9 results on '"Fischbach, Claudia"'
Search Results
2. Tetrathiomolybdate (TM)-associated copper depletion influences collagen remodeling and immune response in the pre-metastatic niche of breast cancer.
- Author
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Liu, Ying L., Bager, Cecilie Liv, Willumsen, Nicholas, Ramchandani, Divya, Kornhauser, Naomi, Ling, Lu, Cobham, Marta, Andreopoulou, Eleni, Cigler, Tessa, Moore, Anne, LaPolla, Dayle, Fitzpatrick, Veronica, Ward, Maureen, Warren, J. David, Fischbach, Claudia, Mittal, Vivek, and Vahdat, Linda T.
- Published
- 2021
- Full Text
- View/download PDF
3. Computational 4D-OCM for label-free imaging of collective cell invasion and force-mediated deformations in collagen.
- Author
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Mulligan, Jeffrey A., Ling, Lu, Leartprapun, Nichaluk, Fischbach, Claudia, and Adie, Steven G.
- Subjects
COLLAGEN ,DEFORMATIONS (Mechanics) ,OPTICAL coherence tomography ,CANCER invasiveness ,STROMAL cells - Abstract
Traction force microscopy (TFM) is an important family of techniques used to measure and study the role of cellular traction forces (CTFs) associated with many biological processes. However, current standard TFM methods rely on imaging techniques that do not provide the experimental capabilities necessary to study CTFs within 3D collective and dynamic systems embedded within optically scattering media. Traction force optical coherence microscopy (TF-OCM) was developed to address these needs, but has only been demonstrated for the study of isolated cells embedded within optically clear media. Here, we present computational 4D-OCM methods that enable the study of dynamic invasion behavior of large tumor spheroids embedded in collagen. Our multi-day, time-lapse imaging data provided detailed visualizations of evolving spheroid morphology, collagen degradation, and collagen deformation, all using label-free scattering contrast. These capabilities, which provided insights into how stromal cells affect cancer progression, significantly expand access to critical data about biophysical interactions of cells with their environment, and lay the foundation for future efforts toward volumetric, time-lapse reconstructions of collective CTFs with TF-OCM. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
- View/download PDF
4. Fibronectin Mechanobiology Regulates Tumorigenesis.
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Wang, Karin, Seo, Bo, Fischbach, Claudia, and Gourdon, Delphine
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FIBRONECTINS ,GLYCOPROTEINS ,BLOOD proteins ,CANCER treatment ,EXTRACELLULAR matrix proteins ,NEOPLASTIC cell transformation - Abstract
Fibronectin (Fn) is an essential extracellular matrix (ECM) glycoprotein involved in both physiological and pathological processes. The structure-function relationship of Fn has been and is still being studied, as changes in its molecular structure are integral in regulating (or dysregulating) its biological activities via its cell, matrix component, and growth factor binding sites. Fn comprises three types of repeating modules; among them, FnIII modules are mechanically unstable domains that may be extended/unfolded upon cell traction and either uncover cryptic binding sites or disrupt otherwise exposed binding sites. Cells assemble Fn into a fibrillar network; its conformational flexibility implicates Fn as a critical mechanoregulator of the ECM. Fn has been shown to contribute to altered stroma remodeling during tumorigenesis. This review will discuss (i) the significance of the structure-function relationship of Fn at both the molecular and the matrix scales, (ii) the role of Fn mechanobiology in the regulation of tumorigenesis, and (iii) Fn-related advances in cancer therapy development. [ABSTRACT FROM AUTHOR]
- Published
- 2016
- Full Text
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5. Microengineered tumor models: insights & opportunities from a physical sciences-oncology perspective.
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DelNero, Peter, Song, Young, and Fischbach, Claudia
- Abstract
Prevailing evidence has established the fundamental role of microenvironmental conditions in tumorigenesis. However, the ability to identify, interrupt, and translate the underlying cellular and molecular mechanisms into meaningful therapies remains limited, due in part to a lack of organotypic culture systems that accurately recapitulate tumor physiology. Integration of tissue engineering with microfabrication technologies has the potential to address this challenge and mimic tumor heterogeneity with pathological fidelity. Specifically, this approach allows recapitulating global changes of tissue-level phenomena, while also controlling microscale variability of various conditions including spatiotemporal presentation of soluble signals, biochemical and physical characteristics of the extracellular matrix, and cellular composition. Such platforms have continued to elucidate the role of the microenvironment in cancer pathogenesis and significantly improve drug discovery and screening, particularly for therapies that target tumor-enabling stromal components. This review discusses some of the landmark efforts in the field of micro-tumor engineering with a particular emphasis on deregulated tissue organization and mass transport phenomena in the tumor microenvironment. [ABSTRACT FROM AUTHOR]
