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New bioink brings 3D-printing of human organs closer to reality

LUND (SE), May 2021 — Researchers at Lund University have designed a new bioink that allows small human-sized airways to be 3D-bioprinted with the help of patient cells for the first time. The 3D-printed constructs are biocompatible and support new blood vessel growth into the transplanted material. This is an important first step towards 3D-printing organs.

The new study has been published in Advanced Materials

Chronic lung diseases are the third leading cause of death worldwide with an EU cost of more than €380 billion annually. For many chronic diseases there is no cure and the only end-stage option for patients is lung transplantation. However, there are not enough donor lungs to meet clinical demand. Therefore, researchers are looking at ways to increase the number of lungs available for transplantation. One approach is fabricating lungs in the lab by combining cells with a bioengineered scaffold. 

“We started small by fabricating small tubes, because this is a feature found in both airways and in the vasculature of the lung. By using our new bioink with stem cells isolated from patient airways, we were able to bioprint small airways which had multiple layers of cells and remained open over time,” explained Darcy Wagner, Ph.D., associate professor and senior author of the study.

The researchers first designed a new bioink (a printable material with cells) for 3D-bioprinting human tissue. The bioink was made by combining two materials: a material derived from seaweed, alginate and extracellular matrix derived from lung tissue.  

This new bioink supports the bioprinted material over several stages of its development toward tissue. They then used the bioink to 3D-bioprint small human airways containing two types of cells found in human airways. However, this bioink can be adapted for any tissue or organ type.   

“These next generation bioinks also support the maturation of the airway stem cells into multiple cell types found in adult human airways, which means that less cell types need to be printed, simplifying the nozzle numbers needed to print tissue made of multiple cell types,” said Dr. Wagner.

She noted that the resolution needs to be improved to 3D-bioprint more distal lung tissue and the air sacs, known as alveoli, that are vital for gas exchange. "We hope that further technological improvements of available 3D printers and further bioink advances will allow for bioprinting at a higher resolution in order to engineer larger tissues which could be used for transplantation in the future. We still have a long way to go.”

The team used a mouse model closely resembling the immunosuppression used in patients undergoing organ transplantation. When transplanted, they found that 3D-printed constructs made from the new bioink were well-tolerated and supported new blood vessels.

“The development of this new bioink is a significant step forward, but it is important to further validate the functionality of the small airways over time and to explore the feasibility of this approach in large animal models,” concluded Martina De Santis, a Ph.D. student in Wagner’s lab and the first author of the study.


Blood vessel infiltration in the 3D bioprinted constructs. Image courtesy of Lund University.


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DOI: 10.1002/adma.202005476