Next-Generation Quantum Dots for Molecular and Cellular Imaging of Cancer

用于癌症分子和细胞成像的下一代量子点

基本信息

批准号：
8137827
负责人：
Andrew Michael Smith
金额：
$ 8.83万
依托单位：
EMORY UNIVERSITY
依托单位国家：
美国
项目类别：
财政年份：
2010
资助国家：
美国
起止时间：
2010-09-03 至 2012-07-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/8137827
关键词：
Active Biological Transport Adsorption Alloys Antibodies Artificial nanoparticles Award Behavior Binding Biological Biotin Blood Blood Circulation Cancer Biology Caveolae Cells Chemicals Chemistry Color Complex Crowding Data Development Diffusion Drug Delivery Systems Drug Formulations Electronics Engineering Ensure Environment Exhibits Fluorescence Fluorescent Dyes Fluorescent Probes Generations Goals Histidine Human Image Interdisciplinary Study Lead Length Ligands Malignant Neoplasms Mechanics Mediating Medicine Mentors Metals Microscopic Microscopy Modeling Nanotechnology Neoplasms in Vascular Tissue Optics Penetration Peptides Pharmaceutical Preparations Pharmacotherapy Phase Postdoctoral Fellow Process Property Proteins Pump Quantum Dots Recombinant Proteins Research Research Institute Research Personnel Research Project Grants Research Proposals Resistance Semiconductors Series Serum Proteins Site Solid Neoplasm Streptavidin Surface Surface Properties System Techniques Technology Therapeutic Time Tissues Training Transport Process Treatment Efficacy Universities Work aerobic respiration control protein base cancer imaging clinical application clinically significant design improved in vivo interstitial intravital microscopy macromolecule malignant breast neoplasm molecular/cellular imaging nanocrystal nanoparticle next generation novel particle protein aminoacid sequence public health relevance quantum research study self assembly single molecule surface coating targeted delivery transcytosis tumor uptake

项目摘要

DESCRIPTION (provided by applicant): The aim of this research proposal is to develop a new class of fluorescent nanoparticles for highly sensitive and multicolor imaging of the tumor microenvironment in vivo toward understanding and improving nanoparticle drug delivery. We will focus on semiconductor quantum dots (QDs), which are nanocrystals that exhibit bright fluorescence and unique optical and electronic properties. We have recently designed a new class of quantum dots called 'alloyed quantum wells,' which have equalized fluorescence brightness across a broad spectrum of colors. This novel property is not available from organic dyes, fluorescent proteins, or conventional quantum dots, and will enable quantitative studies of nanoparticle drug delivery to solid tumors. The basic idea is that we can modify the size, surface chemistry, or targeting ligands on these multicolor probes to model nanoparticle drug formulations, which can then be quantitatively compared for uptake and penetration in solid tumors. Because these particles are immensely bright on the single molecule level, intravital microscopy of solid tumors will allow a single-molecule, mechanistic understanding of the rate-limiting steps of drug delivery in a multicolor fashion. This simultaneous multicolor approach is critical for comparisons in the heterogeneous tumor microenvironment, and is not possible with conventional optical probes. In this proposal, we will optically engineer these nanoparticles, develop inert surface coatings for compact sizes and long circulation times in blood, and develop new high-precision bioconjugation strategies based on self-assembly principles. We will use these new probes to image the microscopic processes of targeted-delivery to tumors, concentrating on caveolae-mediated transcytosis, an active transport process that has recently been shown to efficiently pump nanoparticles from the tumor blood vessels into the interstitial tissue. These studies will implement highly relevant orthotopic models of human breast cancer that will ensure clinical significance of the findings. During the mentored phase of this award, the candidate will be co-mentored by Dr. Shuming Nie of Emory University and Dr. Jan Schnitzer of the Proteogenomic Research Institute for Systems Medicine, and will be trained in the use of orthotopic models of human cancer, intravital microscopy techniques, and antibody-based tumor targeting strategies. Both of these mentors are leaders in their respective fields of nanotechnology and cancer biology, which will enable a convergence of expertise to guide this interdisciplinary research project and to facility the transition of the candidate from a mentored postdoctoral fellow to an independent investigator in an academic setting. PUBLIC HEALTH RELEVANCE: Nanoparticle-based drugs are a promising therapeutic approach for cancer, however our ability to rationally and optimally design these particles is currently limited by a poor understanding of their behavior in tumors. In this proposal, we will develop a new class of fluorescent nanoparticle probes that will enable highly sensitive, quantitative, single-molecule imaging and tracking of nanoparticles in cancer tissue. We will use these probes to understand the mechanisms of targeted nanoparticle delivery to tumors to inform design parameters that will enhance tumor uptake and therapeutic efficacy.

描述（由申请人提供）：本研究计划的目的是开发一类新型荧光纳米颗粒，用于体内肿瘤微环境的高灵敏度和多色成像，以了解和改善纳米颗粒药物输送。我们将重点关注半导体量子点（QD），它是一种纳米晶体，具有明亮的荧光和独特的光学和电子特性。我们最近设计了一种称为“合金量子阱”的新型量子点，它可以在广泛的颜色范围内均衡荧光亮度。这种新颖的特性是有机染料、荧光蛋白或传统量子点所不具备的，它将使得纳米粒子药物递送至实体瘤的定量研究成为可能。基本思想是，我们可以修改这些多色探针的尺寸、表面化学或靶向配体来模拟纳米颗粒药物配方，然后可以定量比较实体瘤中的摄取和渗透。由于这些颗粒在单分子水平上非常明亮，因此实体瘤的活体显微镜检查将允许以多色方式对药物输送的限速步骤进行单分子机械理解。这种同步多色方法对于异质肿瘤微环境中的比较至关重要，并且传统光学探针无法实现。在该提案中，我们将对这些纳米颗粒进行光学工程设计，开发尺寸紧凑、血液循环时间长的惰性表面涂层，并开发基于自组装原理的新型高精度生物共轭策略。我们将使用这些新探针对肿瘤靶向递送的微观过程进行成像，重点关注小凹介导的转胞吞作用，这是一种主动运输过程，最近被证明可以有效地将纳米粒子从肿瘤血管泵入间质组织。这些研究将实施高度相关的人类乳腺癌原位模型，以确保研究结果的临床意义。在该奖项的指导阶段，候选人将由埃默里大学的Shuming Nie博士和系统医学蛋白质基因组研究所的Jan Schnitzer博士共同指导，并将接受人类癌症原位模型使用的培训、活体显微镜技术和基于抗体的肿瘤靶向策略。这两位导师都是各自纳米技术和癌症生物学领域的领导者，这将使专业知识的融合能够指导这个跨学科研究项目，并帮助候选人从受指导的博士后研究员过渡到学术环境中的独立研究者。公共健康相关性：基于纳米颗粒的药物是一种有前途的癌症治疗方法，但目前我们对这些颗粒在肿瘤中的行为了解甚少，因此限制了我们合理、优化设计这些颗粒的能力。在这项提案中，我们将开发一类新型荧光纳米颗粒探针，该探针将能够对癌症组织中的纳米颗粒进行高灵敏度、定量、单分子成像和跟踪。我们将使用这些探针来了解靶向纳米颗粒递送至肿瘤的机制，以告知设计参数，从而增强肿瘤的摄取和治疗效果。