Ying Betty Li, Marina Rukhlova, Dongling Zhang, Jordan Nhan, Caroline Sodja, Erin Bedford, Jean-Philippe St-Pierre, Anna Jezierski
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引用次数: 0
摘要
随着组织工程和再生医学的发展,对生物制造复杂血管结构的创新方法的需求与日俱增。我们介绍了一种利用 Aspect Biosystems RX1 技术的单步三维生物打印方法,该方法将交联步骤集成在一个流动聚焦交界处,以生物制造封装在藻酸盐-胶原 I 型水凝胶环中的永生化成年大鼠脑内皮细胞(SV-ARBEC),从而实现稳健的血管生成并形成错综复杂的血管网络。这种单步生物制造工艺包括战略性地逐层组装水凝胶环,以空间可控的方式封装 SV-ARBEC,同时优化介质和营养物质的获取。内皮细胞在环内的空间排列促进了血管生成网络的形成,通过促进细胞在水凝胶基质中的受限沉积,形成组织样结构,从而有组织地发展血管样网络。这种方法提供了一个可适用于多种不同内皮细胞类型的平台,可用于更好地了解三维生物打印构建体中血管生成和血管网络形成的驱动机制,支持开发更复杂的组织和疾病模型,促进药物发现、组织工程和再生应用。
Single-Step 3D Bioprinting of Alginate-Collagen Type I Hydrogel Fiber Rings to Promote Angiogenic Network Formation.
In the advent of tissue engineering and regenerative medicine, the demand for innovative approaches to biofabricate complex vascular structures is increasing. We describe a single-step 3D bioprinting method leveraging Aspect Biosystems RX1 technology, which integrates the crosslinking step at a flow-focusing junction, to biofabricate immortalized adult rat brain endothelial cell (SV-ARBEC)-encapsulated alginate-collagen type I hydrogel rings. This single-step biofabrication process involves the strategic layer-by-layer assembly of hydrogel rings, encapsulating SV-ARBECs in a spatially controlled manner while optimizing access to media and nutrients. The spatial arrangement of the SV-ARBECs within the rings promotes spontaneous angiogenic network formation and the constrained deposition of cells within the hydrogel matrix facilitates tissue-like organized vascular-like network development. This approach provides a platform that can be adapted to many different endothelial cell types and leveraged to better understand the mechanisms driving angiogenesis and vascular-network formation in 3D bioprinted constructs supporting the development of more complex tissue and disease models for advancing drug discovery, tissue engineering, and regenerative medicine applications.
期刊介绍:
Tissue Engineering is the preeminent, biomedical journal advancing the field with cutting-edge research and applications that repair or regenerate portions or whole tissues. This multidisciplinary journal brings together the principles of engineering and life sciences in the creation of artificial tissues and regenerative medicine. Tissue Engineering is divided into three parts, providing a central forum for groundbreaking scientific research and developments of clinical applications from leading experts in the field that will enable the functional replacement of tissues.
Tissue Engineering Methods (Part C) presents innovative tools and assays in scaffold development, stem cells and biologically active molecules to advance the field and to support clinical translation. Part C publishes monthly.