Generation of Multi-scale Vascular Network System Within 3D Hydrogel Using 3D Bio-printing Technology

Generation of Multi-scale Vascular Network System Within 3D Hydrogel Using 3D Bio-printing Technology

Although 3D bio-printing technology has great potential in creating complex tissues with multiple cell types and matrices, maintaining the viability of thick tissue construct for tissue growth and maturation after the printing is challenging due to lack of vascular perfusion. Perfused capillary netw...

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Bibliographic Details
Published in:Cellular and molecular bioengineering Vol. 7; no. 3; pp. 460 - 472
Main Authors: Lee, Vivian K., Lanzi, Alison M., Ngo, Haygan, Yoo, Seung-Schik, Vincent, Peter A., Dai, Guohao
Format: Journal Article
Language:English
Published: Boston Springer US 01-09-2014
Springer Nature B.V
Subjects:
Angiogenesis
Bioengineering
Biological and Medical Physics
Biomaterials
Biomedical engineering
Biomedical Engineering and Bioengineering
Biomedical Engineering/Biotechnology
Biophysics
Capillarity
Cell Biology
Channels
Construction
Engineering
Fluidics
Hydrogels
Networks
Three dimensional
Three dimensional printing
Angiogenesis
Vascular lumen
3D bio-printing
Vasculogenesis
Hydrogel
Capillary
vasculogenesis
vascular lumen
capillary
hydrogel
angiogenesis
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Summary:Although 3D bio-printing technology has great potential in creating complex tissues with multiple cell types and matrices, maintaining the viability of thick tissue construct for tissue growth and maturation after the printing is challenging due to lack of vascular perfusion. Perfused capillary network can be a solution for this issue; however, construction of a complete capillary network at single cell level using the existing technology is nearly impossible due to limitations in time and spatial resolution of the dispensing technology. To address the vascularization issue, we developed a 3D printing method to construct larger (lumen size of ~1 mm) fluidic vascular channels and to create adjacent capillary network through a natural maturation process, thus providing a feasible solution to connect the capillary network to the large perfused vascular channels. In our model, microvascular bed was formed in between two large fluidic vessels, and then connected to the vessels by angiogenic sprouting from the large channel edge. Our bio-printing technology has a great potential in engineering vascularized thick tissues and vascular niches, as the vascular channels are simultaneously created while cells and matrices are printed around the channels in desired 3D patterns.
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ISSN:1865-5025
1865-5033
DOI:10.1007/s12195-014-0340-0