Self-assembly of actin scaffolds on lipid microbubbles

George R. Heath; Radwa H. Abou-Saleh; Sally A. Peyman; Benjamin R. G. Johnson; Simon D. Connell; Stephen D. Evans

doi:10.1039/c3sm52199k

Self-assembly of actin scaffolds on lipid microbubbles

George R. Heath, Radwa H. Abou-Saleh, Sally A. Peyman, Benjamin R. G. Johnson, Simon D. Connell, Stephen D. Evans^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

9 Citations (Scopus)

Abstract

Microbubbles offer unique properties as combined carriers of therapeutic payloads and diagnostic agents. Here we report on the development of novel microbubble architectures that in addition to the usual lipid shell have an actin cytoskeletal cortex assembled on their exterior. We show, using atomic force microscopy that this biomimetic coating creates a thin mesh that allows tuning of the mechanical properties of microbubbles and that the nature of actin assembly is determined by the fluidity of the lipid layer. Further, we show that it is possible to attach payloads and targeting-ligands to the actin scaffold. Resistance to gas permeation showed that the additional actin layer reduces gas diffusion across the shell and thus increases bubble lifetime. This study demonstrates a one step method to creating more complex microbubble architectures, which would be capable of further modification and tuning through the inclusion of actin binding proteins.

Original language	English
Pages (from-to)	694-700
Number of pages	7
Journal	Soft Matter
Volume	10
Issue number	5
DOIs	https://doi.org/10.1039/c3sm52199k
Publication status	Published - 7 Feb 2014

ASJC Scopus subject areas

General Chemistry
Condensed Matter Physics

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title = "Self-assembly of actin scaffolds on lipid microbubbles",

abstract = "Microbubbles offer unique properties as combined carriers of therapeutic payloads and diagnostic agents. Here we report on the development of novel microbubble architectures that in addition to the usual lipid shell have an actin cytoskeletal cortex assembled on their exterior. We show, using atomic force microscopy that this biomimetic coating creates a thin mesh that allows tuning of the mechanical properties of microbubbles and that the nature of actin assembly is determined by the fluidity of the lipid layer. Further, we show that it is possible to attach payloads and targeting-ligands to the actin scaffold. Resistance to gas permeation showed that the additional actin layer reduces gas diffusion across the shell and thus increases bubble lifetime. This study demonstrates a one step method to creating more complex microbubble architectures, which would be capable of further modification and tuning through the inclusion of actin binding proteins.",

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AU - Heath, George R.

AU - Abou-Saleh, Radwa H.

AU - Peyman, Sally A.

AU - Johnson, Benjamin R. G.

AU - Connell, Simon D.

AU - Evans, Stephen D.

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AB - Microbubbles offer unique properties as combined carriers of therapeutic payloads and diagnostic agents. Here we report on the development of novel microbubble architectures that in addition to the usual lipid shell have an actin cytoskeletal cortex assembled on their exterior. We show, using atomic force microscopy that this biomimetic coating creates a thin mesh that allows tuning of the mechanical properties of microbubbles and that the nature of actin assembly is determined by the fluidity of the lipid layer. Further, we show that it is possible to attach payloads and targeting-ligands to the actin scaffold. Resistance to gas permeation showed that the additional actin layer reduces gas diffusion across the shell and thus increases bubble lifetime. This study demonstrates a one step method to creating more complex microbubble architectures, which would be capable of further modification and tuning through the inclusion of actin binding proteins.

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Self-assembly of actin scaffolds on lipid microbubbles

Abstract

ASJC Scopus subject areas

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