Abstract: This disclosure relates to a method for characterizing activation of an anatomical tissue subjected to contraction, aiming at providing a characterization of the contraction itself in a quantitative manner which is accurate and repeatable. The invention proposes an analysis of the activation of the anatomical structure based on instantaneous spectral contents of an activity signal from which an identification of peaks of dominant frequency characterizing the contraction throughout the anatomical tissue results. An evolution of a spatial distribution of peaks of dominant frequency throughout the anatomical tissue over time can also be monitored. The disclosure finds particular advantageous applications in provision of a mapping of activation of the anatomical tissue in order to identify a possible dysfunction, such as an arrhythmia in a cardiac tissue.

Abstract: Method and system for localizing a region of interest in a medium in which cavitation occurs. Method for localizing a region of interest (R) in a medium (M) in which cavitation occurs, the method comprising the steps consisting in: producing cavitation in the region of interest (R), the cavitation generating an acoustic signal, at each of at least three separate positions, detecting a cavitation signal representative of the acoustic signal of the cavitation, for at least two pairs of cavitation signals, determining a delay between the cavitation signals of each pair of cavitation signals, calculating a localization of the region of interest (R) based on the delays and the positions.

Abstract: This device (2) for generating ultrasonic waves in a target region of a soft solid, includes at least two ultrasound sources (32), light sources (40) distributed around a central axis (X2) of the device (2), for enlightening a zone of the soft solid via subsurface scattering, and a video camera (50), for capturing images of the zone enlightened by the lighting means. The ultrasound source (32), the light sources (40) and the video camera (50) are mounted on a body of the device (20) and oriented toward a common target zone which includes a focal point of the ultrasound sources (32). A boresight of the video camera is aligned on the central axis (X2).

Abstract: An interstitial ultrasound thermal ablation applicator for conformal treatment of an inhomogeneous tumor lesion includes: a body having a longitudinal axis; and a plurality of array transducers mounted on the body, arranged side by side and having azimuth directions parallel to the longitudinal axis of the body, and having outer faces disposed in a polygonal arrangement; the plurality of array transducers having predetermined elevation dimensions defined for directing emitted ultrasonic energy to obtain a conformal volume treatment of the tumor lesions. An electronic driving method for driving an applicator having multiple independent transducer elements arranged in rows and columns includes: controlling focal parameters of each row and column of transducer elements; and controlling a contribution of each row and column of transducer elements in a manner to provide a conformal ablated volume.

Abstract: This shear wave imaging method, for collecting information on a target region (R) of a soft solid (S), comprises at least the steps a) of generating at least one shear wave (SW) in the target region, and b) of detecting a propagation pattern of the shear wave in the target region. Step a) is realized by applying to particles of the target region (R) some Lorentz forces resulting from an electric field (E) and from a magnetic field (B). At least one of the electric field (E) and the magnetic field (B) is variable in time, with a central frequency (fo) between 1 Hz and 10 kHz. Alternatively, both the electric and magnetic fields (E, B) are variable in time, with a central difference frequency (?fo) between 1 Hz and 10 kHz. The shear wave imaging installation comprises a first system (4, 7) for generating at least one shear wave (SW) in the target region (R) and a second system (10) for detecting a propagation pattern of the shear wave.

Abstract: Method and system for localizing a region of interest in a medium in which cavitation occurs. Method for localizing a region of interest (R) in a medium (M) in which cavitation occurs, the method comprising the steps consisting in: producing cavitation in the region of interest (R), the cavitation generating an acoustic signal, at each of at least three separate positions, detecting a cavitation signal representative of the acoustic signal of the cavitation, for at least two pairs of cavitation signals, determining a delay between the cavitation signals of each pair of cavitation signals, calculating a localization of the region of interest (R) based on the delays and the positions.

