Novel application of live imaging to determine the functional cell biology of endothelial-to-mesenchymal transition (EndMT) within a liver-on-a-chip platform

Whiteford, James R.; Arokiasamy, Samantha; Thompson, Claire; Dufton, Neil

doi:10.1007/s44164-022-00034-9

Cited by 6 publications

(1 citation statement)

References 17 publications

(18 reference statements)

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“…to enable live‐tracking of EndMT. [ 136 ] In their approach, although HUVEC cells undergoing EndMT had significantly higher fluorescent signals, wild‐type HUVEC cells were also tagged by EndMT‐Rep. This may provide a useful future direction to engineer a pan‐endothelial cell tracking system for studies involving PDE culture.…”

Section: Strategies To Overcome Limitations Of Pde Modelsmentioning

confidence: 99%

Making In Vitro Tumor Models Whole Again

Adine

Mitriashkin

et al. 2023

Adv Healthcare Materials

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As a reductionist approach, patient‐derived in vitro tumor models are inherently still too simplistic for personalized drug testing as they do not capture many characteristics of the tumor microenvironment (TME), such as tumor architecture and stromal heterogeneity. This is especially problematic for assessing stromal‐targeting drugs such as immunotherapies in which the density and distribution of immune and other stromal cells determine drug efficacy. On the other end, in vivo models are typically costly, low‐throughput, and time‐consuming to establish. Ex vivo patient‐derived tumor explant (PDE) cultures involve the culture of resected tumor fragments that potentially retain the intact TME of the original tumor. Although developed decades ago, PDE cultures have not been widely adopted likely because of their low‐throughput and poor long‐term viability. However, with growing recognition of the importance of patient‐specific TME in mediating drug response, especially in the field of immune‐oncology, there is an urgent need to resurrect these holistic cultures. In this Review, the key limitations of patient‐derived tumor explant cultures are outlined and technologies that have been developed or could be employed to address these limitations are discussed. Engineered holistic tumor explant cultures may truly realize the concept of personalized medicine for cancer patients.

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Section: Strategies To Overcome Limitations Of Pde Modelsmentioning

confidence: 99%

Making In Vitro Tumor Models Whole Again

Adine

Mitriashkin

et al. 2023

Adv Healthcare Materials

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Fibrosis‐on‐Chip: A Guide to Recapitulate the Essential Features of Fibrotic Disease

Streutker,

Devamoglu,

Vonk

et al. 2024

Adv Healthcare Materials

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Fibrosis, which is primarily marked by excessive extracellular matrix (ECM) deposition, is a pathophysiological process associated with many disorders, which ultimately leads to organ dysfunction and poor patient outcomes. Despite the high prevalence of fibrosis, currently there exist few therapeutic options, and importantly, there is a paucity of in vitro models to accurately study fibrosis. This review discusses the multifaceted nature of fibrosis from the viewpoint of developing organ‐on‐chip (OoC) disease models, focusing on five key features: the ECM component, inflammation, mechanical cues, hypoxia and vascularization. We explore the potential of OoC technology for better modeling these features in the context of studying fibrotic diseases and emphasize the interplay between various key features. We review how organ‐specific fibrotic diseases have been modeled in OoC platforms, which elements have been included in these existing models, and we highlight avenues for novel research directions. Finally, we conclude with a perspective section on how to address the current gap with respect to the inclusion of multiple features to yield more sophisticated and relevant models of fibrotic diseases in an OoC format.This article is protected by copyright. All rights reserved

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Endothelial‐mesenchymal transition in skeletal muscle: Opportunities and challenges from 3D microphysiological systems

Francescato,

Moretti,

Bersini

2024

Bioengineering & Transla Med

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Fibrosis is a pathological condition that in the muscular context is linked to primary diseases such as dystrophies, laminopathies, neuromuscular disorders, and volumetric muscle loss following traumas, accidents, and surgeries. Although some basic mechanisms regarding the role of myofibroblasts in the progression of muscle fibrosis have been discovered, our knowledge of the complex cell–cell, and cell–matrix interactions occurring in the fibrotic microenvironment is still rudimentary. Recently, vascular dysfunction has been emerging as a key hallmark of fibrosis through a process called endothelial‐mesenchymal transition (EndoMT). Nevertheless, no effective therapeutic options are currently available for the treatment of muscle fibrosis. This lack is partially due to the absence of advanced in vitro models that can recapitulate the 3D architecture and functionality of a vascularized muscle microenvironment in a human context. These models could be employed for the identification of novel targets and for the screening of potential drugs blocking the progression of the disease. In this review, we explore the potential of 3D human muscle models in studying the role of endothelial cells and EndoMT in muscle fibrotic tissues and identify limitations and opportunities for optimizing the next generation of these microphysiological systems. Starting from the biology of muscle fibrosis and EndoMT, we highlight the synergistic links between different cell populations of the fibrotic microenvironment and how to recapitulate them through microphysiological systems.

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Novel application of live imaging to determine the functional cell biology of endothelial-to-mesenchymal transition (EndMT) within a liver-on-a-chip platform

Cited by 6 publications

References 17 publications

Making In Vitro Tumor Models Whole Again

Making In Vitro Tumor Models Whole Again

Fibrosis‐on‐Chip: A Guide to Recapitulate the Essential Features of Fibrotic Disease

Endothelial‐mesenchymal transition in skeletal muscle: Opportunities and challenges from 3D microphysiological systems

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