Multifunctional PEG Hydrogel Nano/Microparticles for Targeted Treatment of NSCLC

多功能PEG水凝胶纳米/微粒靶向治疗NSCLC

基本信息

批准号：
8025743
负责人：
Patrick J. Sinko
金额：
$ 38.72万
依托单位：
RUTGERS, THE STATE UNIV OF N.J.
依托单位国家：
美国
项目类别：
财政年份：
2011
资助国家：
美国
起止时间：
2011-01-01 至 2015-12-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/8025743
关键词：
Accounting Adherence Adverse effects Affinity Antineoplastic Agents Apoptosis Apoptotic Binding Breathing CXCL12 gene CXCR4 gene Camptothecin Cancer Etiology Cancer Patient Caring Caspase Cell Surface Receptors Cell surface Cessation of life Data Development Diagnosis Diffuse Disease Dose Doxycycline Drug Delivery Systems Engineering Evaluation Filtration Gel Gelatinase B Goals Hydrogels Inflammation Inflammatory Injectable Life Ligands Lung Lung Neoplasms Malignant neoplasm of lung Metastatic Lesion Mus NF-kappa B Neoplasm Metastasis Non-Small-Cell Lung Carcinoma Paclitaxel Pathway interactions Patients Pattern Peptide Fragments Pharmaceutical Preparations Pharmacodynamics Platinum Prevention Process Research Resistance Respiratory physiology Series Signal Transduction Solubility Specificity Staging Structure Surface System Thioctic Acid Time Tissues Toxic effect United States Viral Woman absorption cancer cell chemokine chemotherapeutic agent chemotherapy cytotoxic design improved macrophage men migration mouse model nano nanoparticle natural flow neoplastic cell novel outcome forecast programs receptor binding residence targeted delivery vMIP-II

项目摘要

DESCRIPTION (provided by applicant): The long-term goal of the proposed research program is to develop an intravenously (IV) administered lung- targeted nanoparticle (NP)/gel microparticle (GMP) delivery system for the treatment of non-small cell lung cancer (NSCLC). After the initial diagnosis, greater than half of the patients with localized lung cancer survive at least 5 years suggesting a benefit to an approach that limits metastatic spread from the primary lung cancer. While targeting is an effective approach for improving drug concentrations and minimizing side effects, the options for lung targeting are narrow. Thus, targeted lung delivery approaches for treating NSCLC are urgently needed. Two levels of targeting are proposed. The first is passive targeting. GMPs selectively accumulate in the lung after IV administration. Our compelling preliminary data demonstrates that passive targeting achieves a 10-fold increase in anti-cancer drug potency and 10-fold lower peak systemic drug concentrations. The second is active targeting. Two types of NPs are proposed to achieve active targeting. Using a novel fabrication process, high drug loading into NPs is achieved that overcomes the solubility limitations of hydrophobic cancer drugs. The NP surfaces are functionalized with ligands that selectively target cancer cells. The second NP group is also functionalized with cell surface ligands, however, instead of delivering drug cargo selectively inside the cancer cell, these NPs are engineered to tightly bind to cancer cell surface receptors and remain there in order to inhibit the metastatic signaling cascade. Once the GMPs passively accumulate in the lung, the NPs imbedded in the GMP diffuse out and seek cancer cells resulting in an extraordinary degree of targeting specificity. Three specific aims are proposed: AIM 1: Engineer and evaluate a series of GMPs to achieve (a) optimal passive lung targeting efficiency, retention and elimination and (b) minimal pulmonary toxicity (structural and functional alterations and inflammation) in normal mice and in an orthotropic mouse model of lung cancer. AIM 2: Design, fabricate, and assess NPs and GMPs that enhance the pro-apoptotic effect of camptothecin (CPT). Actively targeted NPs will be developed that specifically deliver CPT and alpha lipoic acid (ALA) to lung cancer cells to exploit synergy in tumor cell apoptosis induced by these two chemotherapeutic agents. AIM 3: Design, fabricate, and assess CXCR4/7-targeted NPs and GMPs that reduce the occurrence of metastasis. Two active targeting approaches will be investigated: (1) direct CXCR4/7 receptor binding and (2) inhibition of downstream pro-metastatic signaling factors NF-kB, ERK and/or MMP-9. If successful, an injectable lung targeted drug delivery system will be produced that: (1) utilizes passive targeting to exploit the natural flow-filtration pattern of the lung to achieve high local and minimal systemic drug concentrations; (2) exploits synergy in chemotherapy-induced tumor cell apoptosis and active targeting to reduce the required effective drug and MP doses; and (3) utilizes active targeting to reduce the occurrence of metastatic lesions by interfering with the CXCR4/7 - CXCL12 chemokine pathway. PUBLIC HEALTH RELEVANCE: Lung cancer is currently the leading cause of cancer deaths in both men and women in the United States and Non-Small Cell Lung Cancer (NSCLC) accounts for the vast majority of lung cancer cases. There is a pressing need to develop new treatment approaches for this highly fatal disease. This project involves the development and evaluation of a novel targeted delivery system (injected intravenously) that uses nanoparticles imbedded into microparticles to deliver chemotherapeutic drugs and other agents specifically to the lungs of patients in order to treat NSCLC and reduce therapy-limiting side effects.

