71 results about "Hyperintensity" patented technology

A novel contrast mechanism for imaging blood flow using magneto-motive optical Doppler tomography (MM-ODT), Optical Coherence Tomography, and Ultrasound. MM-ODT, OCT, and ultrasound combined with an externally applied temporally oscillating high-strength magnetic field detects erythrocytes moving according to the field gradient.

A medical apparatus (600, 700, 800, 900) comprising a high intensity focused ultrasound system (602) configured for generating focused ultrasonic energy (612) for sonicating within a target volume (620) of a subject (601). The high intensity focused ultrasound comprises an ultrasonic transducer (606) with a controllable focus (618). The apparatus further comprises a memory (634) containing machine executable for controlling the medical apparatus and a processor (628) for executing the instructions. Execution of the instructions causes the processor to cause (100, 200, 300, 400, 502) ultrasonic cavitations at multiple cavitation locations (622, 1002) within the target volume using the high intensity focused ultrasound system. Execution of the instructions further cause the processor to sonicate (102, 206, 306, 402, 504) multiple sonication locations (1004) within the target volume using the high intensity focused ultrasound system. The multiple sonication locations and the multiple cavitation locations are targeted by adjusting the controllable focus.

The present invention relates to a sound intensity and acoustical power measurement method of the high-strength focused ultrasound. The sound intensity and acoustical power measurement method of the present invention is characterized by selecting two mutually parallel first and second planes in a pre-focusing area of the high-strength focused ultrasound to measure, and using a PC to control a hydrophone to scan the sound pressure data on the first plane, and then using a servo motor to control the hydrophone to move along a Z direction accurately, repeating the above control and acquisition processes, and obtaining the sound pressure data on the second plane. The sound intensity and acoustical power measurement method of the high-strength focused ultrasound of the present invention has the remarkable characteristics of being simple and convenient to implement, efficient and accurate to calculate, etc., avoids measuring in a focusing area, can protect a sensor furthest, can obtain a plurality of parameters, such as the sound intensity distribution, etc., while obtaining the acoustical power, facilitates evaluating the performances of a focusing transducer comprehensively, and is suitable for measuring the radiation acoustical powers of various focusing transducers.

An ultrasound emission device (10) includes, within a case (12) having a watertight structure, an ultrasonic transducer (20), a power source (16), and a control unit (17). The ultrasonic transducer (20) is attached to the inside of the case (12) via an acoustic matching layer (22). An acoustic scattering layer (24) is provided on the outside of the case (12). The acoustic scattering layer (24) isformed from a material for which the acoustic impedance difference with water is large. One example of the acoustic scattering layer (24) is a wire net. High-strength ultrasonic waves (19) generated by the ultrasonic transducer (20) are scattered by the acoustic scattering layer (24) and emitted, as low-strength ultrasonic waves (21), to a wide area of a human body. The ultrasound emission device(10) can be floated on water inside a water tank (52), or can be used in the water inside the water tank (52). With the present invention, ultrasound stimulation can be applied to the bones of nearlythe entirety of the human body or of the entire body of a mammalian animal.

The invention provides an end sensitive fiber bragg grating high-intensity focused ultrasound sensor which has the grating region length L2, and a central position of a grating region is positioned within a range which covers a distance of L1 away from a single-mode fiber end. The end sensitive fiber bragg grating high-intensity focused ultrasound sensor provided by the invention has higher sound pressure sensitivity than that of a luminous intensity type fiber optic hydrophone which is based on a Fresnel end face reflection principle, is of a full quartz structure, adopts an end sensitive structure and has strong sound pressure bearing capability; compared with a lateral sensitive fiber bragg grating high-intensity focused ultrasound sensor, the end sensitive fiber bragg grating high-intensity focused ultrasound sensor is easy to clamp, is prevented from being damaged by shock wave and can overcome the disturbance of ultrasonic standing wave; different types of membranes are plated on the end sensitive fiber bragg grating high-intensity focused ultrasound sensor, so that the sound pressure resistance or the sound pressure sensitivity can be increased; the end sensitive fiber bragg grating high-intensity focused ultrasound sensor which is added into an annular tube sheath can be prevented from being damaged by the cavitation effect of a sound field; and the end sensitive fiber bragg grating high-intensity focused ultrasound sensor system is simple, and can satisfy requirements on MHz ultrasound measurement.

The invention relates to a method for splicing tunnel images without identification. A high-strength linear laser is adopted for assisting in marking, the position of imaging rays of laser rays on a camera is identified through an image detection algorithm, and the shot tunnel images are spliced and fused through the marked position. Transition of the image fusion edges is made even in a mode for averaging pixels with parameters near the laser rays.

The invention is disclosed to design a real-time pulse / echo system to perform 1-D real-time temperature measurement and integrate in the high-intensity focused ultrasound system. In the invention, a modified echo-time shifting algorithm is developed to calculate the corresponding phase shift from echo signal, which correlates with the instantaneous temperature change during heating process.

A therapeutic apparatus (300, 400, 500) comprising a high intensity focused ultrasound system (302) comprising an ultrasound transducer (306). The ultrasound transducer has an electronically adjustable focus (318). The high intensity focused ultrasound system has a beam deflection zone (322, 608, 704, 1010). The intensity of ultrasound at the electronically adjustable focus divided by the acoustic power emitted is above a predetermined threshold (606, 1008) within the beam deflection zone. The therapeutic apparatus further comprises a processor (328) for controlling the therapeutic apparatus. Execution of machine executable instructions (350, 352, 354) causes the processor to: receive (102, 202) real time medical data (342, 424, 506) descriptive of the location of a moving target (320, 802); adjust (104, 204) the electronically adjustable focus to target the moving target using the real time medical data; and sonicate (106, 206) the moving target when the moving target is within the beam deflection zone.