Vahid Afshar-Kharghan

OvCa-Chip microsystem recreates vascular endothelium–mediated platelet extravasation in ovarian cancer

Abstract In ovarian cancer, platelet extravasation into the tumor and resulting metastasis is thought to be regulated mostly by the vascular endothelium. Because it is difficult to dissect complex underlying events in murine models, organ-on-a-chip methodology is applied to model vascular and platelet functions in ovarian cancer. This system (OvCa-Chip) consists of microfluidic chambers that are lined by human ovarian tumor cells interfaced with a 3-dimensional endothelialized lumen. Subsequent perfusion with human platelets within the device’s vascular endothelial compartment under microvascular shear conditions for 5 days uncovered organ-to-molecular–level contributions of the endothelium to triggering platelet extravasation into tumors. Further, analysis of effluents available from the device’s individual tumor and endothelial chambers revealed temporal dynamics of vascular disintegration caused by cancer cells, a differential increase in cytokine expression, and an alteration of barrier maintenance genes in endothelial cells. These events, when analyzed within the device over time, made the vascular tissue leaky and promoted platelet extravasation. Atorvastatin treatment of the endothelial cells within the OvCa-Chip revealed improved endothelial barrier function, reduction in inflammatory cytokines and, eventually, arrest of platelet extravasation. These data were validated through corresponding observations in patient-derived tumor samples. The OvCa-Chip provides a novel in vitro dissectible platform to model the mechanisms of the cancer-vascular-hematology nexus and the analyses of potential therapeutics.

Human tumor microenvironment chip evaluates the consequences of platelet extravasation and combinatorial antitumor-antiplatelet therapy in ovarian cancer

A tumor microenvironment chip reveals how platelets may fuel cancer metastasis and chemoresistance and unravels a new treatment.

The effect of platelet G proteins on platelet extravasation and tumor growth in the murine model of ovarian cancer

Abstract We and other investigators have shown that platelets promote metastasis and the growth of tumors. Our rationale for conducting this study is that platelets’ prometastatic and progrowth effects depend on a close encounter between platelets and cancer cells. This interaction occurs inside blood vessels with circulating tumor cells and outside blood vessels with cancer cells residing in the tumor parenchyma. Our hypothesis was that platelet extravasation is required for the effect of platelets on tumor growth. Platelets respond to environmental stimuli by activation of G protein–coupled receptors on their surface. We investigated the impact of various platelet G proteins on the growth of ovarian cancer tumors and platelet extravasation. We used mice with platelet-specific deficiency of Gαi2 (Gi), Gα13 (G13), or Gαq (Gq) in a syngeneic ovarian cancer model. We measured the total weight of tumor nodules resected from tumor-bearing mice. We developed methods for automated whole-slide image acquisition and unbiased computerized image analysis to quantify extravasated platelets. We compared the number of platelets inside tumor nodules of platelet G protein–deficient tumor-bearing mice. We found that deficiency of Gi and G13, but not Gq, in platelets resulted in smaller tumors compared with those in corresponding littermates. Deficiency of Gi and G13 in platelets reduced the number of extravasated platelets by >90%, but deficiency of Gq did not reduce the number of extravasated platelets significantly. The lack of Gi or G13 in platelets reduced platelet extravasation into the tumor and tumor growth.