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Abou-Saleh RH, Peyman SA, Johnson BR, et al. The influence of intercalating perfluorohexane into lipid shells on nano and microbubble stability. Soft Matter. 2016;12(34):7223-30doi: 10.1039/c6sm00956e.
Abou-Saleh, R. H., Peyman, S. A., Johnson, B. R., Marston, G., Ingram, N., Bushby, R., Coletta, P. L., Markham, A. F., & Evans, S. D. (2016). The influence of intercalating perfluorohexane into lipid shells on nano and microbubble stability. Soft matter, 12(34), 7223-30. https://doi.org/10.1039/c6sm00956e
Abou-Saleh, Radwa H, et al. "The influence of intercalating perfluorohexane into lipid shells on nano and microbubble stability." Soft matter vol. 12,34 (2016): 7223-30. doi: https://doi.org/10.1039/c6sm00956e
Abou-Saleh RH, Peyman SA, Johnson BR, Marston G, Ingram N, Bushby R, Coletta PL, Markham AF, Evans SD. The influence of intercalating perfluorohexane into lipid shells on nano and microbubble stability. Soft Matter. 2016 Sep 14;12(34):7223-30. doi: 10.1039/c6sm00956e. Epub 2016 Aug 08. PMID: 27501364.
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Soft Matter. 2016 Sep 14;12(34):7223-30. doi: 10.1039/c6sm00956e. Epub 2016 Aug 08.

The influence of intercalating perfluorohexane into lipid shells on nano and microbubble stability.

Soft matter

Radwa H Abou-Saleh, Sally A Peyman, Benjamin R G Johnson, Gemma Marston, Nicola Ingram, Richard Bushby, P Louise Coletta, Alexander F Markham, Stephen D Evans

Affiliations

  1. Molecular and Nanoscale Physics Group, School of Physics and Astronomy, University of Leeds, LS2 9JT, UK. [email protected].

PMID: 27501364 DOI: 10.1039/c6sm00956e

Abstract

Microbubbles are potential diagnostic and therapeutic agents. In vivo stability is important as the bubbles are required to survive multiple passages through the heart and lungs to allow targeting and delivery. Here we have systematically varied key parameters affecting microbubble lifetime to significantly increase in vivo stability. Whilst shell and core composition are found to have an important role in improving microbubble stability, we show that inclusion of small quantities of C6F14 in the microbubble bolus significantly improves microbubble lifetime. Our results indicate that C6F14 inserts into the lipid shell, decreasing surface tension to 19 mN m(-1), and increasing shell resistance, in addition to saturating the surrounding medium. Surface area isotherms suggest that C6F14 incorporates into the acyl chain region of the lipid at a high molar ratio, indicating ∼2 perfluorocarbon molecules per 5 lipid molecules. The resulting microbubble boluses exhibit a higher in vivo image intensity compared to commercial compositions, as well as longer lifetimes.

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Grant support