描述（由申请人提供）：拟议研究计划的长期目标是开发一种静脉（IV）给药的肺靶向纳米颗粒（NP）/凝胶微粒（GMP）递送系统，用于治疗非小细胞肺癌症（非小细胞肺癌）。初步诊断后，超过一半的局限性肺癌患者存活至少 5 年，这表明限制原发性肺癌转移扩散的方法是有益的。虽然靶向是提高药物浓度和最大限度减少副作用的有效方法，但肺部靶向的选择范围很窄。因此，迫切需要用于治疗 NSCLC 的靶向肺递送方法。提出了两个级别的目标定位。第一个是被动瞄准。静脉注射后，GMP 选择性地积聚在肺部。我们令人信服的初步数据表明，被动靶向可将抗癌药物效力提高 10 倍，并将全身药物峰值浓度降低 10 倍。二是主动瞄准。提出了两种类型的纳米粒子来实现主动靶向。使用新颖的制造工艺，实现了纳米颗粒的高载药量，克服了疏水性癌症药物的溶解度限制。纳米粒子表面用选择性靶向癌细胞的配体进行功能化。第二个 NP 基团也通过细胞表面配体进行功能化，然而，这些 NP 不是在癌细胞内选择性地递送药物，而是被设计为与癌细胞表面受体紧密结合并保留在那里，以抑制转移信号级联。一旦 GMP 在肺部被动积累，嵌入 GMP 中的 NP 就会扩散出去并寻找癌细胞，从而产生非凡的靶向特异性。提出了三个具体目标： AIM 1：设计和评估一系列 GMP，以在正常小鼠和小鼠中实现 (a) 最佳被动肺靶向效率、保留和消除，以及 (b) 最小肺毒性（结构和功能改变以及炎症）肺癌正交各向异性小鼠模型。目标 2：设计、制造和评估增强喜树碱 (CPT) 促凋亡作用的 NP 和 GMP。将开发主动靶向纳米粒子，将 CPT 和 α 硫辛酸 (ALA) 特异性递送至肺癌细胞，以利用这两种化疗药物诱导的肿瘤细胞凋亡的协同作用。目标 3：设计、制造和评估可减少转移发生的 CXCR4/7 靶向 NP 和 GMP。将研究两种主动靶向方法：(1) 直接结合 CXCR4/7 受体；(2) 抑制下游促转移信号因子 NF-kB、ERK 和/或 MMP-9。如果成功，将生产出一种可注射的肺部靶向药物递送系统，该系统：（1）利用被动靶向来利用肺部的自然流动过滤模式，以实现较高的局部药物浓度和最低的全身药物浓度； (2)利用化疗诱导的肿瘤细胞凋亡和主动靶向的协同作用，减少所需的有效药物和MP剂量； (3)利用主动靶向，通过干扰CXCR4/7-CXCL12趋化因子途径来减少转移病灶的发生。公共卫生相关性：目前，肺癌是美国男性和女性癌症死亡的主要原因，而非小细胞肺癌 (NSCLC) 占肺癌病例的绝大多数。迫切需要为这种高度致命的疾病开发新的治疗方法。该项目涉及开发和评估一种新型靶向输送系统（静脉注射），该系统使用嵌入微粒中的纳米颗粒将化疗药物和其他药物专门输送到患者的肺部，以治疗非小细胞肺癌并减少限制治疗的副作用。