Recent advancements in the application of new monomers and membrane modification techniques for the fabrication of thin film composite membranes: A review

Poor survival rates from lung cancer can largely be attributed to metastatic cells that invade and spread throughout the body. The tumor microenvironment (TME) is composed of multiple cell types, as well as non-cellular components. The TME plays a critical role in the development of metastatic cancers by providing migratory cues and changing the properties of the tumor cells. The Extracellular Matrix (ECM), a main component of the TME, has been shown to change composition during tumor progression, contributing to cancer cell invasion and survival away from the primary cancer site. Although the ECM is well-known to influence the fate of tumor progression, little is known about the molecular mechanisms that are affected by the cancer cell-ECM interactions. It is imperative that these mechanisms are elucidated in order to properly understand and prevent lung cancer dissemination. However, common in vitro studies do not incorporate these interactions into everyday cell culture assays. We have adopted a model that examines decellularized human fibroblast-derived ECM as a 3-dimensional substrate for growth of lung adenocarcinoma cell lines. Here, we have characterized the effect of fibroblast-derived matrices on the properties of various lung-derived epithelial cell lines, including cancerous and non-transformed cells. This work highlights the significance of the cell-ECM interaction and its requirement for incorporation into in vitro experiments. Implementation of a fibroblast-derived ECM as an in vitro technique will provide researchers with an important factor to manipulate to better recreate and study the TME.

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Microelastic properties of lung cell-derived extracellular matrix

Soucy

Werbin

Heinz³

et al. 2011

Acta Biomaterialia

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Mechanical properties of the extracellular microenvironment regulate cell behaviors including migration, proliferation, and morphogenesis. Although elastic moduli of synthetic materials have been studied, little is known about the properties of naturally produced extracellular matrix. Here, we utilized atomic force microscopy to characterize the microelastic properties of decellularized cell-derived matrix from human pulmonary fibroblasts. This heterogeneous three-dimensional matrix had an average thickness of 5±0.4 μm and a Young’s modulus of 105±14 Pa. Ascorbate treatment of the lung fibroblasts prior to extraction produced a two-fold increase in collagen I content, but did not affect the stiffness of the matrices compared to matrices produced in standard medium. However, fibroblast-derived matrices that were crosslinked with glutaraldehyde demonstrated a 67% increase in stiffness. This work provides a microscale characterization of fibroblast-derived matrix mechanical properties. An accurate understanding of native three-dimensional extracellular microenvironments will be essential for controlling cell responses in tissue engineering applications.

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Patricia A. Soucy

Endothelial cell adhesion, signaling, and morphogenesis in fibroblast-derived matrix

Fibroblast-Derived Extracellular Matrices: An Alternative Cell Culture System That Increases Metastatic Cellular Properties

Microelastic properties of lung cell-derived extracellular matrix

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