Israeli scientists from the Technion-Israel Institute of Technology and the Weizmann Institute of Science recently combined one group’s expertise in tissue engineering with the other’s expertise
Cells, whether in the body or in lab-grown tissue, constantly interact with the extracellular matrix (ECM) – a highly complex molecular network that provides structural support for cells. Until recently scientists had assumed that these interactions were primarily biochemical. Researchers have now realized that mechanical interactions – for example, the ability of cells to sense various properties of the ECM and respond – also play significant roles in cell development and function.
The present research was led by doctoral student Shira Landau and Prof. Shulamit Levenberg of the Faculty of Biomedical Engineering at the Technion, and doctoral student Avraham Moriel and Prof. Eran Bouchbinder of the Weizmann Institute’s Chemical and Biological Physics Department, in collaboration with Dr. Ariel Livne, a former postdoctoral researcher in the Department of Molecular Cell Biology at the Weizmann Institute.
One of the scientific challenges to producing artificial biological tissue for transplant is that – like the real thing – it must contain a network of blood vessels to ensure a steady supply of oxygen and nutrients. Highly essential to the implant’s integration and survival is the directional order of this network. In other words, the blood vessels must organize themselves in the same direction.
In Levenberg’s lab, a platform designed to improve tissue generation and self-organization for transplantation has been developed. The technology is based on three-dimensional scaffolds made of polymers. Biological cells that are essential for the development of blood vessels are seeded on these polymeric scaffolds; studies have proved this technology viable and robust.
In a series of studies, she and her team had previously used this platform to examine the mechanical sensitivity of vascular networks. In particular, they noted that mechanical forces have a strong influence on the properties of these networks, especially on the directions in which they grow and develop.
In 2016, Levenberg and Dr. Dekel Rosenfeld, then a doctoral student in her lab, showed how an original stretching system that applied tensile forces to the artificial tissue affected biological processes in the cells, including differentiation, shape, migration and organization in the structures – as well as the geometry of the emerging tissue, its maturity and stability. This earlier study also showed that tensile forces acting on the tissue during development promote the growth of blood vessels with well-defined directionality.
The study led to the controlled generation of stable, rich networks in which the blood vessels have a well-defined directional order
“We then wanted to understand how this process works and how to control it,” says Landau. “Prof. Bouchbinder and his colleagues at the Weizmann Institute of Science developed a theory that explains the effects of mechanical forces on individual cells; together, we expanded this theory to include multicellular tissues.”
In the new study, the researchers considered two types of stretching forces that can affect the development of blood vessels. These two, known as dynamic-cyclic stretching and static stretching, can lead to the emergence of directional order in vascular networks. The researchers discovered that the biophysical mechanism behind each of these two processes is fundamentally different. “One significant challenge we faced was to understand the relationship between the complicated biological experiments and the physical theory,” says Moriel.
The study led to the establishment of a tensile stretching protocol – one that allows the controlled generation of optimal tissues, including stable, rich networks in which the blood vessels have a well-defined directional order.
The researchers believe that these results and insights they provide will advance the possibility of engineering blood vessels in tissue with structures and directionality that may enable their successful transplantation in patients.
Prof. Eran Bouchbinder’s research is supported by the Ben May Center for Chemical Theory and Computation, which he heads; the Edmond de Rothschild Foundations; the Richard F. Goodman Yale/Weizmann Exchange Program; and Paul and Tina Gardner