Multi-Scale Bio-Simulations

多尺度生物模拟

• 批准号: 8325728
• 负责人: Vittorio Cristini
• 金额: $ 14.01万
• 依托单位: METHODIST HOSPITAL RESEARCH INSTITUTE
• 依托单位国家: 美国
• 资助国家: 美国
• 起止时间: 至
• 项目状态: 未结题
• 来源: https://reporter.nih.gov/project-details/8325728
• 关键词: Accounting; Adhesives; Antineoplastic Agents; Behavior; Biomedical Engineering; Blood Vessels; Calibration; Cardiology; Cells; Chairperson; Chemical Engineering; Collaborations; Computer Simulation; Development; Discontinuous Capillary; Doctor of Philosophy; Endothelium; Engineering; Environment; Epithelial; Extravasation; Generations; Health; Health Sciences; Heating; Information Sciences; Injectable; Internal Medicine; Intracellular Transport; Italy; Lead; Lesion; Liver; Mathematics; Mechanics; Medicine; Modeling; Nanotechnology; Particulate; Patients; Physics; Plasma; Property; Protocols documentation; Research; Simulate; Solid Neoplasm; System; Techniques; Texas; Therapeutic; Therapeutic Agents; Tissues; Universities; Vascular Endothelium; bioimaging; biological systems; biomathematics; cell injury; design; improved; macrophage; mathematical model; model design; multi-scale modeling; nanomedicine; nanoscale; nanosized; professor; response; simulation; small molecule; tool; transcytosis; tumor; tumor growth; vascular endothelium permeability

Core 1 will provide an In silico framework (i) for modeling the systemic administration of therapeutic agents to solid tumors, their transport properties, and their efficacy in controlling tumor growth and (ii) for the 'rational design' of injectable nano-sized particulate systems (nPSs). The mathematical tools will be multi-scale and multi-physics spanning from the analysis of particulate transport within the vascular compartment (sovracellular level, > 10 um), to the adhesive interactions with the vascular walls and macrophages/Kuppfer cells within the liver sinusoids (cellular level, >1 um and <10 um); to the passive translocation across the vascular endothelium and Gl epithelial layers (sub-cellular level, < 1 um), down to the cellular internalization and intracellular transport (sub-cellular level, ¿ 1 um). This core is composed by modules, highly integrated one with the other the other core. Core 1 is co-lead by Drs. Cristini and Decuzzi with the collaboration of Dr. Ferrari and Dr. Macklin. Dr. Cristini (Ph.D. Chemical Engineering, FAAN) is an Associate Professor of Biomedical Engineering and Health Information Sciences at the University of Texas Health Science Center and provides multiscale modeling expertise. Dr. Decuzzi (Ph.D. Mechanical Engineering) is an Associate Professor of Mechanical and Biomedical Engineering at the University of Texas Health Science Center and the Center for Bio/Nanotechnology and Engineering for Medicine at the University of Magna Graecia (In Italy). Dr. Ferrari (Ph.D. Mechanical Engineering) is professor of Professor and Director of the Division of Nanomedicine and Professor of Internal Medicine in the Cardiology Division of The University of Texas Health Science Center, Deputy Chairman of the Department of Biomedical Engineering at the University of Texas. Dr. Macl<lin (Ph.D. Applied Mathematics) is an Assistant Professor of Health Information Sciences at the University of Texas Health Science Center and has researched mathematical modeling of tunnors and their local environment [120-123] and provides expertise in applied mathematics.

核心1将提供一个硅框架(i)用于模拟治疗药物对实体肿瘤的系统给药，它们的运输特性，以及它们在控制肿瘤生长方面的功效；（ii）用于可注射纳米颗粒系统（nps）的“合理设计”。数学工具将是多尺度和多物理跨越分析颗粒运输在血管室（索细胞）