调整脂质纳米颗粒以实现 RNA 向肝外器官的递送。

Tuning Lipid Nanoparticles for RNA Delivery to Extrahepatic Organs.

机构信息

Department of Biomedical Engineering, Tufts University, Medford, MA, 02155, USA.

出版信息

Adv Mater. 2024 Nov;36(44):e2401445. doi: 10.1002/adma.202401445. Epub 2024 Sep 5.

DOI:10.1002/adma.202401445

PMID:39233550

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11530311/

Abstract

RNA therapeutics have been successfully transitioned into clinical applications. Lipid nanoparticles (LNPs) are widely employed as nonviral delivery vehicles for RNA therapeutics in commercial vaccine and gene therapy products. However, the bottleneck in expanding the clinical applications of LNP-based RNA therapeutics lies in the tendency of these nanoparticles to preferentially accumulate in the liver. This challenge underscores the need to design LNPs capable of delivering RNA to organs beyond the liver. In this perspective, recent progress is discussed in developing strategies for designing LNPs to deliver RNA to extrahepatic organs. Organ-selective targeting capability is achieved by either altering the composition of the LNP formulation or chemically modifying the ionizable lipid component. Both approaches result in changes in the physicochemical properties of the LNPs, which subsequently alters the composition of the biomolecular corona that adsorbs onto its surface following administration. The biomolecular corona is a known mechanism that mediates organ-selective LNP delivery. Furthermore, this perspective aims to provide an outlook on shaping the next-generation LNP delivery platforms. Potential efforts include targeting specific cell types, improving the safety profile of LNPs, and developing strategies to overcome physiological barriers against organ-specific delivery.

摘要

RNA 疗法已成功转化为临床应用。脂质纳米粒（LNPs）被广泛用作商业疫苗和基因治疗产品中 RNA 疗法的非病毒递送载体。然而，基于 LNP 的 RNA 疗法临床应用扩展的瓶颈在于这些纳米颗粒倾向于优先在肝脏中积累。这一挑战凸显了设计能够将 RNA 递送到肝脏以外器官的 LNP 的必要性。在这篇观点文章中，讨论了为设计能够将 RNA 递送到肝外器官的 LNP 而开发策略的最新进展。通过改变 LNP 配方的组成或化学修饰可电离脂质成分，来实现对 LNPs 的器官选择性靶向能力。这两种方法都会导致 LNPs 的物理化学性质发生变化，随后改变其表面吸附的生物分子冠的组成。生物分子冠是介导器官选择性 LNP 递送的已知机制。此外，本观点旨在展望下一代 LNP 递药平台的发展。潜在的努力包括靶向特定细胞类型、提高 LNPs 的安全性、开发克服针对特定器官递送的生理障碍的策略。

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