Abstract: An ultrasound medical treatment system includes an end effector insertable into a patient. The end effector includes a tissue-retaining device. The tissue-retaining device includes a first tissue-retaining member having an ultrasound medical-treatment transducer and includes a second tissue-retaining member. The first and second tissue-retaining members are operatively connected together to retain patient tissue between the first and second tissue-retaining members and to release patient tissue so retained. In one example, the second tissue-retaining member has an ultrasound reflector. In the same or a different example, the ultrasound medical-treatment transducer is an ultrasound imaging and medical-treatment transducer.

Abstract: The present invention provides devices and methods for decalcifying an aortic valve. The methods and devices of the present invention break up or obliterate calcific deposits in and around the aortic valve through application or removal of heat energy from the calcific deposits.

Abstract: An ultrasound based technique for detecting and imaging vibrations in tissue caused by eddies produced during bleeding through punctured arteries or from organs. A clutter signal, normally suppressed in conventional color flow imaging, is employed to detect and characterize local tissue vibrations, to detect internal bleeding in an image, or as an audible or palpable signal, or a readout. Using a tissue vibration image, the origin and extent of vibrations relative to the underlying anatomy and blood flow can be visualized in real time, enabling measurements of vibration amplitude, frequency, and spatial distribution. Bleeding rate can be determined from the frequency and amplitude of the vibrations. Signal processing algorithms usable to identify tissue vibrations from an ensemble of 2D ultrasound data include those based on phase decomposition, spectral estimation using eigendecomposition, and spectral estimation using autoregressive modeling for isolating vibrations from clutter, blood flow, and noise.

Abstract: An ultrasonic diagnostic apparatus including: an ultrasonic observation device that transmits and receives an ultrasonic wave by an ultrasonic transducer arranged on a tip end of a probe, and that acquires a plurality of two-dimensional ultrasonic tomographic images for a subject in a living body; a position data calculator that detects information indicating a reference position of each of the two-dimensional ultrasonic tomographic images and an orientation of a tomographic plane of the each two-dimensional ultrasonic tomographic image; and an image processor is provided. The image processor generates a band-shaped longitudinal image including a curved plane along a moving path of the ultrasonic transducer.

Abstract: An integrated ultrasound and nerve stimulation system, ultrasound probe and method are provided. The system may include a transcutaneous electrode adapted for external placement on a patient, a percutaneous electrode having an electrically-conducting tip adapted for percutaneous placement proximate a nerve in the patient and a control for causing a current to flow between the electrodes. The system may also include a probe having an ultrasound transducer that transmits ultrasound waves into the patient and receives reflected ultrasound waves from the patient. The probe also has a communication interface for transmitting a signal representative of the received reflected ultrasound waves to a main unit. The main unit is in operative communication with the communication interface and includes a display and a processor, which receives the signal from the probe and causes the display to display an image in accordance with the received signal.

Abstract: The invention relates to an ultrasonic imaging system having an ultrasound intra-esophageal endoscope device for scanning a patient's organs, for use in particular with transesophageal echocardiography, and an intratracheal transmission device defining a transmission path for sound waves originating from the endoscope device. A transmission device is specially adapted for use with an endoscope device in an ultrasonic imaging system having a flexible balloon member connected to a supply line for a sound wave transmission fluid medium.

Abstract: A transducer assembly is provided including a transducer array comprising a plurality ‘M’ of transducer elements and a sub-aperture processor comprising a plurality ‘P’ of input channels and an output channel. The plurality ‘P’ of input channels is coupled to the ‘M’ transducer elements and a plurality ‘R’ of switching elements in operative association with the output channel of the sub-aperture processor to switchably couple the output channel to at least one of a plurality of ‘N’ system channels.

Abstract: This ultrasonic diagnostic apparatus includes an image constructing circuit (31) for creating plural ultrasonic tomographic images resulting from a process in which an ultrasonic endoscope moves within a body cavity, a position detecting portion (13) for detecting position information of the ultrasonic tomographic images, an image processing circuit (33) for constructing tomographic parallel images resulting from arrangement of plural ultrasonic tomographic images along a scanning path of the ultrasonic endoscope based on the position information, and a display circuit (34) causing a monitor (14) to display an ultrasonic tomographic image and tomographic parallel images so as to compare them. In this ultrasonic diagnostic apparatus, when an ultrasonic image is displayed on the monitor, a spread and depth of an invasion of an affected part are displayed based on ultrasonic image data within a body cavity.

