Engineering Conductive Hydrogels with Tissue-like Properties: A 3D Bioprinting and Enzymatic Polymerization Approach

IF 11.1 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY

Small Science Pub Date : 2024-09-01 DOI:10.1002/smsc.202400290

Changbai Li, Sajjad Naeimipour, Fatemeh Rasti Boroojeni, Tobias Abrahamsson, Xenofon Strakosas, Yangpeiqi Yi, Rebecka Rilemark, Caroline Lindholm, Venkata K. Perla, Chiara Musumeci, Yuyang Li, Hanne Biesmans, Marios Savvakis, Eva Olsson, Klas Tybrandt, Mary J. Donahue, Jennifer Y. Gerasimov, Robert Selegård, Magnus Berggren, Daniel Aili, Daniel T. Simon

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Abstract

Hydrogels are promising materials for medical devices interfacing with neural tissues due to their similar mechanical properties. Traditional hydrogel-based bio-interfaces lack sufficient electrical conductivity, relying on low ionic conductivity, which limits signal transduction distance. Conducting polymer hydrogels offer enhanced ionic and electronic conductivities and biocompatibility but often face challenges in processability and require aggressive polymerization methods. Herein, we demonstrate in situ enzymatic polymerization of π-conjugated monomers in a hyaluronan (HA)-based hydrogel bioink to create cell-compatible, electrically conductive hydrogel structures. These structures were fabricated using 3D bioprinting of HA-based bioinks loaded with conjugated monomers, followed by enzymatic polymerization via horseradish peroxidase. This process increased the hydrogels’ stiffness from about 0.6 to 1.5 kPa and modified their electroactivity. The components and polymerization process were well-tolerated by human primary dermal fibroblasts and PC12 cells. This work presents a novel method to fabricate cytocompatible and conductive hydrogels suitable for bioprinting. These hybrid materials combine tissue-like mechanical properties with mixed ionic and electronic conductivity, providing new ways to use electricity to influence cell behavior in a native-like microenvironment.

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具有类组织特性的导电水凝胶工程：三维生物打印和酶促聚合方法

由于水凝胶具有类似的机械特性，因此是与神经组织连接的医疗设备的理想材料。传统的水凝胶生物界面缺乏足够的导电性，依赖于低离子导电性，这限制了信号传导距离。导电聚合物水凝胶具有更高的离子和电子传导性以及生物相容性，但在加工性方面往往面临挑战，并且需要采用激进的聚合方法。在此，我们展示了π-共轭单体在透明质酸（HA）基水凝胶生物墨水中的原位酶聚合，以创建细胞兼容的导电水凝胶结构。这些结构是用三维生物打印技术制造的，先将含有共轭单体的 HA 基生物墨水打印出来，然后通过辣根过氧化物酶进行酶聚合。这一过程将水凝胶的硬度从 0.6 千帕提高到 1.5 千帕，并改变了它们的电活性。人类原代真皮成纤维细胞和 PC12 细胞对这些成分和聚合过程的耐受性良好。这项研究提出了一种新方法来制造适合生物打印的细胞相容性导电水凝胶。这些混合材料将类似组织的机械特性与混合离子和电子导电性结合在一起，为在类似原生的微环境中使用电来影响细胞行为提供了新方法。

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来源期刊

Small Science

CiteScore

14.00

自引率

2.40%

发文量

期刊介绍： Small Science is a premium multidisciplinary open access journal dedicated to publishing impactful research from all areas of nanoscience and nanotechnology. It features interdisciplinary original research and focused review articles on relevant topics. The journal covers design, characterization, mechanism, technology, and application of micro-/nanoscale structures and systems in various fields including physics, chemistry, materials science, engineering, environmental science, life science, biology, and medicine. It welcomes innovative interdisciplinary research and its readership includes professionals from academia and industry in fields such as chemistry, physics, materials science, biology, engineering, and environmental and analytical science. Small Science is indexed and abstracted in CAS, DOAJ, Clarivate Analytics, ProQuest Central, Publicly Available Content Database, Science Database, SCOPUS, and Web of Science.

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