Systematic Evaluation of Human Explant Model Systems Engineering

Summary

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Description

Personalized therapy is still one of the great goals of oncology. In view of the success of checkpoint inhibitor therapies in selected solid tumors, the question remains why other tumor diseases do not respond in the same way to the therapy. However, this is not only limited to immunotherapies. In p...

Personalized therapy is still one of the great goals of oncology. In view of the success of checkpoint inhibitor therapies in selected solid tumors, the question remains why other tumor diseases do not respond in the same way to the therapy. However, this is not only limited to immunotherapies. In principle, the understanding of the dynamic changes in a patient's tissue has so far been very limited, both for predicting a therapy success and with regard to the mechanistic understanding of how a therapy works. Model systems for diseases are often animal models that reproduce the complexity of a multi-organ system, but show significant differences to humans at the tissue level and therefore have only little informative value. Cell culture experiments, on the other hand, have only little informative value with regard to the overall behavior of a tissue or even an organ or the disease situation. "Naturalistic" co-culture in the Petri dish (such as with organoid systems) does not allow any sensible transferable insights, even if complex cell compositions of fibroblasts, endothelium or immune cells are used. In contrast, there is another problem for in vivo tumor models: either there is a lack of flexibility with regard to the structural context or the species-specific system properties do not allow any conclusions to be drawn about the situation in humans. This is a massive limitation, especially for translational studies. The Tumor Explant Model System developed by us allows the structural integrity of the tissue context to be maintained in the context of obtaining a biopsy or removing a resection. The tissue sample obtained in this way is kept in equilibrium via a bioreactor and can thus be used for tests or is preserved in its context of the tissue. It is also possible in the sense of a personalized diagnosis and therapy to take into account the individual bandwidth of the composition of the tumor microenvironment. This approach has already been validated in a prospective study and the transferability of the results from the explant models to humans has been proven. In this situation, the systematic construction of explant models for other tumor entities and the use of these models for therapy development and for better understanding of pathoregulation in tissues. In addition to the tissue samples donated by the study participants, blood cells can also be used for testing the tissue.hand to understand the basic reaction patterns of the tissue to therapies.

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