用于软组织工程的具有可变各向异性的弹性蛋白酶敏感弹性支架。

Elastase-sensitive elastomeric scaffolds with variable anisotropy for soft tissue engineering.

作者信息

Guan Jianjun, Fujimoto Kazuro L, Wagner William R

机构信息

McGowan Institute for Regenerative Medicine, 100 Technology Drive, Pittsburgh, Pennsylvania 15219, USA.

出版信息

Pharm Res. 2008 Oct;25(10):2400-12. doi: 10.1007/s11095-008-9628-x. Epub 2008 May 29.

DOI:10.1007/s11095-008-9628-x

PMID:18509596

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2860885/

Abstract

PURPOSE

To develop elastase-sensitive polyurethane scaffolds that would be applicable to the engineering of mechanically active soft tissues.

METHODS

A polyurethane containing an elastase-sensitive peptide sequence was processed into scaffolds by thermally induced phase separation. Processing conditions were manipulated to alter scaffold properties and anisotropy. The scaffold's mechanical properties, degradation, and cytocompatibility using muscle-derived stem cells were characterized. Scaffold in vivo degradation was evaluated by subcutaneous implantation.

RESULTS

When heat transfer was multidirectional, scaffolds had randomly oriented pores. Imposition of a heat transfer gradient resulted in oriented pores. Both scaffolds were flexible and relatively strong with mechanical properties dependent upon fabrication conditions such as solvent type, polymer concentration and quenching temperature. Oriented scaffolds exhibited anisotropic mechanical properties with greater tensile strength in the orientation direction. These scaffolds also supported muscle-derived stem cell growth more effectively than random scaffolds. The scaffolds expressed over 40% weight loss after 56 days in elastase containing buffer. Elastase-sensitive scaffolds were complete degraded after 8 weeks subcutaneous implantation in rats, markedly faster than similar polyurethanes that did not contain the peptide sequence.

CONCLUSION

The elastase-sensitive polyurethane scaffolds showed promise for application in soft tissue engineering where controlling scaffold mechanical properties and pore architecture are desirable.

摘要

目的

开发适用于机械活性软组织工程的弹性蛋白酶敏感型聚氨酯支架。

方法

通过热致相分离将含有弹性蛋白酶敏感肽序列的聚氨酯加工成支架。对加工条件进行调控以改变支架性能和各向异性。对支架的力学性能、降解情况以及使用肌肉来源干细胞的细胞相容性进行了表征。通过皮下植入评估支架在体内的降解情况。

结果

当热传递为多向时，支架具有随机取向的孔。施加热传递梯度会导致孔呈定向排列。两种支架都具有柔韧性且相对坚固，其力学性能取决于诸如溶剂类型、聚合物浓度和淬火温度等制造条件。定向支架表现出各向异性的力学性能，在取向方向上具有更高的拉伸强度。这些支架比随机支架更有效地支持肌肉来源干细胞的生长。在含弹性蛋白酶的缓冲液中56天后，支架重量损失超过40%。弹性蛋白酶敏感型支架在大鼠皮下植入8周后完全降解，明显快于不含该肽序列的类似聚氨酯。

结论

弹性蛋白酶敏感型聚氨酯支架在软组织工程中显示出应用前景，在该领域中控制支架力学性能和孔结构是很有必要的。

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