Improved multidetector asymmetrical-flow field-flow fractionation method for particle sizing and concentration measurements of lipid-based nanocarriers for RNA delivery

[Display omitted] •Use of the frit-inlet channel improves MD-AF4 analysis of LNP-RNA.•A robust method for AF4 separation of LNP-RNA has been developed and tested on two different platform.•The method meets all the ISO standard requirements for AF4 analysis.•The method allowed the analysis of particl...

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Published in:European journal of pharmaceutics and biopharmaceutics Vol. 163; pp. 252 - 265
Main Authors: Mildner, R., Hak, S., Parot, J., Hyldbakk, A., Borgos, S.E., Some, D., Johann, C., Caputo, F.
Format: Journal Article
Language:English
Published: Netherlands Elsevier B.V 01-06-2021
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Summary:[Display omitted] •Use of the frit-inlet channel improves MD-AF4 analysis of LNP-RNA.•A robust method for AF4 separation of LNP-RNA has been developed and tested on two different platform.•The method meets all the ISO standard requirements for AF4 analysis.•The method allowed the analysis of particle size, morphology and physical stability.•A macro to display quantitative number based-particle size distributions by AF4-MALS was developed and successfully implemented. Lipid-based nanoparticles for RNA delivery (LNP-RNA) are revolutionizing the nanomedicine field, with one approved gene therapy formulation and two approved vaccines against COVID-19, as well as multiple ongoing clinical trials. As for other innovative nanopharmaceuticals (NPhs), the advancement of robust methods to assess their quality and safety profiles—in line with regulatory needs—is critical for facilitating their development and clinical translation. Asymmetric-flow field-flow fractionation coupled to multiple online optical detectors (MD-AF4) is considered a very versatile and robust approach for the physical characterisation of nanocarriers, and has been used successfully for measuring particle size, polydispersity and physical stability of lipid-based systems, including liposomes and solid lipid nanoparticles. However, the unique core structure of LNP-RNA, composed of ionizable lipids electrostatically complexed with RNA, and the relatively labile lipid-monolayer coating, is more prone to destabilization during focusing in MD-AF4 than previously characterised nanoparticles, resulting in particle aggregation and sample loss. Hence characterisation of LNP-RNA by MD-AF4 needs significant adaptation of the methods developed for liposomes. To improve the performance of MD-AF4 applied to LNP-RNA in a systematic and comprehensive manner, we have explored the use of the frit-inlet channel where, differently from the standard AF4 channel, the particles are relaxed hydrodynamically as they are injected. The absence of a focusing step minimizes contact between the particle and the membrane, reducing artefacts (e.g. sample loss, particle aggregation). Separation in a frit-inlet channel enables satisfactory reproducibility and acceptable sample recovery in the commercially available MD-AF4 instruments. In addition to slice-by-slice measurements of particle size, MD-AF4 also allows to determine particle concentration and the particle size distribution, demonstrating enhanced versatility beyond standard sizing measurements.
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ISSN:0939-6411
1873-3441
DOI:10.1016/j.ejpb.2021.03.004