Albumin-Encapsulated Rare Earth Nanoprobes for Multifunctional Tissue Imaging

用于多功能组织成像的白蛋白封装稀土纳米探针

• 批准号: 8285398
• 负责人: PRABHAS V MOGHE
• 金额: $ 19.07万
• 依托单位: RUTGERS, THE STATE UNIV OF N.J.
• 依托单位国家: 美国
• 财政年份: 2012
• 资助国家: 美国
• 起止时间: 2012-04-01 至 2014-03-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8285398
• 关键词: Acute; Address; Affect; Albumins; Animals; Arterial Fatty Streak; Atherosclerosis; Behavior; Biodistribution; Biological; Biological Availability; Biophotonics; Cardiovascular Diseases; Cardiovascular system; Ceramics; Chemistry; Communicable Diseases; Complex; Coupled; Detection; Development; Diagnostic; Disease; Disorder by Site; Disseminated Malignant Neoplasm; Drug Formulations; Early Diagnosis; Encapsulated; Engineering; Family; Figs - dietary; Fluorescence; Foundations; Growth; Health Care Costs; Healthcare; Human; Image; Lead; Length; Lesion; Libraries; Life; Light; Malignant Neoplasms; Mass Spectrum Analysis; Medicine; Metastatic Melanoma; Methods; Modeling; Molecular; Molecular Target; Monitor; Mus; Nanotechnology; Nature; Neoplasm Metastasis; Nerve Degeneration; Optics; Outcome; Pathogenesis; Pathology; Penetration; Pharmaceutical Preparations; Phenotype; Photons; Property; Proteins; Quantum Dots; Rare Earth Metals; Relative (related person); Reporting; Resolution; Role; Serum Albumin; Societies; Structure; System; Technology; Thick; Time; Tissues; absorption; aqueous; base; bioimaging; biomaterial compatibility; cancer imaging; cardiovascular imaging; clinical application; cost; cytotoxicity; design; disease phenotype; fluorophore; frontier; improved; in vivo; innovation; insight; interest; intravenous administration; melanoma; molecular phenotype; mortality; nanobiotechnology; nanoparticle; nanoprobe; nanoscale; nanoshell; neuroimaging; novel; optical imaging; particle; plaque lesion; pre-clinical; progression marker; research clinical testing; theranostics; tool; tumor

DESCRIPTION (provided by applicant): Complex disease states such as metastatic cancers and acute atherosclerosis take a staggering toll on society in terms of mortality and health care costs. Current approaches to discriminate these pathologies are limited by their invasive nature, costs, and inability to target molecular features of the pathologies using real-time tracking methods. This exploratory R21 study is based on an innovative nanoscale concept to resolve and monitor tissue pathology using molecularly targeted optical imaging nanoprobes that emit infrared light. Infrared light is attractive because can be easily transmitted through thick biological tissues. Our nanoprobes consist of rare earth doped ceramic nanoparticles, which brightly emit infrared light in a novel window of emission. These particles are encapsulated with albumin nanoshells to impart cytocompatibility and aqueous dispersion and the albumin is conjugated with markers to target the disease of interest. The project proposes to develop a repertoire of rare earth-doped nanoparticles encapsulated in functionalized albumin nanoshells to establish nanoprobes with high biological availability in vivo, improved biocompatibility, and functional targeting to disease targets. A particularly innovative endpoint proposed is that of tracking disease phenotype progression through the in vivo imaging of intravenously injected cocktail of nanoprobes emitting across different infrared wavelengths and functionalized to four different markers of disease phenotypes. Two specific aims are proposed. In Aim 1, the project will investigate the role of nanoscale size and biofunctionalization of the rare earth nanoprobes on the biodistribution and accumulation at disease sites using a murine metastatic melanoma model. The in vivo distribution will be examined using infrared imaging of living animals and compared against conventional tissue profiles using high resolution inductively coupled mass spectrometry. Thus, optimal formulations of nanoprobes for in vivo imaging will be established. In Aim 2, the nanoprobe rare earth doped nanoparticles will be tailored to emit at different wavelengths and thus create a family of multi-chromatic nanoparticles. These will be functionalized to report simultaneously on four key markers for growth, invasiveness, and metastatic potential of tumors . The relative accumulation of the multiplexed nanoprobes will be used to track the progression/stabilization of tumors following established drug treatment. This will serve as a proof of concept for the foundations of this R21 project, and be the basis for developing this nanotechnology for a broader range of disease states of varying molecular phenotypes. PUBLIC HEALTH RELEVANCE: This project is concerned with the design of novel nanoscale probes based on biologically compatible rare earth-phosphors for optical imaging of biological tissues at near infrared wavelengths, which allows deeper penetration and real-time detection of pathologies. Outcomes will be insights into the role of size and biodistribution of the nanoprobes in vivo; design of multicolor emitting phosphors for identification of different molecular features of pathologies, and feasibility of molecular targeting to rapidly evolving disease states such as metastatic tumors. The overall health care applications are in diagnostic and multifunctional imaging of cardiovascular lesions/plaques, cancers, neurodegeneration, and infectious diseases.

描述（由申请人提供）：复杂的疾病状态，如转移性癌症和急性动脉粥样硬化，在死亡率和医疗保健费用方面对社会造成惊人的损失。目前区分这些病理的方法受到其侵入性、成本和无法使用实时跟踪方法靶向病理的分子特征的限制。这项探索性的R21研究基于一种创新的纳米概念，使用发射红外光的分子靶向光学成像纳米探针来解决和监测组织病理学。红外线很有吸引力，因为它可以很容易地透过厚厚的生物组织。我们的纳米探针由稀土掺杂的陶瓷纳米颗粒组成，它在一个新的发射窗口中发出明亮的红外光。这些颗粒用白蛋白纳米壳包封以赋予细胞相容性和水分散体，并且白蛋白与标记物缀合以靶向感兴趣的疾病。该项目提出开发一种封装在功能化白蛋白纳米壳中的稀土掺杂纳米颗粒，以建立具有高生物利用度的体内纳米探针，改善生物相容性，并功能性靶向疾病靶标。提出的一个特别创新的终点是通过静脉注射的纳米探针混合物的体内成像来跟踪疾病表型进展，所述纳米探针发射不同的红外波长并功能化为疾病表型的四种不同标志物。提出了两个具体目标。在目标1中，该项目将使用小鼠转移性黑色素瘤模型研究稀土纳米探针的纳米尺寸和生物功能化对疾病部位的生物分布和积累的作用。将使用活体动物的红外成像检查体内分布，并使用高分辨率电感耦合质谱法与传统组织图谱进行比较。因此，将建立用于体内成像的纳米探针的最佳制剂。在目标2中，纳米探针稀土掺杂纳米颗粒将被定制为在不同波长下发射，从而创建多色纳米颗粒家族。这些将被功能化，以同时报告肿瘤生长，侵袭性和转移潜力的四个关键标志物。多重纳米探针的相对累积将用于跟踪在确定的药物治疗后肿瘤的进展/稳定。这将作为R21项目基础的概念验证，并成为开发这种纳米技术用于更广泛的不同分子表型疾病状态的基础。 公共卫生相关性：该项目涉及基于生物相容性稀土磷光体的新型纳米级探针的设计，用于在近红外波长下对生物组织进行光学成像，从而实现更深的穿透和实时检测病理。结果将是深入了解体内纳米探针的大小和生物分布的作用;设计用于识别不同分子特征的发光磷光体 的病理学，以及分子靶向快速发展的疾病状态，如转移性肿瘤的可行性。整体医疗保健应用是心血管病变/斑块、癌症、神经变性和传染病的诊断和多功能成像。