Lipid shedding from single oscillating microbubbles.

Lipid-coated microbubbles are used clinically as contrast agents for ultrasound imaging and are being developed for a variety of therapeutic applications. The lipid encapsulation and shedding of the lipids by acoustic driving of the microbubble has a crucial role in microbubble stability and in ultrasound-triggered drug delivery; however, little is known about the dynamics of lipid shedding under ultrasound excitation. Here we describe a study that optically characterized the lipid shedding behavior of individual microbubbles on a time scale of nanoseconds to microseconds. A single ultrasound burst of 20 to 1000 cycles, with a frequency of 1 MHz and an acoustic pressure varying from 50 to 425 kPa, was applied. In the first step, high-speed fluorescence imaging was performed at 150,000 frames per second to capture the instantaneous dynamics of lipid shedding. Lipid detachment was observed within the first few cycles of ultrasound. Subsequently, the detached lipids were transported by the surrounding flow field, either parallel to the focal plane (in-plane shedding) or in a trajectory perpendicular to the focal plane (out-of-plane shedding). In the second step, the onset of lipid shedding was studied as a function of the acoustic driving parameters, for example, pressure, number of cycles, bubble size and oscillation amplitude. The latter was recorded with an ultrafast framing camera running at 10 million frames per second. A threshold for lipid shedding under ultrasound excitation was found for a relative bubble oscillation amplitude >30%. Lipid shedding was found to be reproducible, indicating that the shedding event can be controlled.

[1]  Rama R. Gullapalli,et al.  Molecular dynamics simulations of DiI-C18(3) in a DPPC lipid bilayer. , 2008, Physical chemistry chemical physics : PCCP.

[2]  Hairong Zheng,et al.  Ultrasound-driven microbubble oscillation and translation within small phantom vessels. , 2007, Ultrasound in medicine & biology.

[3]  R. Adrian,et al.  Out-of-focus effects on particle image visibility and correlation in microscopic particle image velocimetry , 2000 .

[4]  Nico de Jong,et al.  Nonlinear shell behavior of phospholipid-coated microbubbles. , 2010, Ultrasound in medicine & biology.

[5]  Eleanor Stride,et al.  Accounting for the stability of microbubbles to multi-pulse excitation using a lipid-shedding model. , 2011, The Journal of the Acoustical Society of America.

[6]  Junru Wu,et al.  Observation of acoustic streaming near Albunex® spheres , 1998 .

[7]  Mark Borden,et al.  Ultrasound microbubble contrast agents: fundamentals and application to gene and drug delivery. , 2007, Annual review of biomedical engineering.

[8]  M. Borden,et al.  Lipid monolayer collapse and microbubble stability. , 2012, Advances in colloid and interface science.

[9]  P. Qiu Image processing and jump regression analysis , 2005 .

[10]  E Stride,et al.  Microbubble ultrasound contrast agents: A review , 2003, Proceedings of the Institution of Mechanical Engineers. Part H, Journal of engineering in medicine.

[11]  Nico de Jong,et al.  Brandaris 128 ultra-high-speed imaging facility: 10 years of operation, updates, and enhanced features. , 2012, The Review of scientific instruments.

[12]  C. Holland,et al.  Ultrasound-facilitated thrombolysis using tissue-plasminogen activator-loaded echogenic liposomes. , 2007, Thrombosis research.

[13]  Yao-Sheng Tung,et al.  Microbubble-Size Dependence of Focused Ultrasound-Induced Blood–Brain Barrier Opening in Mice In Vivo , 2010, IEEE Transactions on Biomedical Engineering.

[14]  Michel Versluis,et al.  High-speed imaging in fluids , 2013 .

[15]  Mark A Borden,et al.  Collapse and shedding transitions in binary lipid monolayers coating microbubbles. , 2006, Langmuir : the ACS journal of surfaces and colloids.

[16]  S Otto,et al.  Dissolution of multicomponent microbubbles in the bloodstream: 2. Experiment. , 1998, Ultrasound in medicine & biology.

[17]  R. Vandenbroucke,et al.  Ultrasound assisted siRNA delivery using PEG-siPlex loaded microbubbles. , 2008, Journal of Controlled Release.

