Bak Annette, Zhou Liping, Rejman Joanna, Yanez Arteta Marianna, Nilsson Gunilla, Ashford Marianne
Advanced Drug Delivery, Pharmaceutical Sciences, R&D, AstraZeneca, Boston, MA, USA.
Advanced Drug Delivery, Pharmaceutical Sciences, R&D, AstraZeneca, Gothenburg, Sweden.
Expert Opin Drug Deliv. 2025 Feb;22(2):239-254. doi: 10.1080/17425247.2025.2452295. Epub 2025 Feb 15.
mRNA therapeutics were a niche area in drug development before COVID vaccines. They are now used in vaccine development, for non-viral therapeutic genome editing, chimeric antigen receptor T (CAR T) cell therapies and protein replacement. mRNA is large, charged, and easily degraded by nucleases. It cannot get into cells, escape the endosome, and be translated to a disease-modifying protein without a delivery system such as lipid nanoparticles (LNPs).
This article covers how to design, select, and develop an LNP for therapeutic genome editing in the liver. The roadmap is divided into selecting the right LNP for discovery via a design, make, test, and analyze cycle (DMTA). The design elements are focused on ionizable lipids in a 4-component LNP, and insights are provided for how to set an and testing strategy. The second section focuses on transforming the LNP into a clinical drug product and covers formulation, analytical development, and process optimization, with brief notes on supply and regulator strategies.
The perspective discusses the impact that academic-industry collaborations can have on developing new medicines for therapeutic genome editing in the liver. From the cited collaborations an enhanced understanding of intracellular trafficking, notably endosomal escape, and the internal structure of LNPs were attained and are deemed key to designing effective and safe LNPs. The knowledge gained will also enable additional assays and structural activity relationships, which would lead to the design of the next-generation delivery systems for nucleic acid therapies.
在新冠疫苗出现之前,信使核糖核酸(mRNA)疗法在药物研发领域是一个小众领域。如今,它被用于疫苗研发、非病毒治疗性基因组编辑、嵌合抗原受体T(CAR T)细胞疗法以及蛋白质替代疗法。mRNA体积大、带电荷,且容易被核酸酶降解。如果没有脂质纳米颗粒(LNP)等递送系统,它无法进入细胞、逃离内体并被翻译成具有疾病修饰作用的蛋白质。
本文介绍了如何设计、选择和开发用于肝脏治疗性基因组编辑的LNP。路线图分为通过设计、制造、测试和分析循环(DMTA)为发现选择合适的LNP。设计要素聚焦于四组分LNP中的可电离脂质,并提供了如何制定筛选和测试策略的见解。第二部分重点介绍将LNP转化为临床药品,涵盖制剂、分析方法开发和工艺优化,并简要介绍供应和监管策略。
该观点讨论了产学研合作对开发肝脏治疗性基因组编辑新药可能产生的影响。通过引用的合作,对细胞内运输,特别是内体逃逸以及LNP的内部结构有了更深入的了解,这些被认为是设计有效和安全LNP的关键。所获得的知识还将有助于开展更多的分析以及建立构效关系,从而推动下一代核酸治疗递送系统的设计。
