Electrospinning of hybrid polymer has gained widespread interest by taking advantages of the biological property of the natural polymer and the mechanical property of the synthetic polymer. However, the effect of the blend ratio on the above two properties has been less reported despite the importance to balance these two properties in various tissue engineering applications. To this aim, we investigated the electrospun PCL/Gelatin composite fibrous scaffolds with different blend ratios of 4:1, 2:1, 1:1, 1:2, 1:4, respectively. The morphology of the electrospun samples was observed by SEM and the result showed that the fiber diameter distribution became more uniform with the increase of the gelatin content. The mechanical testing results indicated that the 2:1 PCL/Gelatin sample had both the highest tensile strength of 3.7 MPa and the highest elongation rate of about 90%. Surprisingly, the 2:1 PCL/Gelatin sample also showed the best mesenchymal stem cell responses in terms of attachment, spreading, and cytoskeleton organization. Such correlation might be partly due to the fact that the enhanced mechanical property, an integral part of the physical microenvironment, likely played an important role in regulating the cellular functions. Overall, our results indicated that the PCL/Gelatin sample with the blend ratio of 2:1 was a superior candidate for scaffolds for tissue engineering applications.
As a promising biodegradable metallic material, magnesium (Mg) and
its alloys have attracted special attention in the recent decade.
However, challenges still remain due to its high corrosion rate and
insufficient biocompatibility after implantation. In this work, we
prepare a simple and versatile green tea phenol–metal induced
multilayer conversion coating (Mg2+ incorporated epigallocatechin
gallate (EGCG) coating) on magnesium alloys’ (AZ31) substrate
by layer-by-layer (LBL) method. The surface morphology results revealed
that, with the incorporation of Mg2+, the as-formed EGCG/Mg
coating was rich in phenol–Mg complex and presented more homogeneous
and dense morphology, with far less cracks than the pure EGCG coating.
The in vitro degradation rate and corrosion resistance were studied
by electrochemical corrosion tests and monitoring of the changed pH
value and hydrogen evolution, respectively, which revealed that the
corrosion rate was effectively decreased compared to that of bare
AZ31 after it was protected by EGCG/Mg coating. In vitro and ex vivo
thrombogenicity test demonstrated the EGCG/Mg coatings presented an
impressive improvement in decreasing the adhesion and activation of
platelets and erythrocytes, in activated partial thromboplastin time
(APTT), and in antithrombogenicity compared to those of bare AZ31.
Owing to the mild degradation rate, in combination with the biological
function of EGCG, enhanced endothelial cells’ (ECs’)
adhesion and proliferation, suppressed smooth muscle cells’
(SMCs’) adhesion/proliferation, and inhibited cytokine release
were observed on EGCG/Mg coated AZ31 alloy. Besides, the in vivo subcutaneous
embedding experiment suggested that the EGCG/Mg coating performed
more mild tissue response due to the improved corrosion resistance
to the surrounding microenvironment. Moreover, for in vivo abdominal
aorta assay, the EGCG/Mg coated AZ31 wire presented better corrosion
resistance and enhanced re-endothelialization compared to bare AZ31
wire. These results suggested the potential of using green tea polyphenol
induced Mg2+-rich multilayer conversion coating for enhanced
corrosion protection and desired biocompatibility of biodegradable
cardiovascular implants.
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