材料科学
弹性体
热固性聚合物
固化(化学)
3D打印
心肌梗塞
复合材料
环氧树脂
预聚物
生物医学工程
微尺度化学
挤压
机械压缩
软机器人
粘弹性
纳米技术
生物相容性材料
制作
组织工程
自愈水凝胶
细胞外基质
墨水池
人工肌肉
作者
X.R. Zeng,Zhenlong Li,Xiao Tan,Zhishuo Ren,Jingyuan Gao,Zijie Meng,Dichen Li,Jinhai Fan,Mao Mao,Baolin Guo,Jiankang He
标识
DOI:10.1002/adma.202512137
摘要
Poly(glycerol sebacate) (PGS) is promising for engineering flexible cardiac patches for myocardial infarction repair due to its unique elasticity. However, its insulating nature and complex thermal curing process hinder existing 3D printing techniques from producing patches that recapitulate the mechanical, electrical, and anatomical features of native myocardium. Here, a melt-based embedded printing strategy enabling direct, freeform fabrication of thermosetting PGS architectures with in situ thermal curing is proposed. The viscoelastic matrix enables high-fidelity extrusion of PGS prepolymer into microscale filaments while providing temporary support for in situ curing of PGS elastomeric architectures with seamless interface fusion and mechanical stability. This platform further allows direct printing of electro-conductive cardiac patches using carbon nanotube-incorporated PGS that mimic ventricular curvature and mechanical anisotropy. Compared to pure PGS controls, the electro-conductive patches enhance cardiomyocyte maturation in vitro, evidenced by improved sarcomere organization, calcium handling, and electrical synchronization. In vivo, these acellular patches improve mechanical integration with host myocardium, promote vascularization, reduce inflammation, and preserve cardiomyocyte survival, collectively maintaining ejection fraction and attenuating adverse remodeling. This work, therefore, establishes a generalizable manufacturing strategy for printing thermosetting elastomeric constructs with integrated conductivity as acellular, mechanically and electrically functional patches for structural cardiac repair.
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