Enzymatically Active Microgels from Self-Assembling Protein Nanofibrils for Microflow Chemistry

纳米技术 微流控 淀粉样纤维 生物相容性材料 化学 纳米材料 自愈水凝胶 材料科学 淀粉样β 有机化学 医学 生物医学工程 病理 疾病
作者
Xiaoming Zhou,Ulyana Shimanovich,Therese W. Herling,Si Wu,Christopher M. Dobson,Tuomas P. J. Knowles,Sarah Perrett
出处
期刊:ACS Nano [American Chemical Society]
卷期号:9 (6): 5772-5781 被引量:53
标识
DOI:10.1021/acsnano.5b00061
摘要

Amyloid fibrils represent a generic class of protein structure associated with both pathological states and with naturally occurring functional materials. This class of protein nanostructure has recently also emerged as an excellent foundation for sophisticated functional biocompatible materials including scaffolds and carriers for biologically active molecules. Protein-based materials offer the potential advantage that additional functions can be directly incorporated via gene fusion producing a single chimeric polypeptide that will both self-assemble and display the desired activity. To succeed, a chimeric protein system must self-assemble without the need for harsh triggering conditions which would damage the appended functional protein molecule. However, the micrometer to nanoscale patterning and morphological control of protein-based nanomaterials has remained challenging. This study demonstrates a general approach for overcoming these limitations through the microfluidic generation of enzymatically active microgels that are stabilized by amyloid nanofibrils. The use of scaffolds formed from biomaterials that self-assemble under mild conditions enables the formation of catalytic microgels while maintaining the integrity of the encapsulated enzyme. The enzymatically active microgel particles show robust material properties and their porous architecture allows diffusion in and out of reactants and products. In combination with microfluidic droplet trapping approaches, enzymatically active microgels illustrate the potential of self-assembling materials for enzyme immobilization and recycling, and for biological flow-chemistry. These design principles can be adopted to create countless other bioactive amyloid-based materials with diverse functions.
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