Detection of micrometastasis using a dual-ligand nanoparticle

使用双配体纳米颗粒检测微转移

基本信息

批准号：
8876614
负责人：
Efstathios Karathanasis
金额：
$ 32.2万
依托单位：
CASE WESTERN RESERVE UNIVERSITY
依托单位国家：
美国
项目类别：
财政年份：
2013
资助国家：
美国
起止时间：
2013-07-01 至 2016-05-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/8876614
关键词：
4T1 Affect Animals Avidity Blinded Blood Vessels Breast Cancer Model Breast cancer metastasis Case Study Cessation of life Chemicals Clinical Contrast Media Coupled Data Detection Development Diagnostic Dimensions Disease Disseminated Malignant Neoplasm Dose Endothelial Cells Endothelium Epidermal Growth Factor Receptor Exhibits Gold Health Image Immunohistochemistry In Vitro Integrin Binding Integrins Label Length Ligands Link Liver Lung Magnetic Resonance Imaging Magnetism Malignant Neoplasms Metastatic Lesion Metastatic to Microcirculation Micrometastasis Modeling Mus Nanosphere Neoplasm Metastasis Normal Cell Normal tissue morphology Peptides Perception Physicians Population Probability Radiosurgery Reading Shapes Signal Transduction Site Specificity Staging System Technology Testing Treatment outcome Variant Width Work bioluminescence imaging cancer cell cancer type density design diagnostic accuracy effective intervention fluorescence imaging fluorescence molecular tomography human disease improved in vivo iron oxide nanoparticle overexpression radiologist receptor triple-negative invasive breast carcinoma tumor vascular bed

项目摘要

DESCRIPTION (provided by applicant): The vast majority of cancer deaths are due to metastatic disease. While effective interventions (e.g. surgery, radiation) strongly depend on our ability to detect disseminated disease at an early stage, imaging micrometastases hidden in a large population of normal cells presents a unique challenge. We seek to design a dual-ligand nanoparticle capable of 'sensing' the endothelium associated with a metastasis. By selecting two appropriate chemical specificities, a dual-ligand strategy can provide both synergistic amplification of nanoparticle targeting to micrometastases expressing both receptors but also detection of metastatic tumors expressing only one receptor that would be otherwise missed using a single-ligand strategy. Our central hypothesis is that a dual-ligand nanoparticle coupled with a vascular targeting strategy offer an increased likelihood of highly sensitive and specific recognition of micrometastasis. The nanoparticle is comprised of iron oxide nanospheres chemically linked into a linear nanochain. We hypothesize that the dual- ligand strategy will not only enhance the targeting specificity towards regions that express both receptors, but also 'capture' metastatic regions in which only one of the two receptors is predominantly expressed. Since the shape and size of nanoparticles govern their margination and attachment to the vascular bed, we also hypothesize that the aspect ratio and overall dimensions of the nanochain can be optimized, resulting in early and accurate detection of metastatic disease. We will test our hypotheses with the following Specific Aims: Specific Aim 1: Optimize the design of dual-ligand nanochains to perform vascular targeting under flow conditions of the microcirculation in vitro. We seek to optimize the design of nanochains in terms of their length, width and density of the two targeting peptides. The margination and targeting avidity of the nanochains will be evaluated in microchannel networks seeded with endothelial and cancer cells at different flow rates. Specific Aim 2: Test the ability of the dual-ligand nanochains to recognize the microenvironment of micrometastasis in the 4T1 mammary tumor model in mice. We seek to optimize the dose and timeframe for imaging by quantitatively assessing the accumulation of fluorescently labeled nanochains in metastases in vivo using fluorescence molecular tomography. Specific Aim 3: Test the accuracy of the dual-ligand nanochains to detect metastases using MRI. Nanochain- enhanced MRI will be assessed using an analysis of physician perception of metastases. In this blinded study, radiologists will read MR images of healthy and tumor-bearing animals to estimate the diagnostic accuracy. As a case study for the proposed work, detection of triple-negative breast cancer metastases in the liver and lungs was selected, because this cancer subtype is highly metastatic and deadly. However, this technology can be used for many types of cancer, since liver and lungs are common metastatic sites.

描述（由申请人提供）：绝大多数癌症死亡是由于转移性疾病造成的。虽然有效的干预措施（例如手术、放射）在很大程度上取决于我们在早期阶段检测播散性疾病的能力，但对隐藏在大量正常细胞中的微转移进行成像提出了独特的挑战。我们寻求设计一种能够“感知”与转移相关的内皮细胞的双配体纳米颗粒。通过选择两种适当的化学特异性，双配体策略既可以协同放大靶向表达两种受体的微转移的纳米颗粒，又可以检测仅表达一种受体的转移性肿瘤，否则使用单配体策略会错过这一点。我们的中心假设是，双配体纳米颗粒与血管靶向策略相结合，可以增加对微转移进行高度敏感和特异性识别的可能性。该纳米颗粒由化学连接成线性纳米链的氧化铁纳米球组成。我们假设双配体策略不仅会增强对表达两种受体的区域的靶向特异性，而且还会“捕获”仅主要表达两种受体之一的转移区域。由于纳米颗粒的形状和尺寸决定其边缘和与血管床的附着，我们还假设可以优化纳米链的长宽比和整体尺寸，从而早期准确地检测转移性疾病。我们将通过以下具体目标来检验我们的假设：具体目标1：优化双配体纳米链的设计，以在体外微循环流动条件下进行血管靶向。我们寻求在两种靶向肽的长度、宽度和密度方面优化纳米链的设计。纳米链的边缘化和靶向亲和力将在以不同流速接种内皮细胞和癌细胞的微通道网络中进行评估。具体目标2：测试双配体纳米链在小鼠4T1乳腺肿瘤模型中识别微转移微环境的能力。我们寻求通过使用荧光分子断层扫描定量评估体内转移瘤中荧光标记纳米链的积累来优化成像的剂量和时间范围。具体目标 3：测试双配体纳米链使用 MRI 检测转移的准确性。将通过分析医生对转移的感知来评估纳米链增强 MRI。在这项双盲研究中，放射科医生将读取健康动物和荷瘤动物的 MR 图像，以估计诊断准确性。作为拟议工作的案例研究，选择了检测肝脏和肺部的三阴性乳腺癌转移，因为这种癌症亚型具有高度转移性和致命性。然而，这项技术可用于多种类型的癌症，因为肝脏和肺部是常见的转移部位。