一种基于透明质酸的生物相容性大分子双光子引发剂。

A biocompatible macromolecular two-photon initiator based on hyaluronan.

作者信息

Tromayer Maximilian, Gruber Peter, Markovic Marica, Rosspeintner Arnulf, Vauthey Eric, Redl Heinz, Ovsianikov Aleksandr, Liska Robert

机构信息

Institute of Applied Synthetic Chemistry , TU Wien (Technische Universitaet Wien) , Getreidemarkt 9/163/MC , 1060 Vienna , Austria ; Austrian Cluster for Tissue Regeneration , Austria.

Institute of Materials Science and Technology , TU Wien (Technische Universitaet Wien) , Getreidemarkt 9/308 , 1060 Vienna , Austria ; Austrian Cluster for Tissue Regeneration , Austria.

出版信息

Polym Chem. 2017 Jan 14;8(2):451-460. doi: 10.1039/c6py01787h. Epub 2016 Nov 29.

DOI:10.1039/c6py01787h

PMID:28261331

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5310395/

Abstract

The possibility of the direct encapsulation of living cells two-photon induced photopolymerization enables the microfabrication of hydrogel scaffolds with high initial cell loadings and intimate matrix-cell contact. While highly efficient water-soluble two-photon initiators based on benzylidene ketone dyes have been developed, they exhibit considerable cyto- and phototoxicity. To address the problem of photoinitiator migration from the extracellular matrix into the cytosol, a two-photon initiator bound to a polymeric hyaluronan backbone () was synthesized in this work. exhibited a distinct improvement of cytocompatibility compared to a reference two-photon initiator. Basic photophysical investigations were performed to characterize the absorption and fluorescence behavior of . Laser scanning microscopy was used to visualize and confirm the hindered transmembrane migration behavior of . The performance of was tested in two-photon polymerization at exceedingly high printing speeds of 100 mm s producing gelatin-based complex 3D hydrogel scaffolds with a water content of 85%. The photodamage of the structuring process was low and viable MC3T3 cells embedded in the gel were monitored for several days after structuring.

摘要

通过双光子诱导光聚合直接封装活细胞的可能性，使得能够微制造具有高初始细胞负载量和紧密基质-细胞接触的水凝胶支架。虽然已经开发出基于亚苄基酮染料的高效水溶性双光子引发剂，但它们表现出相当大的细胞毒性和光毒性。为了解决光引发剂从细胞外基质迁移到细胞质中的问题，在这项工作中合成了一种与聚合透明质酸主链结合的双光子引发剂（）。与参考双光子引发剂相比，表现出明显改善的细胞相容性。进行了基础光物理研究以表征的吸收和荧光行为。使用激光扫描显微镜来可视化和确认的受阻跨膜迁移行为。在以100 mm s的极高打印速度进行双光子聚合时测试了的性能，制备了含水量为85%的基于明胶的复杂3D水凝胶支架。结构化过程的光损伤较低，并且在结构化后对嵌入凝胶中的活MC3T3细胞进行了数天监测。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/89ef/5310395/7676452b8db7/c6py01787h-f1.jpg

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一种基于透明质酸的生物相容性大分子双光子引发剂。

A biocompatible macromolecular two-photon initiator based on hyaluronan.

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