Abstract: A method of real time ultrasound imaging of an object in at least three two-dimensional scan planes that are rotated around a common axis, is given, together with designs of ultrasound transducer arrays that allows for such imaging. The method is also introduced into a monitoring situation of cardiac function where, combined with other measurements as for example the LV pressure, physiological parameters like ejection fraction and muscular fiber stress is calculated.

Abstract: The present invention provides an ultrasound probe in which bend of a tip part is fixed only in a state that it is not bent in a direction orthogonal to a direction in which ultrasonic waves are emitted from an ultrasound generation source. To be specific, the ultrasound probe includes: a rod-like tip part inserted into a body cavity; an ultrasound emitting part placed at the tip part to emit ultrasonic waves to a subject; a first bending part for bending the tip part in a direction substantially orthogonal to the emission direction; and a fixing part configured to, when the first bending part is not bending the tip part toward any side of the direction orthogonal to the emission direction, lock a rotation member of the first bending part and inhibit the first bending part from bending the tip part in the direction substantially orthogonal to the emission direction.

Abstract: A distal hard part in an insertion portion is provided with an ultrasonic transducer in which a large number of ultrasonic vibrators are arranged in the circumferential direction. The ultrasonic transducer is shaped like a cylinder. Each member that constitutes an endoscopic observation section is passed through this tunnel-like passage. Each ultrasonic vibrator is provided with a single common electrode and individual electrodes the number of which corresponds to the number of the ultrasonic vibrators. Flexible boards and are provided on the proximal and distal end sides of the ultrasonic transducer. Wires are connected to these flexible boards. The wires from the flexible board are extended without changes, whereas the wires from the flexible board are reversely turned from the distal end side, are then passed through the tunnel-like passage, and are extended in the direction of an angle part.

Abstract: An image diagnostic system controls a probe to perform radial scanning within a body cavity, to acquire reflected signals through the probe and to produce data based on the signals. The system includes plural storage units for storing the data in line units, respectively, a writing control unit for controlling writing processing in accordance with a transmission/reception timing of the signals, and a reading control unit for controlling reading processing in accordance with rotation angles of the probe. The writing control unit writes data in the storage unit, other than the storage unit being subjected to reading processing, storing the oldest data. The reading control unit reads the data from the storage unit, other than the storage unit being subjected to writing processing, storing the latest data. The tomographic image is constructed based on the data read by the reading control unit.

Abstract: An imaging system of an object in an imaged subject is provided. The imaging system includes an image detector and a guidewire in support of a pair of markers. The imaging system also includes a controller in communication with the image detector. The controller includes a processor in communication to execute a series of programmable instructions stored in a memory, the programmable instructions including acquiring a plurality of acquired images, detecting a position of the pair of markers, calculating a first mathematical representation of an alignment of the guidewire between the markers and a second mathematical representation of an alignment of the guidewire not between the markers, and registering the first and second mathematical representations of the guidewire extending through the object relative to more than one of the acquired images so as to locate the object in at least one of the acquired images.

Abstract: A noninvasive technique that can be used to deny blood flow to a particular region of tissue, without the inherent risks associated with invasive procedures such as surgery and minimally-invasive procedures such as embolization. Blood flow in selected portions of the vasculature can be occluded by selectively treating specific portions of the vasculature with high intensity focused ultrasound (HIFU). The occlusion denies undesired tissue the nutrients and oxygen provided by blood flow, causing necrosis in the undesired tissue. An imaging technology (such as magnetic resonance imaging, magnetic resonance angiography, ultrasound imaging, Doppler based ultrasound imaging, or computed tomographic angiography) is used to identify the undesired tissue, and the vascular structures associated with the undesired tissue.

Abstract: Transesophageal echocardiography is implemented using a miniature transversely oriented transducer that is preferably small enough to fit in a 7.5 mm diameter probe, and most preferably small enough to fit in a 5 mm diameter probe. Signal processing techniques improve the depth of penetration to the point where the complete trans-gastric short axis view of the left ventricle can be obtained, despite the fact that the transducer is so small. The reduced diameter of the probe (as compared to prior art probes) reduces risks to patients, reduces or eliminates the need for anesthesia, and permits long term direct-visualization monitoring of patients' cardiac function.

Abstract: Transesophageal echocardiography is implemented using a miniature transversely oriented transducer that is preferably small enough to fit in a 7.5 mm diameter probe, and most preferably small enough to fit in a 5 mm diameter probe. Signal processing techniques improve the depth of penetration to the point where the complete trans-gastric short axis view of the left ventricle can be obtained, despite the fact that the transducer is so small. The reduced diameter of the probe (as compared to prior art probes) reduces risks to patients, reduces or eliminates the need for anesthesia, and permits long term direct-visualization monitoring of patients' cardiac function.

