Porosity dominates over microgel stiffness for promoting chondrogenesis in zwitterionic granular hydrogels†

IF 5.8 3区 医学 Q1 MATERIALS SCIENCE, BIOMATERIALS Biomaterials Science Pub Date : 2024-09-30 DOI:10.1039/D4BM00233D
Maryam Asadikorayem, Lucia G. Brunel, Patrick Weber, Sarah C. Heilshorn and Marcy Zenobi-Wong
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Abstract

Granular hydrogels comprised of jammed, crosslinked microgels offer great potential as biomaterial scaffolds for cell-based therapies, including for cartilage tissue regeneration. As stiffness and porosity of hydrogels affect the phenotype of encapsulated cells and the extent of tissue regeneration, the design of tunable granular hydrogels to control and optimize these parameters is highly desirable. We hypothesized that chondrogenesis could be modulated using a granular hydrogel platform based on biocompatible, zwitterionic materials with independent intra- and inter-microgel crosslinking mechanisms. Microgels are made with mechanical fragmentation of photocrosslinked zwitterionic carboxybetaine acrylamide (CBAA) and sulfobetaine methacrylate (SBMA) hydrogels, and secondarily crosslinked in the presence of cells using horseradish peroxide (HRP) to produce cell-laden granular hydrogels. We varied the intra-microgel crosslinking density to produce microgels with varied stiffnesses (1–3 kPa) and swelling properties. These microgels, when resuspended at the same weight fraction and secondarily crosslinked, resulted in granular hydrogels with distinct porosities (5–40%) due to differing swelling properties. The greatest extent of chondrogenesis was achieved in scaffolds with the highest microgel stiffness and highest porosity. However, when scaffold porosity was kept constant and just microgel stiffness varied, cell phenotype and chondrogenesis were similar across scaffolds. These results indicate the dominant role of granular scaffold porosity on chondrogenesis, whereas microgel stiffness appears to play a relatively minor role. These observations are in contrast to cells encapsulated within conventional bulk hydrogels, where stiffness has been shown to significantly affect chondrocyte response. In summary, we introduce chemically-defined, zwitterionic biomaterials to fabricate versatile granular hydrogels allowing for tunable scaffold porosity and microgel stiffness to study and influence chondrogenesis.

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在促进齐聚物颗粒水凝胶中的软骨生成方面,孔隙率比微凝胶硬度更重要。
由交联微凝胶组成的颗粒状水凝胶作为基于细胞的疗法(包括软骨组织再生)的生物材料支架具有巨大的潜力。由于水凝胶的硬度和孔隙率会影响包裹细胞的表型和组织再生的程度,因此设计可调颗粒水凝胶来控制和优化这些参数是非常有必要的。我们假设,可以使用一种基于生物相容性、具有独立的微凝胶内和微凝胶间交联机制的齐聚物材料的颗粒水凝胶平台来调节软骨生成。微凝胶是通过机械破碎光交联的齐聚物羧基甜菜碱丙烯酰胺(CBAA)和甲基丙烯酸磺基甜菜碱(SBMA)水凝胶制成的,并在细胞存在的情况下使用过氧化辣根(HRP)进行二次交联,以产生含有细胞的颗粒状水凝胶。我们改变了微凝胶内部的交联密度,生产出了具有不同硬度(1-3 kPa)和膨胀特性的微凝胶。当这些微凝胶以相同的重量分数重新悬浮并进行二次交联时,由于不同的膨胀特性,会产生具有不同孔隙率(5-40%)的颗粒状水凝胶。具有最高微凝胶硬度和最高孔隙率的支架可实现最大程度的软骨生成。然而,当支架孔隙率保持不变而仅微凝胶硬度发生变化时,不同支架的细胞表型和软骨生成情况相似。这些结果表明,颗粒状支架孔隙率对软骨形成起主导作用,而微凝胶硬度的作用相对较小。这些观察结果与包裹在传统块状水凝胶中的细胞形成了鲜明对比,在传统块状水凝胶中,硬度会显著影响软骨细胞的反应。总之,我们引入了化学定义的齐聚物生物材料来制造多功能颗粒水凝胶,使支架孔隙率和微凝胶硬度可调,从而研究和影响软骨形成。
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来源期刊
Biomaterials Science
Biomaterials Science MATERIALS SCIENCE, BIOMATERIALS-
CiteScore
11.50
自引率
4.50%
发文量
556
期刊介绍: Biomaterials Science is an international high impact journal exploring the science of biomaterials and their translation towards clinical use. Its scope encompasses new concepts in biomaterials design, studies into the interaction of biomaterials with the body, and the use of materials to answer fundamental biological questions.
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