PO.TB04.06 · 肿瘤生物学

GliomaPDOX - A direct brain-to-brain glioma xenograft library for drug discovery and development

海报缩略图:GliomaPDOX - A direct brain-to-brain glioma xenograft library for drug discovery and development
编号 2162 展板 13 时间 4/20 09:00–12:00 区域 Section 29 主讲 Elizabeth Fernandez
分会场 In Vivo Models 1: Mouse, Zebrafish, and Alternative Species
查看完整资料 下载 PDF 登录后可访问当前开放资料 AACR 官方页面 ↗

作者与单位

Elizabeth G. Fernandez1, Christopher Tse1, Jennifer Salinas1, Nicholas Bayley1, Lisa H. Ta1, Laura Gosa1, Henan Zhu1, Michael Vigman1, Francesco Sanvito1, Benjamin M. Ellingson2, Linda M. Liau3, Timothy Cloughsey1, Thomas G. Graeber1, Nathanson David1

1University of California, Los Angeles, Los Angeles, CA,2Assistant Professor of Radiology; Dept. of Radiological Sciences, University of California, Los Angeles, Los Angeles, CA,3UCLA David Geffen School of Medicine, Los Angeles, CA

摘要 Abstract

Cancer drug discovery and development rely on preclinical models that accurately reflect the molecular and functional characteristics of human tumors, while accounting for in vivo factors that influence drug efficacy, such as pharmacokinetics, metabolism and toxicity. Malignant gliomas are highly aggressive brain tumors that develop within the brain parenchyma, where their heterogeneous cellular composition engage in complex interactions with highly specialized brain cells, and a blood brain barrier that restricts drug penetration. When removed from this native environment, such as in culture or heterotopic in vivo environments (e.g., flank), gliomas either lose their molecular diversity or fail to grow altogether. Therefore, there is a critical need for physiologically relevant models that capture both the intra and inter-tumor diversity of glioma, as well as the organismal context required for drug development. Here, we present GliomaPDOX - a direct brain to brain glioma orthotopic xenograft biobank, consisting of more than 200 unique models that faithfully recapitulate the key molecular, histopathological, and proliferative features of their parental tumors. By incorporating a non-invasive, secreted reporter system to monitor tumor burden in real time-including drug-induced changes in intracranial tumor growth-we demonstrate the utility of GliomaPDOX for therapeutic evaluation. Together, this robust platform provides a physiologically relevant system to accelerate drug discovery and development for glioma.
利益披露 Disclosure
E. G. Fernandez, None.. C. Tse, None.. J. Salinas, None.. N. Bayley, None.. L. Gosa, None.. H. Zhu, None.. M. Vigman, None.. F. Sanvito, None.

在会议检索中打开