Fabrication and characterization of silk/forsterite composites for tissue engineering applications

“…1B. 34 The band at 3437 cm À1 in samples corresponds to -OH stretching vibration. 1B(a)], XRD showed two strong peaks around 2q ¼ 14 and 16.5 representing silk I structure 39 for extracted broin.…”

Fabrication and characterization of silk fibroin/chitosan/Nano γ-alumina composite scaffolds for tissue engineering applications

“…1B. 34 The band at 3437 cm À1 in samples corresponds to -OH stretching vibration. 1B(a)], XRD showed two strong peaks around 2q ¼ 14 and 16.5 representing silk I structure 39 for extracted broin.…”

Fabrication and characterization of silk fibroin/chitosan/Nano γ-alumina composite scaffolds for tissue engineering applications

“…However, the influence of nHAp on SF/GE composite scaffolds is not well understood. In continuation of our recent study on the construction of composite scaffolds [24][25][26] in the present study, we focus on the preparation, characterization, bioactivity, biodegradation, mechanical and in vitro properties of nanocomposite scaffolds SF/GE/nHAp in detail.…”

Preparation, characterization, degradation and biocompatibility of different silk fibroin based composite scaffolds prepared by freeze-drying method for tissue engineering application

“…In another study, Teimouri et al [24] have presented the fabrication of nanocomposite scaffolds consisting of silk fibroin and NF powder by a freeze-drying method. They found that the effects of NF powder contents on the structure of the scaffolds could provide an appropriate composite for bone tissue engineering applications.…”

Synthesis and characterization of nanocrystalline forsterite coated poly(l-lactide-co-β-malic acid) scaffolds for bone tissue engineering applications