Abstract: A method for measuring at least one property of biological tissue, including: positioning an ultrasonic transducer opposite the biological tissue to be measured; generating an ultrasonic signal within the biological tissue; acquiring at least one ultrasonic signal reflected by the biological tissue; determining at least one parameter of the biological tissue using the acquisition of the ultrasonic signal reflected by the biological tissue, the at least one parameter being representative of the biological tissue; comparing the at least one parameter of the biological tissue with at least one reference parameter of a target biological tissue so as to confirm the hypothesis of the presence of the target biological tissue opposite the ultrasonic transducer; and determining at least one property of the biological tissue on the basis of the result of the comparison. The method can be directly used in the field of humans or animals.

Abstract: A method for determining, in real time, the probability that target biological tissue is opposite an ultrasonic transducer, the method including: transmitting, via an ultrasonic transducer, an ultrasonic signal into biological tissue; the ultrasonic transducer receiving the transmitted ultrasonic signal which has been backscattered by the biological tissue; calculating at least two instantaneous parameters of the backscattered ultrasonic signal; calculating a predictive value of the presence of an acoustic signature of target biological tissue, the predictive value being calculated via a statistical law using the at least two calculated instantaneous parameters; estimating the probability that the target biological tissue is opposite the ultrasonic transducer, the estimation depending on the calculated predictive value and/or on at least one strength condition based on at least one of the two calculated instantaneous parameters.

Abstract: An elastography device for quantitatively and/or qualitatively measuring the viscoelastic properties of any medium, includes a deformable tube for positioning the ultrasonic transducer located at the end of the deformable tube and for holding it so as to ensure, during at least one measurement, perpendicularity and contact between the ultrasonic transducer and the medium.

Abstract: A device for measuring an ultrasonic or biomechanical parameter of a viscoelastic medium, includes an ultrasound transducer; at least one vibrator having a fixed part and a mobile part, the ultrasound transducer being secured to the mobile part of the at least one vibrator; at least one adhesive element secured to the vibrator, the adhesive element being configured to be fixed adhesively to a surface facing it belonging to the viscoelastic medium and to keep the emission and reception face of the ultrasound transducer facing the surface.

Abstract: A method for determining, in real time, the probability that target biological tissue is opposite an ultrasonic transducer, the method including: transmitting, via an ultrasonic transducer, an ultrasonic signal into biological tissue; the ultrasonic transducer receiving the transmitted ultrasonic signal which has been backscattered by the biological tissue; calculating at least two instantaneous parameters of the backscattered ultrasonic signal; calculating a predictive value of the presence of an acoustic signature of target biological tissue, the predictive value being calculated via a statistical law using the at least two calculated instantaneous parameters; estimating the probability that the target biological tissue is opposite the ultrasonic transducer, the estimation depending on the calculated predictive value and/or on at least one strength condition based on at least one of the two calculated instantaneous parameters.

Abstract: The invention relates to an instrument for measuring the elasticity of a human or animal organ located behind the ribs. The instrument includes a casing having an actuator therein, the end of which is equipped with a transducer that is actuated in order to measure the elasticity of the organ. The measuring instrument also includes a mechanism for centering the transducer between the ribs.

Abstract: A device configured to measure the viscoelastic properties of biological tissues using a processing of ultrasound waves reflected by these tissues when a shear wave runs across them is presented. The device includes memories for forming lines of data such that each line comprises data relative to the ultrasound waves reflected from the same shot and a calculator for determining a parameter relative to the displacement between the tissues and a transducer emitting the shots, a calculator for calculating an intrinsic displacement of the medium from a set of lines forming an acquisition, and a processor for processing the first ultrasound lines, by using the relative parameter, before or during the formation of second ultrasound lines from this same acquisition, in order to determine the intrinsic displacement of the biological tissues from these first lines.

Abstract: A method for measuring at least one property of biological tissue, including: positioning an ultrasonic transducer opposite the biological tissue to be measured; generating an ultrasonic signal within the biological tissue; acquiring at least one ultrasonic signal reflected by the biological tissue; determining at least one parameter of the biological tissue using the acquisition of the ultrasonic signal reflected by the biological tissue, the at least one parameter being representative of the biological tissue; comparing the at least one parameter of the biological tissue with at least one reference parameter of a target biological tissue so as to confirm the hypothesis of the presence of the target biological tissue opposite the ultrasonic transducer; and determining at least one property of the biological tissue on the basis of the result of the comparison. The method can be directly used in the field of humans or animals.

