生物加工
组织工程
再生医学
医学
生物医学工程
心肌细胞
微流控
生物材料
转化研究
机械生物学
从长凳到床边
药物发现
神经科学
细胞
计算生物学
药物输送
生物相容性材料
病理
血管生成
计算机科学
纳米技术
转化医学
干细胞
心肌肥大
体外循环
人类疾病
旁分泌信号
概念证明
天然组织
作者
Yang Liu,Zijie Zhang,Hongbin Li,Lino Prados‐Martin,Huanhong Li,Feng Cheng,Xia Tu,Khoon S. Lim,Wanlu Li,Mian Wang
摘要
The in vitro engineering of vascularized cardiac tissues holds transformative potential for disease modeling, drug screening, and regenerative therapy. However, despite rapid advances in stem cell biology, biomaterials, and biofabrication technologies, the reconstruction of functional, perfusable vasculature within engineered myocardial tissues remains a central and unresolved challenge. In this review, we move beyond a descriptive catalog of available techniques and instead present a process-oriented framework for understanding vascularized cardiac tissue engineering. By systematically analyzing how cellular components, biomaterial design, and biofabrication strategies collectively govern vascular formation, perfusion stability, and myocardial function, we examine self-assembly, mold-casting, 3D bioprinting, and microfluidic approaches, to critically evaluate their respective advantages and trade-offs under cardiac-specific physiological constraints. Finally, application prospects of vascularized cardiac tissues in disease modeling and drug testing are discussed, and current limitations and future directions are proposed to accelerate translational impact. By reframing vascularized cardiac tissue engineering as an integrated manufacturing challenge rather than a collection of isolated technologies, this review aims to provide a coherent conceptual guide for advancing functional human cardiac models.
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