions bigger than that in PPY/Coll/n-Sr@BG, and it was nearer to that in control. The rejuvenated nerve filaments in PPY/Coll/n-Sr@BG had an increasingly standard round shape, the thickness of neuro-filaments in c was more than those in PPY/Coll, and was near that in control.

Keywords

• Bioactive glass
• collagen
• in vivo
• polypyrrole
• strontium
• sciatic nerve