Dynamic Hydrogel Crosslink Strength Controls Yielding Characteristics and Cell Viability During Injection

bioRxiv - Bioengineering Pub Date : 2024-09-09 DOI:10.1101/2024.08.16.608324

Noah Eckman, Abigail K. Grosskopf, Grace Jiang, Krutarth Kamani, Michelle Huang, Brigitte Schmittlein, Sarah C Heilshorn, Simon Rogers, Eric Appel

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Abstract

Yielding of dynamically crosslinked hydrogels, or transition between a solid-like and liquid-like state, allows facile injection and utility in translational biomedical applications including delivery of therapeutic cells. Unfortunately, characterizing the time-varying nature of the transition has not been attempted, nor are there design rules for understanding the effects of yielding on encapsulated cells. Here, we unveil underlying molecular mechanisms governing the yielding transition of dynamically crosslinked gels currently being researched for use in cell therapy. We demonstrate through nonlinear rheological characterization that the network dynamics of the dynamic hydrogels dictate the speed and character of their yielding transition. Rheological testing of these materials reveals unexpected elastic strain stiffening during yielding, as well as characterizing the rapidity of the yielding transition. A slower yielding speed explains enhanced protection of directly injected cells from shear forces, highlighting the importance of mechanical characterization of all phases of yield-stress biomaterials.

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动态水凝胶交联强度控制注射过程中的屈服特性和细胞活力

动态交联水凝胶的屈服，或固态与液态之间的转变，可以方便地注射并用于转化生物医学应用，包括输送治疗细胞。遗憾的是，目前还没有人尝试描述这种转变的时变性质，也没有设计规则来了解屈服对包裹细胞的影响。在这里，我们揭示了目前用于细胞治疗的动态交联凝胶屈服转变的潜在分子机制。我们通过非线性流变特性分析表明，动态水凝胶的网络动力学决定了其屈服转变的速度和特性。对这些材料的流变学测试显示了屈服过程中意想不到的弹性应变僵化，以及屈服转变速度的特征。较慢的屈服速度能更好地保护直接注射的细胞免受剪切力的影响，这突出说明了屈服应力生物材料所有阶段的机械特性分析的重要性。

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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bioRxiv - Bioengineering

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