Specific quantification of intact lipid nanocapsules in rats using FRET: biodistribution and PBPK model development.

Nanomedicine (London, England) Pub Date : 2025-05-01 Epub Date: 2025-04-24 DOI:10.1080/17435889.2025.2492537

Rana Elfatairi, Jessica Ou, Vincent Lebreton, Mariam Mahdjoub, Norraseth Kaeokhamloed, Jérôme Bejaud, Grégory Hilairet, Florence Gattacceca, Emilie Roger, Samuel Legeay

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Abstract

Aims: One major challenge is to quantify intact nanoparticles specifically to understand the pharmacokinetics (PK) of nanomedicines. Lipid nanocapsules (LNC) carrying Förster resonance energy transfer (FRET) trackers have been previously developed, and a quantification method has been applied in blood samples.

Materials & method: A quantification method in liver, spleen, and lungs was developed, and the biodistribution of intact FRET-LNC of 50 nm (FRET-LNC-50) in rats after intravenous injection was performed.

Results: FRET-LNC-50 were extracted from organs using a newly developed extraction method, allowing their integrity preservation and quantification. This method allowed the assessment of the biodistribution study of intact LNC. A non-compartmental PK analysis was performed to calculate PK parameters. The most exposed organ was the liver, with a longer half-life than blood and other organs. The availability of specific biodistribution data allowed the development of the first physiologically based PK (PBPK) model, which represents an ideal platform to further aggregate biodistribution data from various nanoparticle types and to bring insight into PK mechanisms and structure-properties relationships of nanoparticles.

Conclusion: This study presents the first biodistribution analysis of intact LNC using a validated quantification method, enabling the development of a PBPK model that improves the understanding of nanoparticle PK mechanisms.

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利用FRET对大鼠完整脂质纳米胶囊的特异性定量：生物分布和PBPK模型的建立。

目的：一个主要的挑战是量化完整的纳米颗粒，专门了解纳米药物的药代动力学（PK）。脂质纳米胶囊（LNC）携带Förster共振能量转移（FRET）跟踪器之前已经开发出来，并在血液样本中应用了一种定量方法。材料与方法：建立肝、脾、肺的定量方法，进行静脉注射后50 nm完整的FRET-LNC （FRET-LNC-50）在大鼠体内的生物分布。结果：采用新开发的提取方法从器官中提取FRET-LNC-50，使其完整性得以保存和定量。该方法允许评估完整LNC的生物分布研究。进行非区隔PK分析，计算PK参数。暴露最多的器官是肝脏，它的半衰期比血液和其他器官都长。特定生物分布数据的可用性允许开发第一个基于生理的PK （PBPK）模型，该模型代表了一个理想的平台，可以进一步汇总来自各种纳米颗粒类型的生物分布数据，并深入了解PK机制和纳米颗粒的结构-性质关系。结论：本研究首次采用经过验证的定量方法分析了完整LNC的生物分布，从而建立了PBPK模型，提高了对纳米颗粒PK机制的理解。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Nanomedicine (London, England)

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