Development of active loading technologies for encapsulating highly charged molecules into liposomes

开发将高电荷分子封装到脂质体中的主动装载技术

• 批准号: RGPIN-2017-03787
• 负责人: Li, ShyhDar
• 金额: $ 2.04万
• 依托单位: University of British Columbia
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2018
• 资助国家: 加拿大
• 起止时间: 2018-01-01 至 2019-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=657504
• 关键词: Development; active; loading; technologies; encapsulating

Over the next 5 years I will focus on developing new active loading technologies to encapsulate highly charged molecules into liposomes to improve their delivery. I will focus on three types of highly charged drugs: positively charged small molecules, negatively charged small molecules and negatively charged macromolecules. I will select one model drug from each class and develop a new active loading technology for each. Hypothesis: An ion-pairing agent will neutralize the charge of a compound to increase its membrane permeability and drive the loading into liposomes.******Obj 1: Develop an active loading method to encapsulate a positively charged small molecule into liposomes. Our model drug is gentamicin (GEN) that has 5 positively charged amino groups. We will develop and optimize a new loading method to prepare liposomal GEN, and will compare its pharmacokinetics (PK) in mice with free GEN and liposomal GEN prepared with passive loading.******Obj 2: Develop an active loading method to encapsulate a negatively charged small molecule into liposomes. Our model drug is clodronate (CLO) that has 2 negatively charged phosphate groups. Liposomal CLO is used to deplete tissue macrophages in animals to generate research models. We will develop and optimize a new loading technology to prepare liposomal CLO, and will compare its macrophage depleting activity in mice with free CLO and liposomal CLO prepared with passive loading. ******Obj 3: Develop an active loading method to encapsulate a negatively charged macromolecule into liposomes. Our model drug is small interfering ribonucleic acid (siRNA) used to study gene function. We will develop an ion-pairing active loading method to fabricate liposomal siRNA. We will assess the interaction of the liposomal siRNA with blood components and cells and its biodistribution (BD) in tumor-bearing mice, and compare with free siRNA and cationic liposome-siRNA complex.******Short term goal: Develop active loading technologies to encapsulate GEN, CLO and siRNA into liposomes to improve their delivery. Long term goal: Develop a platform technology to load various types of highly charged drugs into liposomes to improve their PK and BD for increased bioavailability, with potential to create effective in vivo research tools or pharmaceutical products. This program will offer comprehensive training for HQP, including pharmaceutical formulation design, fabrication and characterization, in vitro cell based and molecular assays and in vivo PK/BD studies. These knowledge and skills are highly sought after in academia and industry in the pharmaceutical area, and HQP trained in my program have been highly competitive for these skilled jobs. I have published >25 papers and patents with liposomal technologies and licensed 2 technologies to industry with 2 products in clinical trials. This program will yield new liposomal engineering technologies with high commercialization values.**

在接下来的5年里，我将专注于开发新的主动负载技术，将高电荷分子封装到脂质体中，以改善它们的输送。我将重点介绍三种高电荷药物：带正电的小分子，带负电的小分子和带负电的大分子。我将从每一类药物中选择一种模型药物，并为每种药物开发一种新的主动加载技术。假设：离子配对剂将中和化合物的电荷，以增加其膜的渗透性，并将负载驱动到脂质体中。******目的1：开发一种主动负载方法，将带正电的小分子包封到脂质体中。我们的模型药物是庆大霉素（GEN），它有5个带正电的氨基。我们将开发和优化一种新的装药方法制备GEN脂质体，并比较其在小鼠体内的药代动力学（PK）。******目标2：开发一种主动负载方法，将带负电荷的小分子封装到脂质体中。我们的模型药物是氯膦酸盐（CLO），它有两个带负电荷的磷酸基团。利用脂质体CLO消耗动物组织巨噬细胞生成研究模型。我们将开发并优化一种新的负载技术制备CLO脂质体，并比较游离CLO和被动负载制备的CLO脂质体在小鼠体内的巨噬细胞消耗活性。******目的3：开发一种主动负载方法，将带负电荷的大分子包封到脂质体中。我们的模型药物是小干扰核糖核酸（siRNA），用于研究基因功能。我们将开发一种离子配对主动负载方法来制备脂质体siRNA。我们将评估脂质体siRNA与血液成分和细胞的相互作用及其在荷瘤小鼠中的生物分布（BD），并与游离siRNA和阳离子脂质体siRNA复合物进行比较。******短期目标：开发主动负载技术，将GEN， CLO和siRNA封装到脂质体中，以改善其递送。长期目标：开发一种平台技术，将各种类型的高电荷药物装载到脂质体中，以提高其PK和BD，从而提高生物利用度，有可能创造有效的体内研究工具或药物产品。该项目将为HQP提供全面的培训，包括药物配方设计、制造和表征、体外细胞和分子分析以及体内PK/BD研究。这些知识和技能在制药领域的学术界和工业界都受到高度追捧，在我的项目中培训的HQP在这些技术岗位上具有很强的竞争力。我发表了25篇关于脂质体技术的论文和专利，并授权2项技术进入行业，2项产品处于临床试验阶段。本项目将产生具有较高商业化价值的新型脂质体工程技术