Assessment of Angiogenesis and Cell Survivability of an Inkjet Bioprinted Biological Implant in an Animal Model

Author:

Oropeza Beu P.,Serna Carlos,Furth Michael E.,Solis Luis H.,Gonzalez Cesar E.,Altamirano Valeria,Alvarado Daisy C.,Castor Jesus A.,Cedeno Jesus A.,Chaparro Vega Dante,Cordova Octavio,Deaguero Isaac G.,Delgado Erwin I.,Garcia Duarte Mario F. Garcia,Gonzalez Favela Mirsa,Leyva Marquez Alba J. Leyva,Loera Emilio S.,Lopez Gisela,Lugo Fernanda,Miramontes Tania G.,Munoz Erik,Rodriguez Paola A.,Subia Leila M.,Zuniga Herrera Arahim A. Zuniga,Boland ThomasORCID

Abstract

The rapidly growing field of tissue engineering hopes to soon address the shortage of transplantable tissues, allowing for precise control and fabrication that could be made for each specific patient. The protocols currently in place to print large-scale tissues have yet to address the main challenge of nutritional deficiencies in the central areas of the engineered tissue, causing necrosis deep within and rendering it ineffective. Bioprinted microvasculature has been proposed to encourage angiogenesis and facilitate the mobility of oxygen and nutrients throughout the engineered tissue. An implant made via an inkjet printing process containing human microvascular endothelial cells was placed in both B17-SCID and NSG-SGM3 animal models to determine the rate of angiogenesis and degree of cell survival. The implantable tissues were made using a combination of alginate and gelatin type B; all implants were printed via previously published procedures using a modified HP inkjet printer. Histopathological results show a dramatic increase in the average microvasculature formation for mice that received the printed constructs within the implant area when compared to the manual and control implants, indicating inkjet bioprinting technology can be effectively used for vascularization of engineered tissues.

Funder

National Institute of General Medical Sciences

National Sleep Foundation

Publisher

MDPI AG

Subject

General Materials Science

Cited by 3 articles. 订阅此论文施引文献 订阅此论文施引文献,注册后可以免费订阅5篇论文的施引文献,订阅后可以查看论文全部施引文献

1. Bioengineering Cell Therapy for Treatment of Peripheral Artery Disease;Arteriosclerosis, Thrombosis, and Vascular Biology;2024-03

2. Inkjet Printing of Pharmaceuticals;Advanced Materials;2023-12-12

3. Additive manufacturing of bioactive glass biomaterials;Methods;2022-12

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