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- 2013
- Full Text
- View/download PDF
6. Multiscale Models of Breast Cancer Progression.
- Author
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Chakrabarti, Anirikh, Verbridge, Scott, Stroock, Abraham, Fischbach, Claudia, and Varner, Jeffrey
- Abstract
Breast cancer initiation, invasion and metastasis span multiple length and time scales. Molecular events at short length scales lead to an initial tumorigenic population, which left unchecked by immune action, acts at increasingly longer length scales until eventually the cancer cells escape from the primary tumor site. This series of events is highly complex, involving multiple cell types interacting with (and shaping) the microenvironment. Multiscale mathematical models have emerged as a powerful tool to quantitatively integrate the convective-diffusion-reaction processes occurring on the systemic scale, with the molecular signaling processes occurring on the cellular and subcellular scales. In this study, we reviewed the current state of the art in cancer modeling across multiple length scales, with an emphasis on the integration of intracellular signal transduction models with pro-tumorigenic chemical and mechanical microenvironmental cues. First, we reviewed the underlying biomolecular origin of breast cancer, with a special emphasis on angiogenesis. Then, we summarized the development of tissue engineering platforms which could provide high-fidelity ex vivo experimental models to identify and validate multiscale simulations. Lastly, we reviewed top-down and bottom-up multiscale strategies that integrate subcellular networks with the microenvironment. We present models of a variety of cancers, in addition to breast cancer specific models. Taken together, we expect as the sophistication of the simulations increase, that multiscale modeling and bottom-up agent-based models in particular will become an increasingly important platform technology for basic scientific discovery, as well as the identification and validation of potentially novel therapeutic targets. [ABSTRACT FROM AUTHOR]
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- 2012
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7. Engineering tumors with 3D scaffolds.
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Fischbach, Claudia, Chen, Ruth, Matsumoto, Takuya, Schmelzle, Tobias, Brugge, Joan S., Polverini, Peter J., and Mooney, David J.
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CARCINOGENESIS , *TUMORS , *GEOCHEMICAL modeling , *CANCER cells , *VASCULAR endothelial growth factors , *DRUG therapy - Abstract
Microenvironmental conditions control tumorigenesis and biomimetic culture systems that allow for in vitro and in vivo tumor modeling may greatly aid studies of cancer cells' dependency on these conditions. We engineered three-dimensional (3D) human tumor models using carcinoma cells in polymeric scaffolds that recreated microenvironmental characteristics representative of tumors in vivo. Strikingly, the angiogenic characteristics of tumor cells were dramatically altered upon 3D culture within this system, and corresponded much more closely to tumors formed in vivo. Cells in this model were also less sensitive to chemotherapy and yielded tumors with enhanced malignant potential. We assessed the broad relevance of these findings with 3D culture of other tumor cell lines in this same model, comparison with standard 3D Matrigel culture and in vivo experiments. This new biomimetic model may provide a broadly applicable 3D culture system to study the effect of microenvironmental conditions on tumor malignancy in vitro and in vivo. [ABSTRACT FROM AUTHOR]
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- 2007
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8. Polymeric Systems for Bioinspired Delivery of Angiogenic Molecules.
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Fischbach, Claudia, Mooney, David J., and Werner, Carsten
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CYTOKINES , *GROWTH factors , *PEPTIDES , *NERVOUS system regeneration , *NEOVASCULARIZATION - Abstract
Growth factors are increasingly utilized to promote regeneration of lost or compromised tissues and organs. However, current strategies applying growth factors by bolus injections typically fail to restore tissue functions. Delivery from polymeric systems may overcome this limitation by supplying growth factors in a well-controlled, localized, and sustained manner to the defect site. Traditional polymeric delivery vehicles have been developed based on physicochemical design variables; however, it has now become clear that the appropriate mimicry of certain biologic signaling events may be necessary to achieve full function from the delivered growth factors. Because of its central importance in the development and regeneration of various tissues (e.g., blood vessels, bone, and nerves) bioinspired VEGF supply may be particularly useful to successfully restore tissue functions. Following a brief overview of VEGF's biology, design attributes for polymeric systems for VEGF delivery will be discussed, and subsequently illustrated in the context of three specific applications: therapeutic angiogenesis, bone regeneration, and nerve regeneration. [ABSTRACT FROM AUTHOR]
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- 2006
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9. Endothelial cells promote 3D invasion of GBM by IL-8-dependent induction of cancer stem cell properties.
- Author
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McCoy, Michael G., Nyanyo, Dennis, Hung, Carol K., Goerger, Julian Palacios, R. Zipfel, Warren, Williams, Rebecca M., Nishimura, Nozomi, and Fischbach, Claudia
- Abstract
Rapid growth and perivascular invasion are hallmarks of glioblastoma (GBM) that have been attributed to the presence of cancer stem-like cells (CSCs) and their association with the perivascular niche. However, the mechanisms by which the perivascular niche regulates GBM invasion and CSCs remain poorly understood due in part to a lack of relevant model systems. To simulate perivascular niche conditions and analyze consequential changes of GBM growth and invasion, patient-derived GBM spheroids were co-cultured with brain endothelial cells (ECs) in microfabricated collagen gels. Integrating these systems with 3D imaging and biochemical assays revealed that ECs increase GBM invasiveness and growth through interleukin-8 (IL-8)-mediated enrichment of CSCs. Blockade of IL-8 inhibited these effects in GBM-EC co-cultures, while IL-8 supplementation increased CSC-mediated growth and invasion in GBM-monocultures. Experiments in mice confirmed that ECs and IL-8 stimulate intracranial tumor growth and invasion in vivo. Collectively, perivascular niche conditions promote GBM growth and invasion by increasing CSC frequency, and IL-8 may be explored clinically to inhibit these interactions. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
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