Abstract: The present invention relates to a Method of measuring the viscoelastic properties of biological tissues employing an ultrasonic transducer equipped with elements converting the ultrasonic waves reflected by these biological tissues into electrical signals, different elements being grouped to form sub-apertures such that the acquisition of electrical signals from the elements of the same sub-aperture is carried out simultaneously, each of these sub-apertures being intercepted by an ultrasonic wave propagation axis at an acoustic center (Ca). In conformance with the invention, such a method is characterized in that one and the same element belongs to at least two different sub-apertures and in that an acoustic center is surrounded by at least three other unaligned acoustic centers.

Abstract: An elastography device for quantitatively and/or qualitatively measuring the viscoelastic properties of any medium, includes a deformable tube for positioning the ultrasonic transducer located at the end of the deformable tube and for holding it so as to ensure, during at least one measurement, perpendicularity and contact between the ultrasonic transducer and the medium.

Abstract: A device configured to measure the viscoelastic properties of biological tissues using a processing of ultrasound waves reflected by these tissues when a shear wave runs across them is presented. The device includes means for forming lines of data such that each line comprises data relative to the ultrasound waves reflected from the same shot and means for determining a parameter relative to the displacement between the tissues and a transducer emitting the shots, means for calculating an intrinsic displacement of the medium from a set of lines forming an acquisition, and means for processing the first ultrasound lines, by using the relative parameter, before or during the formation of second ultrasound lines from this same acquisition, in order to determine the intrinsic displacement of the biological tissues from these first lines.

Abstract: A device for measuring elasticity of a human or animal organ or viscoelastic media having an ultrasonic signal after ultrasonic illumination including at least one sensor including an ultrasonic transducer, at least one position sensor, an actuator to trigger the device connected by wire link to an electric power source, and a controlled electrodynamic actuator attached to the ultrasonic transducer that generates a transitory low-frequency impulse having a frequency range between about 1 Hz and about 5000 Hz.

Abstract: A device for measuring elasticity of a human or animal organ, or viscoelastic environments presenting an ultrasonic signal after ultrasonic illumination and consecutively establishing a representation in two or three dimensions of the elasticity, including at least one ultrasonic bar including a plurality of transducers, an excitor that generates and delivers a low-frequency, direct or indirect applied force, a receiver that acquires ultrasonic signals, a controller that commands and processes data, and a scanner that carries out scanning with the bar in one dimension (1D) or in two dimensions (2D) in two perpendicular directions, respectively, to obtain a representation of the measure of the elasticity in two (2D) or three dimensions (3D).

Abstract: A system and method are provided for an imaging system that may be used to measure the elasticity of an organ. In the system, an electronic transducer forms an image of a human or animal organ. A mobile part may be moved in translation or rotation, and is arranged to induce the propagation of low frequency vibration in the direction of the organ when actuated. The mobile part delivers the vibrational energy against the human or animal body. The transducer has a fixed part that also emits similar energy. By application of energy to the mobile and fixed parts, and by collection of energy, a control and calculation module may compute parameters of internal organs, such as elasticity.

Abstract: A device for measuring elasticity of a human or animal organ, or viscoelastic environments presenting an ultrasonic signal after ultrasonic illumination and consecutively establishing a representation in two or three dimensions of the elasticity, including at least one ultrasonic bar including a plurality of transducers, an excitor that generates and delivers a low-frequency, direct or indirect applied force, a receiver that acquires ultrasonic signals, a controller that commands and processes data, and a scanner that carries out scanning with the bar in one dimension (1D) or in two dimensions (2D) in two perpendicular directions, respectively, to obtain a representation of the measure of the elasticity in two (2D) or three dimensions (3D).

Abstract: A device for measuring elasticity of a human or animal organ or viscoelastic media having an ultrasonic signal after ultrasonic illumination including at least one sensor including an ultrasonic transducer, at least one position sensor, an actuator to trigger the device connected by wire link to an electric power source, and a controlled electrodynamic actuator attached to the ultrasonic transducer that generates a transitory low-frequency impulse having a frequency range between about 1 Hz and about 5000 Hz.