[18]  Siewert J Marrink,et al.  The molecular mechanism of lipid monolayer collapse , 2008, Proceedings of the National Academy of Sciences.

[19]  Richard Manasseh,et al.  Cavitation microstreaming and stress fields created by microbubbles. , 2010, Ultrasonics.

[20]  Nico de Jong,et al.  Acoustical properties of individual liposome-loaded microbubbles. , 2012, Ultrasound in medicine & biology.

[21]  Detlef Lohse,et al.  Brandaris 128: A digital 25 million frames per second camera with 128 highly sensitive frames , 2003 .

[22]  P. Dayton,et al.  Influence of lipid shell physicochemical properties on ultrasound-induced microbubble destruction , 2005, IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control.

[23]  A. Katiyar,et al.  Growth and dissolution of an encapsulated contrast microbubble: effects of encapsulation permeability. , 2009, Ultrasound in medicine & biology.

[24]  Nico de Jong,et al.  Microbubble shape oscillations excited through ultrasonic parametric driving. , 2010, Physical review. E, Statistical, nonlinear, and soft matter physics.

[25]  Sascha Hilgenfeldt,et al.  Frequency dependence and frequency control of microbubble streaming flows , 2013 .

[26]  A. Kabalnov,et al.  Dissolution of multicomponent microbubbles in the bloodstream: 1. Theory. , 1998, Ultrasound in medicine & biology.

[27]  Nico de Jong,et al.  Microbubble spectroscopy of ultrasound contrast agents. , 2006, The Journal of the Acoustical Society of America.

[28]  Stefaan C De Smedt,et al.  Design and evaluation of doxorubicin-containing microbubbles for ultrasound-triggered doxorubicin delivery: cytotoxicity and mechanisms involved. , 2010, Molecular therapy : the journal of the American Society of Gene Therapy.

[29]  Nico de Jong,et al.  Nonspherical shape oscillations of coated microbubbles in contact with a wall. , 2011, Ultrasound in medicine & biology.

[30]  E. Gelderblom,et al.  Ultra-high-speed fluorescence imaging , 2012 .

[31]  James L. Thomas,et al.  Rapid shrinkage of lipid-coated bubbles in pulsed ultrasound. , 2013, Ultrasound in medicine & biology.

[32]  Nico de Jong,et al.  Characterizing the subharmonic response of phospholipid-coated microbubbles for carotid imaging. , 2011, Ultrasound in medicine & biology.

[33]  Richard Manasseh,et al.  Cavitation microstreaming patterns in single and multiple bubble systems , 2007, Journal of Fluid Mechanics.

[34]  R. Adrian,et al.  Pulsed laser technique application to liquid and gaseous flows and the scattering power of seed materials. , 1985, Applied optics.

[35]  A. Dumont,et al.  SONOTHROMBOLYSIS: AN EMERGING MODALITY FOR THE MANAGEMENT OF STROKE , 2009, Neurosurgery.

[36]  P. Marmottant,et al.  Controlled vesicle deformation and lysis by single oscillating bubbles , 2003, Nature.

[37]  Nico de Jong,et al.  High-speed imaging of an ultrasound-driven bubble in contact with a wall: “Narcissus” effect and resolved acoustic streaming , 2006 .

[38]  Nico de Jong,et al.  Sonoporation from jetting cavitation bubbles. , 2006, Biophysical journal.

[39]  Vassilis Sboros,et al.  The “quasi-stable” lipid shelled microbubble in response to consecutive ultrasound pulses , 2012 .

[40]  M. Versluis,et al.  Nonspherical vibrations of microbubbles in contact with a wall: a pilot study at low mechanical index. , 2008, Ultrasound in medicine & biology.

[41]  S. Smedt,et al.  Lipoplex‐Loaded Microbubbles for Gene Delivery: A Trojan Horse Controlled by Ultrasound , 2007 .

[42]  J. Connor Digital imaging of free calcium changes and of spatial gradients in growing processes in single, mammalian central nervous system cells. , 1986, Proceedings of the National Academy of Sciences of the United States of America.