高度缠结聚合物网络的增材制造。

Additive manufacturing of highly entangled polymer networks.

作者信息

Dhand Abhishek P, Davidson Matthew D, Zlotnick Hannah M, Kolibaba Thomas J, Killgore Jason P, Burdick Jason A

机构信息

Department of Bioengineering, University of Pennsylvania, Philadelphia, PA 19104, USA.

BioFrontiers Institute & Department of Chemical and Biological Engineering, University of Colorado, Boulder, CO 80303, USA.

出版信息

Science. 2024 Aug 2;385(6708):566-572. doi: 10.1126/science.adn6925. Epub 2024 Aug 1.

DOI:10.1126/science.adn6925

PMID:39088628

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11921614/

Abstract

Incorporation of polymer chain entanglements within a single network can synergistically improve stiffness and toughness, yet attaining such dense entanglements through vat photopolymerization additive manufacturing [e.g., digital light processing (DLP)] remains elusive. We report a facile strategy that combines light and dark polymerization to allow constituent polymer chains to densely entangle as they form within printed structures. This generalizable approach reaches high monomer conversion at room temperature without the need for additional stimuli, such as light or heat after printing, and enables additive manufacturing of highly entangled hydrogels and elastomers that exhibit fourfold- to sevenfold-higher extension energies in comparison to that of traditional DLP. We used this method to print high-resolution and multimaterial structures with features such as spatially programmed adhesion to wet tissues.

摘要

在单个网络中引入聚合物链缠结可以协同提高刚度和韧性，然而，通过光固化3D打印增材制造（例如数字光处理（DLP））实现如此密集的缠结仍然难以实现。我们报告了一种简便的策略，该策略结合了光聚合和暗聚合，使组成聚合物链在打印结构中形成时能够密集缠结。这种通用方法在室温下即可实现高单体转化率，无需额外的刺激，如打印后的光或热，并能够增材制造高度缠结的水凝胶和弹性体，与传统DLP相比，其拉伸能高出四到七倍。我们使用这种方法打印了具有高分辨率和多材料结构，这些结构具有对湿组织的空间编程粘附等特性。

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