Orthotopic transplantation of the bioengineered lung using a mouse-scale perfusion-based bioreactor and human primary endothelial cells

Whole lung engineering and the transplantation of its products is an ambitious goal and ultimately a viable solution for alleviating the donor-shortage crisis for lung transplants. There are several limitations currently impeding progress in the field with a major obstacle being efficient revascular...

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Bibliographic Details
Published in:Scientific reports 2024-04, Vol.14 (1), p.7040-7040, Article 7040
Main Authors: Tomiyama, Fumiko, Suzuki, Takaya, Watanabe, Tatsuaki, Miyanaga, Jun, Suzuki, Anna, Ito, Takayasu, Murai, Sho, Suzuki, Yuyo, Niikawa, Hiromichi, Oishi, Hisashi, Notsuda, Hirotsugu, Watanabe, Yui, Hirama, Takashi, Onodera, Ken, Togo, Takeo, Noda, Masafumi, Waddell, Thomas K., Karoubi, Golnaz, Okada, Yoshinori
Format: Article
Language:English
Subjects:
631/61/2035
639/705/1041
Alveoli
Animal models
Bioengineering
Bioreactors
Box-counting analysis
Decellularization
Endothelial cells
Hemorrhage
Humanities and Social Sciences
Lung bioengineering
Lung transplantation
multidisciplinary
Perfusion
Perfusion-based Bioreactor
Science
Science (multidisciplinary)
Thorax
Tissue engineering
Transplantation
Transplants & implants
Umbilical cord
Vascular engineering
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Summary:Whole lung engineering and the transplantation of its products is an ambitious goal and ultimately a viable solution for alleviating the donor-shortage crisis for lung transplants. There are several limitations currently impeding progress in the field with a major obstacle being efficient revascularization of decellularized scaffolds, which requires an extremely large number of cells when using larger pre-clinical animal models. Here, we developed a simple but effective experimental pulmonary bioengineering platform by utilizing the lung as a scaffold. Revascularization of pulmonary vasculature using human umbilical cord vein endothelial cells was feasible using a novel in-house developed perfusion-based bioreactor. The endothelial lumens formed in the peripheral alveolar area were confirmed using a transmission electron microscope. The quality of engineered lung vasculature was evaluated using box-counting analysis of histological images. The engineered mouse lungs were successfully transplanted into the orthotopic thoracic cavity. The engineered vasculature in the lung scaffold showed blood perfusion after transplantation without significant hemorrhage. The mouse-based lung bioengineering system can be utilized as an efficient ex-vivo screening platform for lung tissue engineering.
ISSN:2045-2322
2045-2322
DOI:10.1038/s41598-024-57084-0