Anisotropic super-attenuation of capillary waves on driven glass interfaces

Metrological AFM measurements are performed on the silica glass interfaces of photonic band-gap fibres and hollow capillaries. The freezing of attenuated out-of-equilibrium capillary waves during the drawing process is shown to result in a reduced surface roughness. The roughness attenuation with respect to the expected thermodynamical limit is determined to vary with the drawing stress following a power law. A striking anisotropic character of the height correlation is observed: glass surfaces thus retain a structural record of the direction of the flow to which the liquid was submitted

A numerical method for fast 3D photoacoustic tomography with arbitrary geometry of sensors

International audienc

A numerical method for fast 3D photoacoustic tomography with arbitrary geometry of sensors

International audienc

Transcranial ultrasonic therapy based on time reversal of acoustically induced cavitation bubble signature.

International audienceBrain treatment through the skull with high-intensity focused ultrasound can be achieved with multichannel arrays and adaptive focusing techniques such as time reversal. This method requires a reference signal to be either emitted by a real source embedded in brain tissues or computed from a virtual source, using the acoustic properties of the skull derived from computed tomography images. This noninvasive computational method focuses with precision, but suffers from modeling and repositioning errors that reduce the accessible acoustic pressure at the focus in comparison with fully experimental time reversal using an implanted hydrophone. In this paper, this simulation-based targeting has been used experimentally as a first step for focusing through an ex vivo human skull at a single location. It has enabled the creation of a cavitation bubble at focus that spontaneously emitted an ultrasonic wave received by the array. This active source signal has allowed 97 +/- 1.1% of the reference pressure (hydrophone-based) to be restored at the geometrical focus. To target points around the focus with an optimal pressure level, conventional electronic steering from the initial focus has been combined with bubble generation. Thanks to step-by-step bubble generation, the electronic steering capabilities of the array through the skull were improved

Volumetric and Simultaneous Photoacoustic and Ultrasound Imaging with a Conventional Linear Array in a Multiview Scanning Scheme

Volumetric dual photacoustic (PA) / ultrasonic (US) imaging with precise spatial and temporal coregistration can provide valuable and complementary information for diagnosis and monitoring. Considerable research has sought to combine 3D PA/US imaging in configurations that can be transferred to clinical application but technical compromises currently result in poor image quality either for photoacoustic or ultrasonic modes. Simultaneous 3D PA/US tomography was implemented here by interlacing PA and US acquisitions during the rotate-translate scan of a 5-MHz linear array (12 angles and 30 mm translational range to image a cylindrical volume of 21 mm diameter and 19 mm length within 21 seconds). Volumetric image reconstruction was performed with synthetic aperture approaches. An original calibration method was developed to estimate 6 geometrical parameters and 1 temporal off-set providing sharpest and best superimposed reconstructions. Calibration thread phantom design and choice of metrics to build the cost function were based on analysis of a numerical phantom and the final selection demonstrates a high estimation accuracy of the 7 parameters. Experimental estimations validated the calibration repeatability. Experiments in an additional phantom showed a superposition distance between thread centers identified in the PA and US images to be smaller than 10% of the acoustic wavelength, and a spatial resolution on the order of the wavelength. Dual mode 3D imaging with high-quality co-registration and excellent, uniform spatial resolution was further demonstrated on phantoms with complementary contrasts, and should contribute to more sensitive and robust imaging to detect and follow biological changes or the accumulation of nanoagents in living systems