Optimising the manufacture of perfluorocarbon nanodroplets through varying sonication parameters
Optimising the manufacture of perfluorocarbon nanodroplets through varying sonication parameters
Perfluorocarbon nanodroplets (PFC-NDs) are promising ultrasound-responsive theranostic agents with applications in both diagnostic imaging and drug delivery. The acoustic vaporisation threshold, extravasation potential, and stability of PFC-NDs are all affected by their size. However, methods to ensure reproducible size and concentration during production by sonication are lacking. To address this need, we examined the effect of temperature, sonication time, sonication intensity, PFC concentration and sonicator tip height on ND characteristics. PFC-NDs with a perfluoro-n-pentane (PFP) core and a phospholipid shell were manufactured by probe-sonication. Pulsed sonication was used to maintain the sample temperature below the boiling point of PFP. Median particle diameter was measured using nanoparticle tracking analysis. PFC-ND diameter increased with increasing PFP concentration, with a stronger relationship as sonicator tip height increased. Above 5% v/v PFP, there was a qualitative increase in the number of particles visible by light microscopy. Increasing the sonication duration did not yield a significant change in ND size. A minimum amplitude of 60% was required for mixing to occur, with amplitudes of 80% and 100% resulting in foam production. Sonicator power output was linear with respect to time but differed depending on sample volume, composition, and vessel geometry. This study indicates that controlling the processing parameters can facilitate reproducible manufacturing of PFC-NDs.
particle manufacture, perfluorocarbon nanodroplet, ultrasound, Particle manufacture, Perfluorocarbon nanodroplet, Ultrasound
Campbell, Christopher K.
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O'Brien, Kirsten Emma
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Kosk, Dariusz Konrad
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Rumney, Robin M.H.
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Glynne-Jones, Peter
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Birkin, Peter
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LuTheryn, Gareth
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Webb, Jeremy
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Stride, Eleanor
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Carugo, Dario
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Evans, Nicholas D.
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July 2025
Campbell, Christopher K.
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O'Brien, Kirsten Emma
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Kosk, Dariusz Konrad
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Rumney, Robin M.H.
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Glynne-Jones, Peter
6ca3fcbc-14db-4af9-83e2-cf7c8b91ef0d
Birkin, Peter
ba466560-f27c-418d-89fc-67ea4f81d0a7
LuTheryn, Gareth
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Webb, Jeremy
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Stride, Eleanor
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Carugo, Dario
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Evans, Nicholas D.
06a05c97-bfed-4abb-9244-34ec9f4b4b95
Campbell, Christopher K., O'Brien, Kirsten Emma, Kosk, Dariusz Konrad, Rumney, Robin M.H., Glynne-Jones, Peter, Birkin, Peter, LuTheryn, Gareth, Webb, Jeremy, Stride, Eleanor, Carugo, Dario and Evans, Nicholas D.
(2025)
Optimising the manufacture of perfluorocarbon nanodroplets through varying sonication parameters.
Ultrasonics Sonochemistry, 118, [107332].
(doi:10.1016/j.ultsonch.2025.107332).
Abstract
Perfluorocarbon nanodroplets (PFC-NDs) are promising ultrasound-responsive theranostic agents with applications in both diagnostic imaging and drug delivery. The acoustic vaporisation threshold, extravasation potential, and stability of PFC-NDs are all affected by their size. However, methods to ensure reproducible size and concentration during production by sonication are lacking. To address this need, we examined the effect of temperature, sonication time, sonication intensity, PFC concentration and sonicator tip height on ND characteristics. PFC-NDs with a perfluoro-n-pentane (PFP) core and a phospholipid shell were manufactured by probe-sonication. Pulsed sonication was used to maintain the sample temperature below the boiling point of PFP. Median particle diameter was measured using nanoparticle tracking analysis. PFC-ND diameter increased with increasing PFP concentration, with a stronger relationship as sonicator tip height increased. Above 5% v/v PFP, there was a qualitative increase in the number of particles visible by light microscopy. Increasing the sonication duration did not yield a significant change in ND size. A minimum amplitude of 60% was required for mixing to occur, with amplitudes of 80% and 100% resulting in foam production. Sonicator power output was linear with respect to time but differed depending on sample volume, composition, and vessel geometry. This study indicates that controlling the processing parameters can facilitate reproducible manufacturing of PFC-NDs.
Text
Accepted MS ULTSON-D-24-01094_R2
- Accepted Manuscript
More information
Accepted/In Press date: 25 March 2025
e-pub ahead of print date: 9 April 2025
Published date: July 2025
Keywords:
particle manufacture, perfluorocarbon nanodroplet, ultrasound, Particle manufacture, Perfluorocarbon nanodroplet, Ultrasound
Identifiers
Local EPrints ID: 501262
URI: http://eprints.soton.ac.uk/id/eprint/501262
ISSN: 1350-4177
PURE UUID: 44f2c707-2da9-4ece-a497-8d596c348187
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Date deposited: 28 May 2025 16:34
Last modified: 11 Sep 2025 02:30
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Contributors
Author:
Christopher K. Campbell
Author:
Kirsten Emma O'Brien
Author:
Dariusz Konrad Kosk
Author:
Robin M.H. Rumney
Author:
Gareth LuTheryn
Author:
Eleanor Stride
Author:
Dario Carugo
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