Development of Targeted Anticancer Drugs

靶向抗癌药物的开发

• 批准号: 8064408
• 负责人: James M. Gallo
• 金额: $ 34.12万
• 依托单位: ICAHN SCHOOL OF MEDICINE AT MOUNT SINAI
• 依托单位国家: 美国
• 财政年份: 2008
• 资助国家: 美国
• 起止时间: 2008-07-01 至 2013-04-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8064408
• 关键词: Animals; Antineoplastic Agents; Area Under Curve; Behavior; Biological Assay; Blood - brain barrier anatomy; Brain; Brain Neoplasms; Bypass; Cancer Patient; Cell Line; Cells; Characteristics; Clinical; Clinical Trials; Coupled; Data Set; Development; Development Plans; Dose; Dose-Limiting; Drug Administration Schedule; Drug Efflux; Drug Kinetics; Drug or chemical Tissue Distribution; Ensure; Epidermal Growth Factor Receptor; Epidermal Growth Factor Receptor Tyrosine Kinase Inhibitor; Erlotinib; Failure; Gefitinib; Glioma; Goals; Health; Human; Hybrids; In Vitro; Individual; Inhibitory Concentration 50; Investigation; Lead; Letters; Link; Measurement; Measures; Modeling; Molecular; Molecular Weight; Motivation; Mus; Oral; Pathway interactions; Patients; Penetration; Pharmaceutical Preparations; Pharmacodynamics; Pharmacogenetics; Phase; Physiological; Plasma; Procedures; Property; Protocols documentation; Receptor Signaling; Regimen; Reliance; Route; Schedule; Scheme; Screening procedure; Series; Signal Pathway; Site; Testing; Therapeutic; Time; Tissues; Translations; Tumor Cell Line; Tumor-Derived; Tyrosine Kinase Inhibitor; anti-cancer therapeutic; base; cytotoxic; cytotoxicity; design; drug candidate; drug development; drug discovery; drug efficacy; drug sensitivity; efflux pump; epidermal growth factor receptor VIII; in vitro activity; in vivo; mutant; novel; pharmacodynamic model; pre-clinical; preclinical study; programs; protein expression; scale up; therapeutic target; tool; tumor; uptake

DESCRIPTION (provided by applicant): This project is concerned with the development of a new drug development paradigm that focuses on the use of preclinical studies in animals to derive predictive pharmacokinetic [PK] - pharmacodynamic [PD] models that can aid in the rational selection of drug candidates, and be used to predict human PK-PD characteristics. A unique feature of the proposal is that the drug's PK-PD properties in target tissues, in this case brain and brain tumors, are integral to the drug development plan. The proposed drug development strategy will be demonstrated for a series of epidermal growth factor receptor [EGFR] inhibitors, a class of small molecular weight compounds that are represenative of targeted anticancer drugs, an emerging anticancer therapeutic strategy. The motivation for this new drug development approach is based on limitations of current semi-empirical anticancer drug development approaches, which rely on a plethora of drug efficacy studies that lack predictive capability on how drugs should be used in humans. Moreover, EGFR inhibitors are representative of the problems of defining optimal doses for targeted therapies in cancer patients, since these classes of drugs often do not possess readily identified dose-limiting toxicites that typically guide the use of standard cytotoxics. The PK-PD driven approach will rely on the use of hybrid PK-PD models that enables a target tissue [i.e. brain tumors] to be represented in physiological terms, which accomodates a mechanistic depiction of drug disposition, and facilitates model scale-up to humans. The drug development scheme will be implemented in brain tumor models that differ only in EGFR status, one being wild-type and the other the vIII mutant, which is associated with drug sensitivity, which will allow us to test the broader applicability of the approach to other brain tumor models whose molecular characteristics are known. A synopsis of the Specific Aims are 1) screen new EGFR inhibitors for brain accumulation in a cassette dosing format; 2) determine in vitro PD endpoints associated with EGFR signaling pathways; 3) develop hybrid PK-PD models in mice; and 4) evaluate drug efficacy in a range of brain tumor types based on the use of PK-PD equivalent dosing regimens. The proposed drug development package relies on a drug's in vivo pharmacological behavior to screen, select, and subsequently design therapeutic regimens based on model-predicted PK-PD endpoints. It is believed that this approach offers the best opportunity to develop drugs in a rational and optimal manner. PUBLIC HEALTH RELEVANCE: The translation of preclinical pharmacological information of new anticancer drugs to patients does not offer a direct conduit to ensure biologically relevant and optimal drug doses are administered. The current proposal will attempt to rectify these deficiencies through the implementation of a new drug development paradigm based on a drug's pharmacokinetic and pharmacodynamic characteristics in the target tissue, which for this project is brain tumors.

描述（由申请人提供）：本项目涉及一种新药开发模式的开发，该模式侧重于使用动物临床前研究来推导预测性药代动力学[PK] -药效学[PD]模型，该模型可帮助合理选择候选药物，并用于预测人体PK-PD特征。该提案的一个独特之处在于，药物在靶组织（在这种情况下是脑和脑肿瘤）中的PK-PD特性是药物开发计划的组成部分。将针对一系列表皮生长因子受体[EGFR]抑制剂（一类代表靶向抗癌药物的小分子量化合物，一种新兴的抗癌治疗策略）证明拟定的药物开发策略。这种新药开发方法的动机是基于当前半经验抗癌药物开发方法的局限性，这些方法依赖于大量的药物疗效研究，这些研究缺乏对药物应如何用于人类的预测能力。此外，EGFR抑制剂代表了确定癌症患者靶向治疗的最佳剂量的问题，因为这些类别的药物通常不具有通常指导标准细胞毒性药物使用的容易鉴定的剂量限制性毒性物质。PK-PD驱动的方法将依赖于混合PK-PD模型的使用，该模型使靶组织[即脑肿瘤]能够以生理学术语表示，这适应药物分布的机械描述，并促进模型放大至人类。该药物开发计划将在仅EGFR状态不同的脑肿瘤模型中实施，一个是野生型，另一个是与药物敏感性相关的vIII突变体，这将使我们能够测试该方法对其他分子特征已知的脑肿瘤模型的更广泛适用性。具体目的概要为：1）以卡匣给药形式筛选新的EGFR抑制剂的脑蓄积; 2）确定与EGFR信号传导途径相关的体外PD终点; 3）在小鼠中开发混合PK-PD模型;以及4）基于使用PK-PD等效给药方案，评价药物在一系列脑肿瘤类型中的疗效。拟议的药物开发包依赖于药物的体内药理学行为，以筛选，选择和随后设计基于模型预测的PK-PD终点的治疗方案。人们认为，这种方法提供了以合理和最佳方式开发药物的最佳机会。 公共卫生关系：将新抗癌药物的临床前药理学信息翻译给患者并不能提供一个直接的渠道来确保给予生物学相关的最佳药物剂量。目前的提案将试图通过实施基于药物在靶组织（本项目为脑肿瘤）中的药代动力学和药效学特征的新药开发范式来纠正这些缺陷。