Abstract: An ultrasonic horn includes a main body portion and a distal end structure formed at a distal end of the main body portion, the ultrasonic horn being adapted to be used to cut living tissue. The largest outer diameter of a portion of the ultrasonic horn is in the distal end structure, the portion being inserted into the living tissue when the living tissue is cut.

Abstract: A medical system is a medical device, such as a catheter, that includes an inner core and an imager that is extendable from within an elongated tubular member and configured to penetrate a body tissue within a living body. The elongated tubular member has a distal end and is configured to slideably receive the inner core. The distal end is further configured to allow the inner core to advance outside the elongated member. The inner core has a distal end and is configured to rotate radially around a longitudinal axis of the elongated member. The device can further include an imager located at the distal end of the inner core, and the imager can be configured to image a body tissue and output an image signal to an imaging system communicatively coupled with the imager. The imaging system is configured to generate an image of the body tissue from the image signal of the imager when the imager is rotated and placed into contact with the body tissue such that the imager penetrates the body tissue.

Abstract: An imaging system is provided with an ultrasound catheter and a controller coupled to the ultrasound catheter. The catheter includes a localizer sensor configured to generate positional information for the ultrasound catheter, and an imaging ultrasound sensor having a restricted field of view. The controller co-registers images from the imaging ultrasound sensor with positional information from the localizer sensor.

Abstract: A pressing device for smoothly performing pressing operation, an ultrasonic probe, and an ultrasonic diagnostic apparatus are provided. The pressing device has a balloon installed on an ultrasonic transmission/reception surface of an ultrasonic probe and presses an object to be examined by the balloon. The balloon has a hollow pressing unit made of an elastic material, a tube for charging/discharging liquid to/from the pressing unit, and an attachment part contiguous to the peripheral edge of the pressing unit and attaching the pressing unit to the ultrasonic transmission/reception unit of the ultrasonic probe. The inner diameter of the attachment part or the pressing unit is set smaller than the outer diameter of the part of the ultrasonic probe on which the attachment part is attached. Because tension is applied to the pressing unit, pressing operation can be started with a less amount of initial injection, and this makes the pressing operation smooth.

Abstract: An ultrasonic image scanning system for scanning an organic object includes a container for containing a coupling medium for transmitting an ultrasonic signal to the organic object disposed therein whereby a simultaneous multiple direction scanning process may be carried out without physically contacting the organic object. The ultrasonic image scanning system further includes ultrasound transducers for transmitting the ultrasonic signal to the organic object through the coupling medium without asserting an image deforming pressure to the organic object. These transducers distributed substantially around a two-dimensional perimeter of the container and substantially at symmetrical angular positions at approximately equal divisions of 360 degrees over a two-dimensional perimeter of the container. The transducers are further movable over a vertical direction alone sidewalls of the container for a real time three dimensional (3D) image data acquisition.

Abstract: In order to improve the quality of cross-sectional images, which have been recorded along a longitudinal axis of a vessel of a body, it is proposed to add successive cross-sectional images to an overall cross-sectional image. Artifacts in the cross-sectional images are hereby weakened and pathological structures to be detected are high-lighted.

Abstract: An ultrasonic diagnostic apparatus includes an ultrasonic transducer housed in a catheter for sending an ultrasonic wave to a blood vessel and receiving a reflected signal from the blood vessel, an A/D converter for converting the received reflected signal into a digital signal, a data averaging processor for storing lines or frames of digital data represented by the digital signal and adding the stored lines or frames of the digital data to average the reflected signal, a demodulating/logarithmic converting processor for demodulating the averaged reflected signal, an image constructor for constructing an image in a radial scan B mode from the demodulated signal, and a display unit for displaying the constructed image in the radial scan B mode. The ultrasonic diagnostic apparatus plots a cross-sectional vascular image with a reduced ultrasonic echo reflected from blood cells, the image clearly displaying the boundary between the blood vessel wall and the blood vessel lumen.

Abstract: An ultrasound probe for three-dimensional scanning and focusing of an ultrasound beam in both an azimuth direction and an elevation direction normal to the azimuth direction. The probe is composed of an ultrasound transducer array which has a linear division of the elements in the azimuth direction for electronic steering of the beam direction and focus in the azimuth direction. The array elements have a coarse division in the elevation direction for electronic steering of the focus in the elevation direction, and possibly small angle direction steering of the beam in the elevation direction for parallel receive and/or transmit beams. Large angle direction scanning of the beam in the elevation direction is obtained by mechanical rotation of the array around an axis. The invention implies useful embodiments for insertion of the probe into the body, through mounting the array at the distal tip of an elongated device.

