Low-boiling-point perfluorocarbon nanodroplets for adaptable ultrasound-induced blood-brain barrier opening

Low-boiling point perfluorocarbon nanodroplets (NDs) are valued as effective sonosensitive agents, encapsulating a liquid perfluorocarbon that would instantaneously vaporize at body temperature without the NDs shell. Those NDs have been explored for both therapeutic and diagnostic purposes. Here, ph...

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Bibliographic Details
Published in:Journal of controlled release 2024-12, Vol.376, p.441-456
Main Authors: Dauba, Ambre, Spitzlei, Claire, Bautista, Kathlyne Jayne B., Jourdain, Laurène, Selingue, Erwan, VanTreeck, Kelly E., Mattern, Jacob A., Denis, Caroline, Ouldali, Malika, Arteni, Ana-Andreea, Truillet, Charles, Larrat, Benoit, Tsuruta, James, Durham, Phillip G., Papadopoulou, Virginie, Dayton, Paul A., Tsapis, Nicolas, Novell, Anthony
Format: Article
Language:English
Subjects:
Animals
Blood-brain barrier
Blood-Brain Barrier - metabolism
Chemical Sciences
Contrast Media - chemistry
Drug delivery
Engineering Sciences
Fluorocarbons - chemistry
Focused ultrasound
Life Sciences
Male
Mice
Microbubbles
Nanodroplets
Nanoparticles - chemistry
Perfluorocarbon
Phospholipids - chemistry
Ultrasonic Waves
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Summary:Low-boiling point perfluorocarbon nanodroplets (NDs) are valued as effective sonosensitive agents, encapsulating a liquid perfluorocarbon that would instantaneously vaporize at body temperature without the NDs shell. Those NDs have been explored for both therapeutic and diagnostic purposes. Here, phospholipid-shelled nanodroplets containing octafluoropropane (C3F8) or decafluorobutane (C4F10) formed by condensation of microbubbles were thoroughly characterized before blood-brain (BBB) permeabilization. Transmission electron microscopy (TEM) and cryo-TEM were employed to confirm droplet formation while providing high-resolution insights into the droplet surface and lipid arrangement assessed from electron density observation after condensation. The vaporization threshold of NDs was determined with a high-speed camera, and the frequency signal emitted by the freshly vaporized bubbles was analyzed using cavitation detection. C3F8 NDs exhibited vaporization at 0.3 MPa (f0 = 1.5 MHz, 50 cycles), and emitted signals at 2 f0 and 1.5 f0 from 0.45 MPa onwards (f0 = 1.5 MHz, 50 cycles), while broadband noise was measured starting from 0.55 MPa. NDs with the higher boiling point C4F10 vaporized at 1.15 MPa and emitted signals at 2 f0 from 0.65 MPa and 1.5 f0 from 0.9 MPa, while broadband noise was detected starting from 0.95 MPa. Both ND formulations were used to permeabilize the BBB in healthy mice using tailored ultrasound sequences, allowing for the identification of optimal applications for each NDs type. C3F8 NDs proved suitable and safe for permeabilizing a large area, potentially the entire brain, at low acoustic pressure. Meanwhile, C4F10 droplets facilitated very localized (400 μm isotropic) permeabilization at higher pressure. This study prompts a closer examination of the structural rearrangements occurring during the condensation of microbubbles into NDs and highlights the potential to tailor solutions for different brain pathologies by choosing the composition of the NDs and adjusting the ultrasound sequence. [Display omitted]
ISSN:0168-3659
1873-4995
1873-4995
DOI:10.1016/j.jconrel.2024.10.023