Endothelial Thermotolerance Impairs Nanoparticle Transport in Tumors

Bagley, Alexander F.; Scherz-Shouval, Ruth; Galie, Peter A.; Zhang, Angela Q.; Wyckoff, Jeffrey; Whitesell, Luke; Chen, Christopher; Lindquist, Susan; Bhatia, Sangeeta N.

doi:10.1158/0008-5472.can-15-0325

Cited by 27 publications

(29 citation statements)

References 52 publications

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“…Bagley et al demonstrated the use of plasmonic nanoantennae to enhance transport into a model of ovarian cancer via heat generation. They also used temperaturecontrolled microfluidic devices to measure diffusion of the nanoparticles in vitro [192]. The use of microfluidic devices to aid in the rapid development of translatable nanoparticles for TME studies is a very active and promising area of research.…”

Section: Transport and Delivery Of Nanoparticlesmentioning

confidence: 99%

Tumour-on-a-chip: microfluidic models of tumour morphology, growth and microenvironment

Tsai

Trubelja

Shen

et al. 2017

J. R. Soc. Interface.

168

133

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Cancer remains one of the leading causes of death, albeit enormous efforts to cure the disease. To overcome the major challenges in cancer therapy, we need to have a better understanding of the tumour microenvironment (TME), as well as a more effective means to screen anti-cancer drug leads; both can be achieved using advanced technologies, including the emerging tumour-on-a-chip technology. Here, we review the recent development of the tumour-on-a-chip technology, which integrates microfluidics, microfabrication, tissue engineering and biomaterials research, and offers new opportunities for building and applying functional three-dimensional in vitro human tumour models for oncology research, immunotherapy studies and drug screening. In particular, tumour-on-a-chip microdevices allow well-controlled microscopic studies of the interaction among tumour cells, immune cells and cells in the TME, of which simple tissue cultures and animal models are not amenable to do. The challenges in developing the next-generation tumour-on-a-chip technology are also discussed.

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Section: Transport and Delivery Of Nanoparticlesmentioning

confidence: 99%

Tumour-on-a-chip: microfluidic models of tumour morphology, growth and microenvironment

Tsai

Trubelja

Shen

et al. 2017

J. R. Soc. Interface.

168

133

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“…Vascular structure, perfusion, and permeability continue to be key features captured by IVM, and IVM studies have been useful in parsing the influence of various cell populations including perivascular VEGF+ macrophages [64]; therapeutic adjuvants such as anti-VEGF treatment [226], radiation [227], ultrasound [228], and hyperthermia [47,229,230]; and NP physicochemical features such as size [50,219] and shape [231] impact transport from vasculature to the target tissue. Reporter GEMMs enable clear and simultaneous visualization of vascularity, for instance using Tie2-GFP GEMMs [230], and neighboring cell populations.…”

Section: The Nuts and Bolts Of Ivm Nanoparticle Imagingmentioning

confidence: 99%

“…Reporter GEMMs enable clear and simultaneous visualization of vascularity, for instance using Tie2-GFP GEMMs [230], and neighboring cell populations. As an example, a two-color GEMM that ubiquitously expresses membrane-anchored RFP, including in the endothelium, and GFP in CX3CR1+ phagocytes, was used to visualize NP transport from tumor vasculature to adjacent perivascular phagocytic cells [54].…”

Section: The Nuts and Bolts Of Ivm Nanoparticle Imagingmentioning

confidence: 99%

“…As an example, a two-color GEMM that ubiquitously expresses membrane-anchored RFP, including in the endothelium, and GFP in CX3CR1+ phagocytes, was used to visualize NP transport from tumor vasculature to adjacent perivascular phagocytic cells [54]. Fluorescent dextran conjugates of various molecular weight are often used to measure vessel permeability in both cancer and inflammation, as was recently done in study of local tissue heating [230], local macrophage accumulation [64], allergan-induced permeability from IgE release [232], and interferon-gamma induced permeability in a model of colitis [233]. Increasing IVM resolution and stability have enabled much greater mechanistic insight into the causes of macromolecular or NP extravasation, with recent insight into the role of subcellular tumor-cell protrusions into vascular space [64] and highly dynamic bursts of NP extravasation that last under 30 min for smaller NPs [30].…”

Section: The Nuts and Bolts Of Ivm Nanoparticle Imagingmentioning

confidence: 99%

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Imaging the pharmacology of nanomaterials by intravital microscopy: Toward understanding their biological behavior

Miller

Weissleder

2017

Advanced Drug Delivery Reviews

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Therapeutic nanoparticles (NPs) can deliver cytotoxic chemotherapeutics and other drugs more safely and efficiently to patients; furthermore, selective delivery to target tissues can theoretically be accomplished actively through coating NPs with molecular ligands, and passively through exploiting physiological “enhanced permeability and retention” features. However, clinical trial results have been mixed in showing improved efficacy with drug nano-encapsulation, largely due to heterogeneous NP accumulation at target sites across patients. Thus, a clear need exists to better understand why many NP strategies fail in vivo and not result in significantly improved tumor uptake or therapeutic response. Multicolor in vivo confocal fluorescence imaging (intravital microscopy; IVM) enables integrated pharmacokinetic and pharmacodynamic (PK/PD) measurement at the single-cell level, and has helped answer key questions regarding the biological mechanisms of in vivo NP behavior. This review summarizes progress to date and also describes useful technical strategies for successful IVM experimentation.

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“…Such microfluidic devices have been used to study various aspects of cancer progression such as tumor growth, presence of high interstitial fluid pressure, and cancer cell extravasation 18–24 . Such technological platforms have also been used to understand drug-tumor interactions such as drug specificity, penetration into cancer spheroids, and efficacy towards repressing cancer growth 20, 24–27 . Many of these platforms employ multi-layered or multi-channel devices to create a perfused tumor-a-on-chip system 18, 21, 25, 26 .…”

Section: Introductionmentioning

confidence: 99%

Chemotaxis-driven assembly of endothelial barrier in a tumor-on-a-chip platform

et al. 2016

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The integration of three-dimensional micropatterning with microfluidics provides a unique opportunity to create perfusable tissue constructs in vitro. Herein, we have used this approach to create a tumor-on-chip with endothelial barrier. Specifically, we photopatterned a mixture of endothelial cells and cancer spheroids within a gelatin methacrylate (GelMA) hydrogel inside of a microfluidic device. The differential motility of endothelial and cancer cells in response to a controlled morphogen gradient across the cell-laden network drove the migration of endothelial cells to the periphery while maintaining the cancer cells within the interior of the hydrogel. The resultant endothelial cell layer forming cell-cell contact via VE-Cadherin junctions was found to encompass the entire the GelMA hydrogel structure. Furthermore, we have also examined the potential of such tumor-on-a-chip system as a drug screening platform using Doxorubicin, a model cancer drug.

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Endothelial Thermotolerance Impairs Nanoparticle Transport in Tumors

Cited by 27 publications

References 52 publications

Tumour-on-a-chip: microfluidic models of tumour morphology, growth and microenvironment

Tumour-on-a-chip: microfluidic models of tumour morphology, growth and microenvironment

Imaging the pharmacology of nanomaterials by intravital microscopy: Toward understanding their biological behavior

Chemotaxis-driven assembly of endothelial barrier in a tumor-on-a-chip platform

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