Abstract: In an ultrasonic probe including an insert section which is to be inserted into a body cavity organ of a subject and a handle section which is coupled with the insert section, a plurality of vibrator elements (104) are disposed at a tip end of the insert section over the entire 360 degree circumference thereof and in the handle section, a connection change over switch (105) is disposed which successively changes over the electrical connection of a predetermined number of the vibrator elements among the plurality of the vibrator elements to be connected with a predetermined number of ultrasonic wave transmission and reception channels (701,702) in an ultrasonic diagnostic apparatus main body for transmitting and receiving ultrasonic wave signals.

Abstract: There is provided a pulse detecting device which resists fluctuations in the quality by locating an ultrasound transmitting piezoelectric element and an ultrasound receiving piezoelectric element with high precision. In the pulse detecting device, a detection sensitivity of the pulse is improved. A transmitting piezoelectric element and a receiving piezoelectric element are fixed onto a substrate by electrodes. The transmitting piezoelectric element is excited in response to an inputted drive voltage signal to generate an ultrasound and transmits the generated ultrasound to a living body. The receiving piezoelectric element receives an echo produced by reflecting the ultrasound transmitted into the living body by a blood flow of the living body and converts it into a voltage signal. A processing arithmetic unit compares the frequency of the ultrasound generated by the transmitting piezoelectric element with that of the echo received in the receiving piezoelectric element to thereby detect a pulse.

Abstract: A method for determining the distance of a transceiver located within a lumen from the center of the lumen and for determining the radius of the lumen, the lumen cross-section being substantially circular at the transceiver location, the method applied on data received from a transceiver placed at a position within the lumen that is distance (r) from the center and distance (a) from the lumen wall, transmitting a signal of known velocity (v) that can be correlated with the time of flight and receiving a first signal and a second signal that are reflections of the transmitted signal, timing the time differences between the transmission of the transmitted signal and reception of the first (t1) and second (t2) reflection signals, the method comprising: Calculating the distance of the transceiver from the center of the lumen=(t1?t2)v/4; and Calculating the radius of the lumen=(t1+t2)v/4.

Abstract: A transducer array is connected with a catheter housing. As the transducer array is rotated, the catheter housing also rotates. As a result, at least a portion of the catheter housing twists about a longitudinal axis. By applying rotation in a controlled way, such as with a motor, a plurality of two-dimensional images for three-dimensional reconstruction may be obtained. The rotation of the catheter housing may limit the total amount of rotation of the array, such as rotating the array through a 90 degree or less amount of rotation about the longitudinal axis. The housing of the catheter is formed with a soft section. The softer material allows for a greater amount or increased ease for twisting the catheter.

Abstract: A flexible elongate member such as a pressure guide wire (1000) includes an electrical device such as a pressure sensor (1002). The pressure sensor (1002) is electrically connected to conductive bands (304), (306) and (308) located on electrical connector (300). The electrical connector is attached to core wire (602) and shaft or hypotube (704). The use of electrical connector (300) helps minimize the assembly time of pressure guide wire (1000), as well as minimize some of the assembly problems associated with prior art designs such as pressure guide wire (100).

Abstract: A needle guide includes a straight conduit having a linear passage of an inner diameter that allows passage of the needle and a funnel for increasing the diameter of an opening of the straight conduit at a second end wherein a distance from a center of an opening of the funnel to an ultrasonic probe body is larger than a distance from a center of an opening of the straight conduit at a first end to the ultrasonic probe body.

Abstract: A transducer array is connected with a catheter housing. As the transducer array is rotated, the catheter housing also rotates. As a result, at least a portion of the catheter housing twists about a longitudinal axis. By applying rotation in a controlled way, such as with a motor, a plurality of two-dimensional images for three-dimensional reconstruction may be obtained. The rotation of the catheter housing may limit the total amount of rotation of the array, such as rotating the array through a 90 degree or less amount of rotation about the longitudinal axis. The housing of the catheter is formed with a soft section. The softer material allows for a greater amount or increased ease for twisting the catheter.

Abstract: The present invention relates to a new intravascular imaging device based on a Shape Memory Alloy (SMA) actuator mechanism embedded inside an elongate member such as a guide wire or catheter. The present invention utilizes a novel SMA mechanism to provide side-looking imaging by providing movement for an ultrasound transducer element. This novel SMA actuator mechanism can be easily fabricated in micro-scale, providing an advantage over existing imaging devices because it offers the ability to miniaturize the overall size of the device, while the use of multiple transducer crystals maximizes field of view. Also disclosed are methods of using the same.

