Photoreactive elastin-like proteins for use as versatile bioactive materials and surface coatings.

Jordan Raphel, Andreina Parisi-Amon, Sarah Heilshorn
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引用次数: 0

Abstract

Photocrosslinkable, protein-engineered biomaterials combine a rapid, controllable, cytocompatible crosslinking method with a modular design strategy to create a new family of bioactive materials. These materials have a wide range of biomedical applications, including the development of bioactive implant coatings, drug delivery vehicles, and tissue engineering scaffolds. We present the successful functionalization of a bioactive elastin-like protein with photoreactive diazirine moieties. Scalable synthesis is achieved using a standard recombinant protein expression host followed by site-specific modification of lysine residues with a heterobifunctional N-hydroxysuccinimide ester-diazirine crosslinker. The resulting biomaterial is demonstrated to be processable by spin coating, drop casting, soft lithographic patterning, and mold casting to fabricate a variety of two- and three-dimensional photocrosslinked biomaterials with length scales spanning the nanometer to millimeter range. Protein thin films proved to be highly stable over a three-week period. Cell-adhesive functional domains incorporated into the engineered protein materials were shown to remain active post-photo-processing. Human adipose-derived stem cells achieved faster rates of cell adhesion and larger spread areas on thin films of the engineered protein compared to control substrates. The ease and scalability of material production, processing versatility, and modular bioactive functionality make this recombinantly engineered protein an ideal candidate for the development of novel biomaterial coatings, films, and scaffolds.

用作多功能生物活性材料和表面涂层的光活性弹性蛋白。
可光照交联蛋白质工程生物材料将快速、可控、细胞兼容的交联方法与模块化设计策略相结合,创造出一系列新型生物活性材料。这些材料具有广泛的生物医学应用前景,包括开发生物活性植入涂层、药物输送载体和组织工程支架。我们介绍了一种具有生物活性的弹性蛋白与光活性重氮吖啶分子的成功功能化。利用标准重组蛋白表达宿主实现了可扩展的合成,然后用一种异双功能 N-羟基琥珀酰亚胺酯-重氮交联剂对赖氨酸残基进行了特定位点修饰。实验证明,由此产生的生物材料可以通过旋涂、滴注、软光刻制图和铸模等方法进行加工,从而制造出各种二维和三维光交联生物材料,其长度范围从纳米到毫米不等。事实证明,蛋白质薄膜在三周内高度稳定。在光处理后,加入工程蛋白质材料的细胞粘附功能域仍能保持活性。与对照基底相比,人体脂肪干细胞在工程蛋白质薄膜上的细胞粘附率更快,铺展面积更大。材料生产的简易性和可扩展性、加工的多功能性以及模块化生物活性功能使这种重组工程蛋白成为开发新型生物材料涂层、薄膜和支架的理想候选材料。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Journal of Materials Chemistry
Journal of Materials Chemistry 工程技术-材料科学:综合
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1.5 months
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