Ionizable lipid nanoparticles for in utero mRNA delivery

Riley, Rachel; Kashyap, Meghana V.; Billingsley, Margaret M.; White, Brandon M.; Alameh, Mohamad-Gabriel; Bose, Sourav K.; Zoltick, Philip W.; Li, Hiaying; Zhang, Rui; Cheng, Angela; Weissman, Drew; Peranteau, William H.; Mitchell, Michael J.

doi:10.1126/sciadv.aba1028

Cited by 125 publications

(116 citation statements)

References 76 publications

(133 reference statements)

Supporting

Mentioning

115

Contrasting

Order By: Relevance

“…In addition, lipid nanoparticle–mRNA formulations encoding immune stimulators can be directly delivered into tumour tissue by intratumoural injection 106 , 161 – 163 , to boost a local pro-inflammatory environment, which leads to immune cell activation and subsequent priming of systemic anticancer responses 106 , 161 – 163 . Finally, in utero administration of lipid nanoparticle–mRNA formulations can be applied to deliver mRNA to mouse fetuses 164 , achieving protein expression in fetal livers, lungs and intestines 164 .…”

Section: Administration Routesmentioning

confidence: 99%

Lipid nanoparticles for mRNA delivery

et al. 2021

View full text Add to dashboard Cite

Messenger RNA (mRNA) has emerged as a new category of therapeutic agent to prevent and treat various diseases. To function in vivo, mRNA requires safe, effective and stable delivery systems that protect the nucleic acid from degradation and that allow cellular uptake and mRNA release. Lipid nanoparticles have successfully entered the clinic for the delivery of mRNA; in particular, lipid nanoparticle–mRNA vaccines are now in clinical use against coronavirus disease 2019 (COVID-19), which marks a milestone for mRNA therapeutics. In this Review, we discuss the design of lipid nanoparticles for mRNA delivery and examine physiological barriers and possible administration routes for lipid nanoparticle–mRNA systems. We then consider key points for the clinical translation of lipid nanoparticle–mRNA formulations, including good manufacturing practice, stability, storage and safety, and highlight preclinical and clinical studies of lipid nanoparticle–mRNA therapeutics for infectious diseases, cancer and genetic disorders. Finally, we give an outlook to future possibilities and remaining challenges for this promising technology.

show abstract

Section: Administration Routesmentioning

confidence: 99%

Lipid nanoparticles for mRNA delivery

et al. 2021

View full text Add to dashboard Cite

show abstract

“…[5,[15][16][17][18] LNPs are typically comprised of an ionizable cationic lipid to encapsulate RNA and aid intracellular delivery with low toxicity, [19,20] combined with several "helper lipids", [21] such as phospholipids, a sterol, and a lipidated polyethylene glycol (PEG; PEG-ylated lipid). In addition to the introduction of new ionizable lipids, [17,[22][23][24][25][26][27] LNP efficacy can be significantly modulated by fine-tuning of LNP lipid compositions to induce changes of physicochemical parameters such as size and surface properties [28] or by chemical modification of individual helper components such as cholesterol. [29] Optimisation can result in both improved total cell uptake and, importantly, better endosomal escape.…”

Section: Introductionmentioning

confidence: 99%

Time evolution of PEG-shedding and serum protein coronation determines the cell uptake kinetics and delivery of lipid nanoparticle formulated mRNA

Gallud

Munson

Liu

et al. 2021

Preprint

View full text Add to dashboard Cite

Development of efficient lipid nanoparticle (LNP) vectors remains a major challenge towards broad clinical translation of RNA therapeutics. New lipids will be required, but also better understanding LNP interactions with the biological environment. Herein, we model protein corona formation on PEG-ylated DLin-MC3-DMA LNPs and identify time-dependent maturation steps that critically unlock their cellular uptake and mRNA delivery. Uptake requires active serum proteins and precedes after a significant (∼2 hours) lag-time, which we show can be eliminated by pre-incubating LNPs for 3-4 hours in serum-containing media. This indicates an important role of protein corona maturation for the pharmacokinetic effects of these LNPs. We show, using single-nanoparticle imaging, NMR diffusometry, SANS, and proteomics, that the LNPs, upon serum exposure, undergo rapid PEG-shedding (∼30 minutes), followed by a slower rearrangement of the adsorbed protein layer. The PEG-shedding coincides in time with high surface abundance of Apolipoprotein A-II, whereas the LNPs preferentially bind Apolipoprotein E when their maximum uptake-competent state is reached. Finally, we show that pre-incubation of the LNPs enables rapid uptake and allows pulse-chase video-microscopy colocalization experiments with sufficiently short pulse durations to gain improved mechanistic understanding of how intracellular trafficking events determine delivery efficacy, emphasizing early endosomes as important delivery-mediating compartments.

show abstract

“… 104 In fact, commercial devices based on micromixers such as NanoAssemblr™ platforms have been universally used in many studies to prepare liposome/LNPs for different applications, such as CRISPR-Cas9 genome editing for cancer therapy 105 and in utero mRNA delivery for monogenic fetal diseases. 106 Notably, COVID-19 vaccine nanoparticles manufactured by Pfizer are reported to be prepared by microfluidic mixers. 93 …”

Section: Microfluidic-assisted Formation Of Liposomesmentioning

confidence: 99%