Abstract: This method for determining a mechanical property of a layered soft material, includes steps of a) generating an ultrasound wave (W1) focused towards a first point (P1) of the material, said wave, upon interacting with a layer of said material, generating in turn a Lamb (L1) wave propagating into said layer of the material, b) measuring, at a second point (P2) of the material belonging to said layer, a physical parameter of the generated Lamb wave, c) automatically determining the mechanical property of the layered soft material, based on the measured physical parameter. Step a) is performed by exciting a first ultrasonic transducer (401) with a first excitation signal (S401) during at most 50 ms, step b) is performed by exciting a second ultrasonic transducer (402) with a second excitation signal (S402) during at most 0.

Abstract: This device (2) for generating ultrasonic waves in a target region of a soft solid, includes at least two ultrasound sources (32), light sources (40) distributed around a central axis (X2) of the device (2), for enlightening a zone of the soft solid via subsurface scattering, and a video camera (50), for capturing images of the zone enlightened by the lighting means. The ultrasound source (32), the light sources (40) and the video camera (50) are mounted on a body of the device (20) and oriented toward a common target zone which includes a focal point of the ultrasound sources (32). A boresight of the video camera is aligned on the central axis (X2).

Abstract: The method determines parameters to generate confocal ultrasound beams (B1,B2) inside a medium (4), and uses a device (1) comprising first and second ultrasound means (11,12) and first and second displacement members (13,14) for moving the ultrasound means (11,12). The parameters include signals s1,s2 to the ultrasound means (11,12), and the positions x1,x2 of the ultrasound means (11,12). The parameters are optimized for having a minimum amplitude a1,a2 of the signals s1,s2 and having an acoustic effect inside the medium (4).

Abstract: A device for treatment of an ocular pathology characterized in that it comprises at least one eye ring (1) wherein the proximal end of said eye ring (1) is suitable to be applied onto the glove and means (2,17) to generate ultrasound beam fixed on the distal end of the eye ring (1), said means to generate ultrasound beam presenting a concave segment shape conformed along a single curvature corresponding to a single direction wherein the concavity is designed to be tuned towards the eyeglobe.

Abstract: An interstitial ultrasound thermal ablation applicator for conformal treatment of an inhomogeneous tumor lesion includes: a body having a longitudinal axis; and a plurality of array transducers mounted on the body, arranged side by side and having azimuth directions parallel to the longitudinal axis of the body, and having outer faces disposed in a polygonal arrangement; the plurality of array transducers having predetermined elevation dimensions defined for directing emitted ultrasonic energy to obtain a conformal volume treatment of the tumor lesions. An electronic driving method for driving an applicator having multiple independent transducer elements arranged in rows and columns includes: controlling focal parameters of each row and column of transducer elements; and controlling a contribution of each row and column of transducer elements in a manner to provide a conformal ablated volume.

Abstract: A device for treatment of an ocular pathology characterized in that it comprisesat least one eye ring (1) wherein the proximal end of said eye ring (1) is suitable to be applied onto the globe and means (2,17) to generate ultrasound beam fixed on the distal end of the eye ring (1), said means to generate ultrasound beam presenting a concave segment shape conformed along a single curvature corresponding to a single direction wherein the concavity is designed to be tuned towards the eyeglobe.

Abstract: This shear wave imaging method, for collecting information on a target region (R) of a soft solid (S), comprises at fi least the steps a) of generating at least one shear wave (SW) in the target region, and b) of detecting a propagation pattern of the shear wave in the target region. Step a) is realized by applying to particles of the target region (R) some Lorentz forces resulting from an electric field (E) and from a magnetic field (B). At least one of the electric field (E) and the magnetic field (B) is variable in time, with a central frequency (fo) between 1 Hz and 10 kHz. Alternatively, both the electric and magnetic fields (E, B) are variable in time, with a central difference frequency (?fo) between 1 Hz and 10 kHz. The shear wave imaging installation comprises a first system (4, 7) for generating at least one shear wave (SW) in the target region (R) and a second system (10) for detecting a propagation pattern of the shear wave.

