Formation of protein and protein-gold nanoparticle stabilized microbubbles by pressurized gyration

Suntharavathanan Mahalingam; Raimi-Abraham Bahijja; Duncan Q M Craig; Mohan Edirisinghe

doi:10.1021/la502181g

Formation of protein and protein-gold nanoparticle stabilized microbubbles by pressurized gyration

Suntharavathanan Mahalingam, Raimi-Abraham Bahijja, Duncan Q M Craig, Mohan Edirisinghe^*

^*Corresponding author for this work

Institute of Pharmaceutical Science

UCL University College London

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

71 Citations (Scopus)

Abstract

A one-pot single-step novel process has been developed to form microbubbles up to 250 μm in diameter using a pressurized rotating device. The microbubble diameter is shown to be a function of rotational speed and working pressure of the processing system, and a modified Rayleigh-Plesset equation has been derived to explain the bubble-forming mechanism. A parametric plot is constructed to identify a rotating speed and working pressure regime, which allows for continuous bubbling. Bare protein (lysozyme) microbubbles generated in this way exhibit a morphological change, resulting in microcapsules over a period of time. Microbubbles prepared with gold nanoparticles at the bubble surface showed greater stability over a time period and retained the same morphology. The functionalization of microbubbles with gold nanoparticles also rendered optical tunability and has promising applications in imaging, biosensing, and diagnostics.

Original language	English
Pages (from-to)	659-666
Number of pages	8
Journal	Langmuir : the ACS journal of surfaces and colloids
Volume	31
Issue number	2
Early online date	15 Jul 2014
DOIs	https://doi.org/10.1021/la502181g
Publication status	Published - 20 Jan 2015

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abstract = "A one-pot single-step novel process has been developed to form microbubbles up to 250 μm in diameter using a pressurized rotating device. The microbubble diameter is shown to be a function of rotational speed and working pressure of the processing system, and a modified Rayleigh-Plesset equation has been derived to explain the bubble-forming mechanism. A parametric plot is constructed to identify a rotating speed and working pressure regime, which allows for continuous bubbling. Bare protein (lysozyme) microbubbles generated in this way exhibit a morphological change, resulting in microcapsules over a period of time. Microbubbles prepared with gold nanoparticles at the bubble surface showed greater stability over a time period and retained the same morphology. The functionalization of microbubbles with gold nanoparticles also rendered optical tunability and has promising applications in imaging, biosensing, and diagnostics.",

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Formation of protein and protein-gold nanoparticle stabilized microbubbles by pressurized gyration

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