Morini Sara, Melitón Barbancho Sandra, Blanes Rodríguez Álvaro, Pla-Palacín Iris, Sainz-Arnal Pilar, Sánchez-Romero Natalia, Falceto Maria Victoria, Mitjana Olga, Romero Antonio, Del Rio-Nechaevsky Marcela, Bengochea Martinez Maria Lourdes, Olmedo Arbizu Emma, Lorente Sara, Lanas Angel, Fernandes-Platzgummer Ana, Baptista Pedro M
Department of Bioengineering and iBB - Institute for Bioengineering and Biosciences, Instituto Superior Técnico, Universidade de Lisboa, Lisbon, Portugal.
Associate Laboratory i4HB - Institute for Health and Bioeconomy at Instituto Superior Técnico, Universidade de Lisboa, Lisbon, Portugal.
Front Bioeng Biotechnol. 2025 Aug 4;13:1625999. doi: 10.3389/fbioe.2025.1625999. eCollection 2025.
The bioengineering of solid tissues and organs to mitigate the organ donor shortage has become a critical area of research in tissue engineering and regenerative medicine, where establishing a functional vascular network is crucial, particularly for complex organs such as the lung, kidney, and liver. This requires the isolation and characterization of various vascular cell types. In this quest, pigs have emerged as the preferred experimental animal model in this field, highlighting the importance of procuring and characterizing porcine vascular cells to create organs with functional vasculature for transplant. However, species-unique differences present challenges. Although some of the processes for isolating, expanding, and characterizing porcine vascular cells have been published, these are less established than those for human cells, requiring in our view and experience, additional research. Furthermore, no reliable and comprehensive models currently exist for testing vascular cell interactions in co-culture .
In this study, we developed effective methods to isolate and further characterize distinct porcine vascular cell types from various sources. We also introduced a straightforward and practical three-dimensional model for testing vascular cell co-culture, organization and function .
This proof-of-concept study demonstrates the potential of our co-culture strategy, employing a decellularized liver extracellular matrix disc scaffold microenvironment to assess cell interactions and vascular potential on a small scale .
通过生物工程构建实体组织和器官以缓解器官供体短缺,已成为组织工程和再生医学领域的一个关键研究方向,其中建立功能性血管网络至关重要,对于肺、肾和肝等复杂器官尤为如此。这需要分离和鉴定各种血管细胞类型。在此过程中,猪已成为该领域首选的实验动物模型,凸显了获取和鉴定猪血管细胞以构建具有功能性脉管系统的可移植器官的重要性。然而,物种独特差异带来了挑战。尽管已发表了一些分离、扩增和鉴定猪血管细胞的方法,但这些方法不如人类细胞的方法成熟,根据我们的观点和经验,还需要进一步研究。此外,目前不存在用于测试共培养中血管细胞相互作用的可靠且全面的模型。
在本研究中,我们开发了有效的方法,从各种来源分离并进一步鉴定不同类型的猪血管细胞。我们还引入了一种简单实用的三维模型,用于测试血管细胞的共培养、组织和功能。
这项概念验证研究证明了我们共培养策略的潜力,该策略采用去细胞化的肝脏细胞外基质圆盘支架微环境,在小尺度上评估细胞相互作用和血管生成潜力。
