由微生物细胞制造的坚固的可自我再生的刚性生物材料。
Robust Self-Regeneratable Stiff Living Materials Fabricated from Microbial Cells.
作者信息
Manjula-Basavanna Avinash, Duraj-Thatte Anna M, Joshi Neel S
机构信息
Wyss Institute for Biologically Inspired Engineering, Harvard University, Boston, MA 02115, USA.
出版信息
Adv Funct Mater. 2021 May 10;31(19). doi: 10.1002/adfm.202010784. Epub 2021 Mar 4.
Abstract
Living systems have not only the exemplary capability to fabricate materials (. wood, bone) under ambient conditions but they also consist of living cells that imbue them with properties like growth and self-regeneration. Like a seed that can grow into a sturdy living wood, we wondered: can living cells alone serve as the primary building block to fabricate stiff materials? Here we report the fabrication of stiff living materials (SLMs) produced entirely from microbial cells, without the incorporation of any structural biopolymers (. cellulose, chitin, collagen) or biominerals (. hydroxyapatite, calcium carbonate) that are known to impart stiffness to biological materials. Remarkably, SLMs are also lightweight, strong, resistant to organic solvents and can self-regenerate. This living materials technology can serve as a powerful biomanufacturing platform to design and develop advanced structural and cellular materials in a sustainable manner.
摘要
生命系统不仅具有在环境条件下制造材料(如木材、骨骼)的卓越能力,而且还由活细胞组成,这些活细胞赋予它们生长和自我再生等特性。就像一颗能长成坚固活木的种子一样,我们不禁思考:仅活细胞能否作为制造硬质材料的主要构建单元?在此,我们报告了完全由微生物细胞制造的硬质生物材料(SLMs),其中未掺入任何已知能赋予生物材料硬度的结构生物聚合物(如纤维素、几丁质、胶原蛋白)或生物矿物质(如羟基磷灰石、碳酸钙)。值得注意的是,SLMs还具有轻质、坚固、耐有机溶剂且能自我再生的特点。这种生物材料技术可作为一个强大的生物制造平台,以可持续的方式设计和开发先进的结构和细胞材料。
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