How does the new mix-and-match system differ from other organ-on-a-chip systems?
Loskill: There are a variety of organ-on-a-chip systems on the market. However, essentially no models specifically target adipose tissue research. In recent years, we introduced individual systems, and this new system is an advancement of the former. It enables us to replicate all cellular components of adipose tissue. Aside from the fat cells – the adipocytes-, we also integrate stromal cells and stem cell-like progenitor cells. Immune cells are another key aspect of adipose tissue biology. The mix-and-match system allows us to choose the cell types we want to integrate on the chip and to study the impact the individual cell types have on the function of the tissue as a whole. In doing so, we can assess whether the tissue is still functional when we leave out different cells or explore the changes when certain cells are brought into a disease state.
How can you simulate different aspects of obesity via the chip?
Loskill: Chronic inflammation in adipose tissue is one disease that is linked to obesity. We can recreate this inflammation on a chip by integrating the immune cells and different compositions of immune cells. It’s also possible to set up a patient-specific disease model by harvesting tissue directly from obese patients. By leveraging simulations with the adipose-tissue-on-chip, we can study the obesity phenotype, meaning the appearance of an organism shaped by hereditary predisposition and environmental factors.
What role could chip systems play in the future of medical research?
Loskill: Organ-on-a-chip systems allow us to model more complex human biology structures outside of the human body. Traditionally, one would have to use animal testing, which comes with ethical questions besides differing from human systems. Organ-on-a-chip systems give us the option of conducting experimental research on human models without ethical concerns.
However, it’s important to note that these are still developments, not completed research projects. These systems can not replace animal testing overnight. To get to this point, the process still needs time and extensive development, but we are very optimistic that the chip models could reduce the need for animals in experiments in the future.