Patterned vascularization in a directional ice-templated scaffold of decellularized matrix
Li Shen, Xiuyue Song, Yalan Xu, Runhua Tian, Yin Wang, Peifeng Li, Jing Li, Hao Bai, Hai Zhu, Dong Wang
Journal:ENGINEERING IN LIFE SCIENCES
IF:2.68
DOI:10.1002/elsc.202100034
PMID:34690638
Published:2021-07-01
research field:肿瘤学药理学细胞生物学
Abstract
Vascularization is fundamental for large-scale tissue engineering. Most of the current vascularization strategies including microfluidics and three-dimensional (3D) printing aim to precisely fabricate microchannels for individual microvessels. However, few studies have examined the remodeling capacity of the microvessels in the engineered constructs, which is important for transplantation in vivo. Here we present a method for patterning microvessels in a directional ice-templated scaffold of decellularized porcine kidney extracellular matrix. The aligned microchannels made by directional ice templating allowed for fast and efficient cell seeding. The pure decellularized matrix without any fixatives or cross-linkers maximized the potential of tissue remodeling. Dramatical microvascular remodeling happened in the scaffold in 2 weeks, from small primary microvessel segments to long patterned microvessels. The majority of the microvessels were aligned in parallel and interconnected with each other to form a network. This method is compatible with other engineering techniques, such as microfluidics and 3D printing, and multiple cell types can be co-cultured to make complex vascularized tissue and organ models.
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