Preparation and evaluation of a silk fibroin–polycaprolactone biodegradable biomimetic tracheal scaffold

In tracheal tissue engineering, the construction of tracheal scaffolds with adequate biodegradable mechanical capacity and biological functions that mimic the structure of a natural trachea is challenging. To explore the feasibility of preparing biomimetic degradable scaffolds with C‐type cartilage...

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Published in:Journal of biomedical materials research. Part B, Applied biomaterials Applied biomaterials, 2022-06, Vol.110 (6), p.1292-1305
Main Authors: Liu, Cai‐Sheng, Feng, Bo‐Wen, He, Shao‐Ru, Liu, Yu‐Mei, Chen, Liang, Chen, Yan‐Ling, Yao, Zhi‐Ye, Jian, Min‐Qiao
Format: Article
Language:English
Subjects:
Animals
Biodegradability
biodegradable
Biodegradation
Biological properties
Biomedical materials
biomimetic structure
Biomimetics
Blood vessels
Cartilage
composite scaffold
Compression
Degradation
Diameters
Feasibility
Fibroins - chemistry
Humans
Hydrolysis
Materials research
Materials science
Mechanical properties
Molds
natural biomaterial
Polycaprolactone
Polyesters
polymeric synthetic material
Pore size
Pore size distribution
porous
pre‐vascularization
Rabbits
Scaffolds
Scanning electron microscopy
Sectioning
Silk
Silk fibroin
Tissue engineering
Tissue Engineering - methods
Tissue Scaffolds - chemistry
Trachea
Trachea - surgery
Vascularization
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Summary:In tracheal tissue engineering, the construction of tracheal scaffolds with adequate biodegradable mechanical capacity and biological functions that mimic the structure of a natural trachea is challenging. To explore the feasibility of preparing biomimetic degradable scaffolds with C‐type cartilage rings and an inner tracheal wall of polycaprolactone and silk fibroin. A mold was made according to the diameter of a rabbit trachea, and a silk fibroin tube and polycaprolactone ring attached to the tube were obtained by solution casting. The ring was fixed to the tube at a specific spacing using electrostatic spinning technology to construct a biomimetic tracheal scaffold; its porous structure was observed by scanning electron microscopy, its degradation properties were determined by in vitro enzymatic hydrolysis and its mechanical properties were obtained by pressure testing. The composite scaffold was transplanted subcutaneously into a rabbit model, and the scaffold was taken at 1, 2, and 4 weeks after surgery for sectioning to observe pre‐vascularization. The Medical Ethics Committee of Guangdong Provincial People's Hospital approved the study. The general view of the biomimetic scaffold: the polycaprolactone ring was fixed firmly on the outer wall of the silk fibroin tube; the two corresponded in size, and they fitted closely. The surface of the polycaprolactone ring was smooth and dense, while the surface of the silk fibroin tube could be seen as a uniform porous structure. Scanning electron microscopy showed that the surface and profile of the fibroin tube had a uniform pore size and distribution. The pores were connected to form a network. In vitro, enzymatic hydrolysis experiments confirmed that the fibroin was degraded easily, with most being degraded at the end of week 1. The degradation slowed at 2, 3, and 4 weeks, while the degradation of polycaprolactone was extremely slow. A compression test showed that the compressive resistance of the silk fibroin–polycaprolactone biomimetic scaffolds was much better than that of the rabbit trachea at close thickness. In the tissue staining experiments, as the material degraded, fibrous tissues and blood vessels grew to replace the material, allowing the scaffold to obtain a blood supply and better mechanical properties. A quantitative analysis of CD31 showed that the results for the vascularization of the scaffold were better at 4 weeks than at 2 weeks following subcutaneous grafting (P 
ISSN:1552-4973
1552-4981
DOI:10.1002/jbm.b.35000