Engineering Polymers For Gene Therapy of Head Cancer

用于头部癌症基因治疗的工程聚合物

基本信息

批准号：
7228061
负责人：
PETER W SWAAN
金额：
$ 27.81万
依托单位：
UNIVERSITY OF MARYLAND BALTIMORE
依托单位国家：
美国
项目类别：
财政年份：
2005
资助国家：
美国
起止时间：
2005-05-01 至 2008-04-30
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/7228061
关键词：
Address Adenovirus Vector Adenoviruses Amino Acids Arts Biocompatible Biocompatible Materials Biodistribution Biology Body Temperature Class Commit Condition Coupled Development Disease Dose Drug Controls Drug Delivery Systems Elastin Engineering Family Future Gene Delivery Gene Transduction Agent Gene Transfer Genes Genetic Engineering Goals Green Fluorescent Proteins Head Cancer Head and Neck Cancer Head and Neck Squamous Cell Carcinoma Head and neck structure Hydrogels Implant In Vitro Injection of therapeutic agent Invasive Ionic Strengths Length Liquid substance Localized Malignant Neoplasms Mediating Modeling Molecular Weight Nude Mice Oncogenes Operative Surgical Procedures Oral cavity Organic solvent product Oropharyngeal Pharyngeal Neoplasms Phase Physiological Polymers Property Proteins Purpose Radiation therapy Recombinants Research Research Personnel Resources Silk Site Solvents Squamous cell carcinoma Structure Swelling System Techniques Temperature Therapeutic Time Toxic effect Treatment Efficacy Treatment outcome Tumor Suppressor Genes Virus Week Xenograft Model adenoviral-mediated analog chemotherapy copolymer design desire gene therapy improved in vitro Model in vivo innovation killings monomer neoplastic cell novel particle plasmid DNA programs transduction efficiency transgene expression tumor tumor xenograft vector

项目摘要

DESCRIPTION (provided by applicant): The long-term goal of this research is to engineer polymeric delivery systems that improve the efficacy and reduce the toxicity of head and neck cancer gene therapy. The purpose of this project is to engineer silk-elastinlike polymeric (SELP) matrices for minimally invasive controlled delivery of adenovirus constructs carrying the RB94 tumor suppressor gene (Ad-RB94). The rationale is that by genetic engineering of SELPs, it is possible to tailor-make delivery systems that are liquid at room temperature, mixed under mild conditions with adenoviral tumor suppressor gene therapy vectors, form vector-laden hydrogels at body temperature after a single intratumoral injection, release viable vectors at the site of tumor over a desired period of time, and kill the tumor cells with minimum systemic toxicity and maximum efficacy. The following Specific Aims will be addressed: 1) To synthesize and characterize SELP hydrogels for localized and controlled adenoviral gene delivery. Linear SELP copolymer analogs containing silk-like and elastin-like repeating units with various sequences and lengths will be biosynthesized and characterized using recombinant techniques. Hydrogels will be formed from the linear polymers. The degree of swelling of the hydrogels will be examined as a function of polymer structure and initial polymer concentration at physiological temperature, pH, and ionic strength. 2) To examine the influence of polymer and adenoviral composition on the degree of swelling, adenoviral particle release and bioactivity in vitro. Model adenoviruses will be incorporated in the hydrogels. The degree of swelling will be evaluated in the presence of adenoviral particles. The amount released will be evaluated over time as a function of polymer structure and concentration. Release will be correlated with the bioactivity of the particles in relevant in vitro models. From the results of model adenoviral release and in vitro gene transfer, appropriate polymer and Ad-RB94 compositions will be used to examine the bioactivity of the released therapeutic tumor suppressor gene. 3) To evaluate the influence of polymer composition on transduction efficiency, duration of transgene expression, biodistribution, therapeutic efficacy, and toxicity of adenoviral-containing SELP hydrogels in vivo. A nude mouse tumor xenograft model of head and neck cancer will be used to evaluate these parameters by intratumoral administration of SELP hydrogels containing Ad-GFP (Adenoviruses containing green fluorescent protein gene as markers of gene transfer) and Ad-RB94. In the future phases, the proposed matrix-mediated adenoviral .gene therapy approach using genetically engineered polymers can be used for the development of clinically acceptable systems for gene therapy of head and neck cancer.

描述（由申请人提供）：这项研究的长期目标是设计聚合物递送系统，以提高头颈癌基因治疗的功效并降低毒性。该项目的目的是设计丝弹性蛋白样聚合物 (SELP) 基质，用于微创控制递送携带 RB94 肿瘤抑制基因 (Ad-RB94) 的腺病毒构建体。基本原理是，通过SELP的基因工程，可以定制在室温下为液体的递送系统，在温和条件下与腺病毒肿瘤抑制基因治疗载体混合，在单次瘤内注射后在体温下形成载有载体的水凝胶注射，在所需的时间内在肿瘤部位释放活载体，并以最小的全身毒性和最大的功效杀死肿瘤细胞。将解决以下具体目标：1）合成和表征用于局部和受控腺病毒基因传递的 SELP 水凝胶。含有各种序列和长度的丝状和弹性蛋白状重复单元的线性 SELP 共聚物类似物将使用重组技术进行生物合成和表征。水凝胶将由线性聚合物形成。将检查水凝胶的溶胀程度作为聚合物结构和生理温度下初始聚合物浓度、pH 和离子强度的函数。 2)考察聚合物和腺病毒组合物对体外溶胀程度、腺病毒颗粒释放和生物活性的影响。模型腺病毒将被纳入水凝胶中。将在腺病毒颗粒存在的情况下评估肿胀程度。释放量将随着时间的推移作为聚合物结构和浓度的函数进行评估。释放将与相关体外模型中颗粒的生物活性相关。根据模型腺病毒释放和体外基因转移的结果，将使用适当的聚合物和Ad-RB94组合物来检查所释放的治疗性肿瘤抑制基因的生物活性。 3) 评估聚合物成分对含腺病毒SELP水凝胶体内转导效率、转基因表达持续时间、生物分布、治疗效果和毒性的影响。将使用头颈癌裸鼠肿瘤异种移植模型，通过瘤内施用含有 Ad-GFP（含有绿色荧光蛋白基因作为基因转移标记的腺病毒）和 Ad-RB94 的 SELP 水凝胶来评估这些参数。在未来阶段，所提出的使用基因工程聚合物的基质介导的腺病毒基因治疗方法可用于开发临床可接受的头颈癌基因治疗系统。