Decellularized matrices are steadily gaining popularity to study the biology of cells and tissues, as they represent a biomimetic environment in which cells can recapitulate certain behaviours that share similarities with those observed in vivo. Basically, biochemistry, microstructure and mechanics of the decellularized matrices are the most valuable properties that differentiate these culturing systems from conventional bidimensional models. Several procedures to decellularize tissues have been proposed so far, with the common aim to preserve the tissue chemical/physical properties of the original tissue. However, these processes are complex, time-consuming and expensive. In this work, we propose a cost-effective, easy-to-produce decellularized dermal matrix, derived from animal skin. The chemical/physical processes to obtain the matrices proved to not alter matrix structure and did not induce cytotoxicity issues. To test the validity of the decellularized matrices as a model to study the behaviour of tumour cells in vitro, we performed microstructural and mechanical investigations as well as cell proliferation assays. In particular, three different tumour cell lines were used, which proliferated and invaded the matrix with no additional treatments. Decellularized skin scaffold, presented in this work, could be a strong competitor for conventional 3D systems like synthetic porous scaffolds or hydrogels.
Early in the COVID-19 pandemic, it emerged that the risk of severe outcomes was greater in patients with co-morbidities, including cancer. The huge effort undertaken to fight the pandemic, affects the management of cancer care, influencing their outcome. Despite the high fatality rate of COVID-19 disease in cancer patients, rare cases of temporary or prolonged clinical remission from cancers after SARS-CoV-2 infection have been reported. We have reviewed sixteen case reports of COVID-19 disease with spontaneous cancer reduction of progression. Fourteen cases of remission following viral infections and two after anti-SARS-CoV-2 vaccination. The immune response to COVID-19, may be implicated in both tumor regression, and progression. Specifically, we discuss potential mechanisms which include oncolytic and priming hypotheses, that may have contributed to the cancer regression in these cases and could be useful for future options in cancer treatment.
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