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Brain-Mimetic 3D Culture Platforms Allow Investigation of Cooperative Effects of Extracellular Matrix Features on Therapeutic Resistance in Glioblastoma
Glioblastoma (GBM) tumors exhibit potentially actionable genetic alterations against which targeted therapies have been effective in treatment of other cancers. However, these therapies have largely failed in GBM patients. A notable example is kinase inhibitors of EGFR, which display poor clinical e...
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| Published in: | Cancer research (Chicago, Ill.) Ill.), 2018-03, Vol.78 (5), p.1358-1370 |
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| container_end_page | 1370 |
| container_issue | 5 |
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| container_title | Cancer research (Chicago, Ill.) |
| container_volume | 78 |
| creator | Xiao, Weikun Zhang, Rongyu Sohrabi, Alireza Ehsanipour, Arshia Sun, Songping Liang, Jesse Walthers, Christopher M Ta, Lisa Nathanson, David A Seidlits, Stephanie K |
| description | Glioblastoma (GBM) tumors exhibit potentially actionable genetic alterations against which targeted therapies have been effective in treatment of other cancers. However, these therapies have largely failed in GBM patients. A notable example is kinase inhibitors of EGFR, which display poor clinical efficacy despite overexpression and/or mutation of EGFR in >50% of GBM. In addressing this issue, preclinical models may be limited by the inability to accurately replicate pathophysiologic interactions of GBM cells with unique aspects of the brain extracellular matrix (ECM), which is relatively enriched in hyaluronic acid (HA) and flexible. In this study, we present a brain-mimetic biomaterial ECM platform for 3D culturing of patient-derived GBM cells, with improved pathophysiologic properties as an experimental model. Compared with orthotopic xenograft assays, the novel biomaterial cultures we developed better preserved the physiology and kinetics of acquired resistance to the EGFR inhibition than gliomasphere cultures. Orthogonal modulation of both HA content and mechanical properties of biomaterial scaffolds was required to achieve this result. Overall, our findings show how specific interactions between GBM cell receptors and scaffold components contribute significantly to resistance to the cytotoxic effects of EGFR inhibition.
Three-dimensional culture scaffolds of glioblastoma provide a better physiological representation over current methods of patient-derived cell culture and xenograft models.
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| doi_str_mv | 10.1158/0008-5472.CAN-17-2429 |
| format | article |
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Three-dimensional culture scaffolds of glioblastoma provide a better physiological representation over current methods of patient-derived cell culture and xenograft models.
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Three-dimensional culture scaffolds of glioblastoma provide a better physiological representation over current methods of patient-derived cell culture and xenograft models.
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However, these therapies have largely failed in GBM patients. A notable example is kinase inhibitors of EGFR, which display poor clinical efficacy despite overexpression and/or mutation of EGFR in >50% of GBM. In addressing this issue, preclinical models may be limited by the inability to accurately replicate pathophysiologic interactions of GBM cells with unique aspects of the brain extracellular matrix (ECM), which is relatively enriched in hyaluronic acid (HA) and flexible. In this study, we present a brain-mimetic biomaterial ECM platform for 3D culturing of patient-derived GBM cells, with improved pathophysiologic properties as an experimental model. Compared with orthotopic xenograft assays, the novel biomaterial cultures we developed better preserved the physiology and kinetics of acquired resistance to the EGFR inhibition than gliomasphere cultures. Orthogonal modulation of both HA content and mechanical properties of biomaterial scaffolds was required to achieve this result. Overall, our findings show how specific interactions between GBM cell receptors and scaffold components contribute significantly to resistance to the cytotoxic effects of EGFR inhibition.
Three-dimensional culture scaffolds of glioblastoma provide a better physiological representation over current methods of patient-derived cell culture and xenograft models.
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| subjects | Animals Apoptosis Biocompatible Materials - chemistry Biomarkers, Tumor - metabolism Biomaterials Biomimetics - methods Brain cancer Brain Neoplasms - drug therapy Brain Neoplasms - metabolism Brain Neoplasms - pathology Cancer Cell culture Cell Culture Techniques - methods Cell Proliferation Cytotoxicity Drug Resistance, Neoplasm Epidermal growth factor receptors ErbB Receptors - antagonists & inhibitors Extracellular matrix Extracellular Matrix - drug effects Extracellular Matrix - metabolism Glioblastoma Glioblastoma - drug therapy Glioblastoma - metabolism Glioblastoma - pathology Humans Hyaluronic acid Hyaluronic Acid - metabolism Hydrogels - chemistry Inhibition Kinetics Mechanical properties Mice Mice, Inbred NOD Mice, SCID Physiology Protein Kinase Inhibitors - pharmacology Tumor Cells, Cultured Tumors Xenograft Model Antitumor Assays Xenografts |
| title | Brain-Mimetic 3D Culture Platforms Allow Investigation of Cooperative Effects of Extracellular Matrix Features on Therapeutic Resistance in Glioblastoma |
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