Technion scientists have succeeded in producing an engineered lymph vessel network, paving the way for novel lymphedema treatment
Technion scientists have managed to grow an engineered human lymphatic vessel network. Published in PNAS, the study was led by postdoctoral fellow Dr. Shira Landau and conducted in the laboratory of Professor Shulamit Levenberg of the Technion Faculty of Biomedical Engineering (pictured). The significance of the researchers’ findings lies in a better understanding of lymphatic vessel generation, which could have implications for treatment of lymphedema and the generation of more lifelike tissue flaps.
In the lab, Dr. Shira Landau and her coresearchers grew human lymphatic vessels, together with blood vessels and supporting cells, creating engineered tissue with a functioning vessel network. This was done from inner-lining cells of lymphatic vessels, together with blood vessels respectively, together with support cells, all seeded on sheets of collagen – the main structural protein of the body’s connective tissue. That is, their engineered tissue mimics as closely as possible the body’s natural structures. From this seemingly simple starting point, the group had within a few days a network of vessels that displayed both the arrangement and the functionality expected of them in the body. The engineered tissue was further implanted into a mouse, and successfully integrated with the mouse’s lymph and blood vessels.
This success by the Technion scientists has multiple implications. First, the platform they grew would facilitate the study of lymphatic vessels, their formation, and the factors that affect them. Second, lymphedema, which currently lacks effective treatment, could be in the future treated by implanting a functional network of smaller and larger lymph vessels that would merge with the host’s system, all grown from the patient’s own cells, eliminating fear of rejection. Third, engineered tissue flaps, that is units containing multiple tissues necessary for transplantation, such as muscle, blood vessels, and connective tissue, could be made more lifelike, containing lymph vessels as well. This would improve the implant’s integration and speed up healing.