Abstract: A device for treatment of an ocular pathology characterized in that it comprises at least one eye ring (1) wherein the proximal end of said eye ring (1) is suitable to be applied onto the globe and a generator (2,17) to generate ultrasound beam fixed on the distal end of the eye ring (1), the generator to generate ultrasound beam presenting a concave segment shape conformed along a single curvature corresponding to a single direction wherein the concavity is designed to be tuned towards the eyeglobe.

Abstract: A method of treating an ocular pathology by generating high intensity focused ultrasound onto at least one eye's area, the method comprises at least the following steps of: positioning onto the eye a device capable of directing high intensity focused ultrasound onto at least one annular segment, and generating high intensity focused ultrasound energy onto the segment to treat at least one annular segment in the eye. Another embodiment of the invention concerns a device for treatment of an ocular pathology comprising at least one eye ring wherein the proximal end of the eye ring is suitable to be applied onto the globe and a high intensity focused ultrasound beam generator to generate ultrasound beam fixed on the distal end of the eye ring capable of treating the whole circumference of the eye in one step.

Abstract: The invention relates to methods comprising a step consisting of determining the proportion and/or the level of T regulatory lymphocytes with a CD4+ CD8??low Foxp3neg phenotype specific for Faecalibacterium prausnitzii for (i) diagnosing, (ii) prognosing outcome of, or (iii) predicting the risk of developing, an inflammatory bowel disease in a patient. The invention also concerns the treatment of an inflammatory bowel disease. The invention further relates to the kits that are useful in the above methods for diagnosing/prognosing an inflammatory bowel disease, and in the treatment of an inflammatory bowel disease. In a particular embodiment, the inflammatory bowel disease is the Crohn's disease.

Abstract: The method determines parameters to generate confocal ultrasound beams (B1,B2) inside a medium (4), and uses a device (1) comprising first and second ultrasound means (11,12) and first and second displacement members (13,14) for moving the ultrasound means (11,12). The parameters include signals s1,s2 to the ultrasound means (11,12), and the positions x1,x2 of the ultrasound means (11,12). The parameters are optimized for having a minimum amplitude a1,a2 of the signals s1,s2 and having an acoustic effect inside the medium (4).

Abstract: The present invention relates to an apparatus for the treatment of a brain affection, which comprises at least one implantable generator (4) made of non-ferromagnetic material comprising a casing (7), an ultrasound generating treating device (11) positioned into said casing to induce brain affection treatment by emission of ultrasound waves, and means for fastening the implantable casing into the skull. The apparatus further comprises a power controller (PwC) to supply electricity to the treating device of the implantable generator and to set and control its working parameters, and connecting means (6) to connect the power controller and the treating device of the implantable generator. A method for treating a brain affection with such an apparatus is also disclosed.

Abstract: The present invention relates to a device for treating an ocular pathology, including a ring (1) comprising a proximal end intended to be in contact with an eye of a patient, and a distal end intended to receive ultrasound generating means (2), wherein the device additionally includes at least one reflector (3) for reflecting and focusing ultrasound generated by the generation means.

Abstract: An interstitial ultrasound thermal ablation applicator for conformal treatment of inhomogeneous tumor lesions includes: a body having a longitudinal axis, the body defining a hollow central channel along the longitudinal axis; and a plurality of CMUT array transducers mounted on the body, arranged side by side to form a cylindrical shape, having azimuth plans parallel to a longitudinal axis of the body, each of the plurality of CMUT array transducers having elevation dimensions predetermined to steer emitted ultrasonic waves to obtain a conformal volume treatment of the tumor lesions. An electronic driving method for driving an applicator having multiple independent transducer elements arranged in rows and columns includes: controlling focal parameters of each row and column of transducer elements; and controlling a contribution of each row and column of transducer elements in a manner to provide a conformal ablated volume.