A carbon nanotubes based in situ multifunctional power assist system for restoring failed heart function.

Quanfu Xu, Yuli Yang, Jianwen Hou, Taizhong Chen, Yudong Fei, Qian Wang, Qing Zhou, Wei Li, Jing Ren, Yi-Gang Li
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Abstract

Background: End-stage heart failure is a major risk of mortality. The conductive super-aligned carbon nanotubes sheets (SA-CNTs) has been applied to restore the structure and function of injured myocardium through tissue engineering, and developed as efficient cardiac pacing electrodes. However, the interfacial interaction between SA-CNTs and the surface cells is unclear, and it remains challenge to restore the diminished contraction for a seriously damaged heart.

Results: A concept of a multifunctional power assist system (MPS) capable of multipoint pacing and contraction assisting is proposed. This device is designed to work with the host heart and does not contact blood, thus avoiding long-term anticoagulation required in current therapies. Pacing electrode constructed by SA--CNTs promotes the epithelial-mesenchymal transition and directs the migration of pro-regenerative epicardial cells. Meanwhile, the power assist unit reveals an excellent frequency response to alternating voltage, with natural heart mimicked systolic/diastolic amplitudes. Moreover, this system exhibits an excellent pacing when attached to the surface of a rabbit heart, and presents nice biocompatibility in both in vitro and in vivo evaluation.

Conclusions: This MPS provides a promising non-blood contact strategy to restore in situ the normal blood-pumping function of a failed heart.

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基于碳纳米管的原位多功能动力辅助系统,用于恢复衰竭的心脏功能。
背景:终末期心力衰竭是导致死亡的主要风险。导电超对准碳纳米管片(SA-CNTs)已被应用于通过组织工程恢复受损心肌的结构和功能,并被开发为高效的心脏起搏电极。然而,SA-CNT 与表面细胞之间的界面相互作用尚不清楚,要恢复严重受损心脏减弱的收缩功能仍是一项挑战:结果:我们提出了一个多功能动力辅助系统(MPS)的概念,该系统能够进行多点起搏和收缩辅助。该设备的设计目的是与宿主心脏一起工作,不接触血液,从而避免了当前疗法所需的长期抗凝。由 SA-CNTs 构建的起搏电极可促进上皮-间充质转化,并引导有利于再生的心外膜细胞迁移。同时,该动力辅助装置对交变电压的频率响应极佳,具有模仿自然心脏收缩/舒张的振幅。此外,该系统附着在兔子心脏表面时,起搏效果极佳,在体外和体内评估中均表现出良好的生物相容性:这种 MPS 为在原位恢复衰竭心脏的正常血液泵送功能提供了一种很有前景的非血液接触策略。
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