High-speed reliable detection of cancer cells in blood

高速可靠地检测血液中的癌细胞

• 批准号: 7474609
• 负责人: Richard H. Bruce
• 金额: $ 84.67万
• 依托单位: PALO ALTO RESEARCH CENTER
• 依托单位国家: 美国
• 财政年份: 2006
• 资助国家: 美国
• 起止时间: 2006-09-06 至 2011-07-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7474609
• 关键词: Antigens; Area; Automation; Biomedical Engineering; Blood; Blood Cells; Blood specimen; Cancer Center; Cancer Patient; Cancer Research Project; Cell Count; Cell Line; Cells; Clinic; Clinical; Clinical Oncology; Collaborations; Computer software; Data; Detection; Development; Diagnostic Neoplasm Staging; Disclosure; Disease; Disseminated Malignant Neoplasm; Doctor of Philosophy; Engineering; Enrollment; Fiber; Heterogeneity; Human; Image; Incidence; Institution; Label; Lead; Malignant Neoplasms; Measures; Mechanics; Medical; Medicine; Methods; Microscopy; Monitor; Numbers; Optics; Pathology; Patients; Performance; Population; Preparation; Prevalence; Principal Investigator; Procedures; Process; Protocols documentation; Publishing; Rate; Recurrent disease; Relapse; Reporting; Research; Research Institute; Research Personnel; Research Subjects; Resolution; Risk; Sampling; Scanning; Screening for cancer; Specificity; Specimen Handling; Speed; Stage at Diagnosis; Staging; Statistically Significant; System; Technology; Time; Title; Today; United States Food and Drug Administration; Validation; Visual; base; burden of illness; cancer cell; cell preparation; cohort; computerized data processing; concept; cost; design; experimental analysis; improved; instrument; interdisciplinary approach; malignant breast neoplasm; method development; multidisciplinary; neoplastic cell; new technology; oncology; peripheral blood; programs; prototype; response

DESCRIPTION (provided by applicant): The medical value of detecting circulating tumor cells (CTCs) in peripheral blood is now established, and a specific approach has FDA approval for managing metastatic patients. While the value is clear, it is also limited in application. For example, the reported results are uninformative for a large percentage of metastatic patients, and no validation exists for earlier stages. The cancer bioengineering research partnership (CBRP) proposes to develop a technology for CTC detection that overcomes these limitations. We will develop a new instrument, the Fiber Array Scan Technology (FAST) cytometer that efficiently scans the large numbers of cells required to detect CTCs and a cell preparation protocol that is optimized for cell retention. We will use these developments to investigate whether more metastatic patients have CTCs than current approaches indicate. We will also investigate the medical efficacy of CTC detection in early stage cancer patients. In addition we will investigate applications for staging at diagnosis, as well as for longitudinal therapy monitoring and long-term patient management. The effort integrates clinical oncology with biophysical analysis methods and opto-mechanical engineering. The CBRP will develop a rare cell detection system that can analyze approximately 50 million cells in 2 minutes with a sensitivity of 10% false negatives and a false positive ratio of less than 1 in 107. The Lead Investigators of the CBRP have developed the initial proof of concept through a multidisciplinary approach bridging optical design, statistical software analysis, experimental medicine, oncology, and pathology at the leading institutions, the Palo Alto Research Center (PARC) and The Scripps Research Institute (TSRI), as well as at the participating institutions, Scripps Clinic and the Scripps Cancer Center. The lead investigators are Richard Bruce, Ph.D. (PARC), who is the principal investigator and will in addition lead the optical and system engineering efforts; Peter Kuhn, Ph.D. (TSRI), who will lead the experimental processing; and Jorge Nieva, MD (TSRI and Scripps Cancer Center), who will lead the oncology and pathology of the CBRP. The lead investigators are experts in their respective fields and provide the required expertise for the multi-disciplinary research program of the CBRP.

描述（由申请人提供）：检测外周血中循环肿瘤细胞（CTC）的医学价值现已确立，FDA批准了一种用于管理转移性患者的特定方法。虽然价值是明确的，但在应用上也是有限的。例如，报告的结果对于大部分转移性患者是无信息的，并且对于早期阶段不存在验证。癌症生物工程研究伙伴关系（CBRP）建议开发一种克服这些限制的CTC检测技术。我们将开发一种新的仪器，即光纤阵列扫描技术（FAST）细胞仪，它可以有效地扫描检测CTC所需的大量细胞，并开发一种针对细胞保留进行优化的细胞制备方案。我们将利用这些进展来研究是否有更多的转移性患者比目前的方法表明有CTC。我们还将研究CTC检测在早期癌症患者中的医疗功效。此外，我们还将研究在诊断分期，以及纵向治疗监测和长期患者管理方面的应用。这项工作将临床肿瘤学与生物物理分析方法和光机械工程相结合。CBRP将开发一种罕见细胞检测系统，可以在2分钟内分析约5000万个细胞，灵敏度为10%假阴性，假阳性率低于1/107。CBRP的主要研究者通过多学科方法开发了初步的概念验证，该方法将领先机构帕洛阿尔托研究中心（PARC）和斯克里普斯研究所（TSRI）以及参与机构斯克里普斯诊所和斯克里普斯癌症中心的光学设计、统计软件分析、实验医学、肿瘤学和病理学联系起来。主要研究者是Richard布鲁斯博士。（PARC），他是首席研究员，还将领导光学和系统工程工作; Peter Kuhn博士（TSRI），谁将领导实验处理;和豪尔赫Nieva，医学博士（TSRI和斯克里普斯癌症中心），谁将领导CBRP的肿瘤学和病理学。首席研究员是各自领域的专家，并为CBRP的多学科研究计划提供所需的专业知识。