Tumor progression relies on the interaction between neoplastic epithelial cells and their surrounding stromal partners. This cell cross-talk affects stromal development, and ultimately the heterogeneity impacts drug efficacy. To mimic this evolving paradigm, 3D vascularized pancreatic adenocarcinoma tissue is microengineered in a tri-culture system composed of patient-derived pancreatic organoids, human fibroblasts, and endothelial cells on a perfusable platform, situated in a 96-well plate. Through synergistic engineering, the benefits of cellular fidelity of patient tumor organoids are combined with the flow control of an organ-on-a-chip platform. Validation of this platform includes demonstrating the growth of pancreatic tumor organoids by monitoring the change in metabolic activity of the tissue. Investigation of the tumor microenvironment highlights the role of fibroblasts in symbiosis with patient organoids, resulting in a sixfold increase of collagen deposition and corresponding increase in tissue stiffness in comparison to fibroblast free controls. The value of a perfusable vascular network is evident in drug screening, as perfusing gemcitabine into stiffened matrix does not show the dose-dependent effects on decrease in tumor viability as those under static conditions. These findings demonstrate the importance of a dynamic synergistic relationship between patient cells with stromal fibroblasts, in a 3D perfused vascular network, to accurately recapitulate a dynamic tumor microenvironment.
Impaired blood vessel formation limits the healing of diabetic ulcers and leaves patients at high risk for amputation. Nonbiologic vascular regenerative materials made of methacrylic acid (MAA) copolymer, such as MAA-co-methyl methacrylate beads, have shown to enhance wound healing in a diabetic animal model, but their lack of biodegradability precludes their clinical implementation. Here, a new MAA-based gel was created by cross-linking polyMAA with collagen using carbodiimide chemistry. Using this gel on full-thickness wounds in diabetic db/db mice augmented vascularization of the wound bed, resulting in a faster closure compared to untreated or collagen-only treated wounds. After 21 days, almost all the wounds were closed and re-epithelialized in the polyMAA-collagen group compared to that in the other groups in which most wounds remained open. Histological and fluorescent gel tracking data suggested that the gel resorbed during the phase of tissue remodeling, likely because of the action of macrophages that colonized the gel. We expect the addition of the polyMAA to commercially available collagen-based dressing to be a good candidate to treat diabetic ulcers.
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