Abstract: A method and a device (1) for ultrasound measurement of the blood flow through a heart valve are proposed. To permit a simple, automated measurement, it is proposed that the measurement area (9) of a measurement beam (7) is moved three-dimensionally by means of a multi-array transducer (11) and continuously evaluated for characteristic Doppler signals. It is further proposed to evaluate several measurement beams (7) with offset spatial, partially overlapping measurement areas (9) and/or several reference beams (8) with offset spatial measurement areas (10) for determination of the opening surface area, the volumetric flow rate, the flow volume and/or a value proportional thereto.

Abstract: The present invention relates to a device for moving a transducer of an ultrasonic probe in an ultrasonic diagnostic apparatus for acquiring a 3-dimensional ultrasound image. A motor for generating power to move the transducer and guide rails for guiding the movement of the transducer are mounted to the frame. The rotational force of a driving shaft of the motor is transmitted to a driven shaft through pulleys and belts. A portion of a wire is wound around the driven shaft and both ends of the wire are fixed to two opposing surfaces of the transducer. A reel having a spiral groove on the peripheral surface is coupled to the driven shaft. The wire is wound along the spiral groove.

Abstract: Methods and systems are provided for generating graphical representations of orifices and vessels. One method comprises generating a representation of the surface (e.g., an endocardial surface) within a coordinate system, and laterally moving the distal end of an elongated probe within an orifice (e.g., a valve or a vessel ostium) associated with the surface. The method further comprises defining line segments within the coordinate system while the probe distal end is moved within the orifice, wherein each of the line segments represents the probe distal end. The method further comprises defining intersection points within the coordinate system, wherein each of the points represents an intersection of one of the line segments and the surface representation. Lastly, the method comprises graphically generating a representation of the orifice based on the intersection points, e.g., by forming the orifice representation around the intersection points.

Abstract: A position of an imaging plane relative to a catheter or other probe is aligned with tissue of interest. Ultrasound tissue images may be registered to the catheter position with minimal rotational ambiguity. The spatial position of an ablation catheter or other device with respect to the imaging plane is more accurately determined, allowing a physician to identify specific anatomy in the relative location of a catheter or catheters. Another alternative or additional approach to determining the position of an imaging plane is to determine the relative position of two or more catheters. A catheter associated with imaging is then moved or bent in a direction having a known spatial relationship with the imaging plane. The position of the catheter is relative to each is then determined again to determine the angle or position of the imaging plane.

Abstract: An apparatus and method for rendering for display forward-looking image data. The apparatus includes rendering for display image data from a forward-looking conical section of tissue collected by an image data collection device, comprising a data input unit configured to receive the image data; and an image data processing unit configured to rasterize the image data onto a projected three-dimensional geometric model to produce a rasterized image, thereby giving the appearance of three-dimensions when displayed. The method includes a method of rendering for display image data from a forward-looking conical section of tissue collected by an image data collecting device, comprising receiving the image data; and rasterizing the image data onto a projected three-dimensional geometric model to produce a rasterized image, thereby giving the appearance of three dimensions when displayed.

Abstract: An automatic pullback catheter system (2) includes a disposable catheter assembly (6) mountable to a drive assembly (4). The drive assembly includes a body (8) to which a drive. chassis (14) is mounted for movement along a longitudinal path (16) by a motor (20) which rotates a longitudinal drive screw (22) selectively coupled to the drive chassis by a threaded clamp (24). A rotary drive motor (30), mounted to the drive chassis, rotates a first combined connector (34). The catheter assembly includes a hollow sheath (38) housing a rotatable and axially movable cable assembly (44). The sheath includes a proximal hub (42) mountable to the body. The cable assembly includes an elongate imaging cable (46) with a second combined connector (36) at its proximal end. The first and second combined connectors are blind matable connectors and provide for the longitudinal movement coupling, the rotary movement coupling and the data/information connection of the two connectors.

Abstract: A capsule-type medical apparatus includes a capsule to be introduced into a tubular body cavity, and a string member that extends from one end of the capsule and is able to be pulled when the capsule is pulled.

Abstract: The invention relates to a method of determining the position of a catheter introduced along a guide wire inserted into a body, in which method an image of the guide wire and the body region at the area of the guide wire is acquired by means of an imaging method, the distance traveled by the catheter on the guide wire is measured and the position of the catheter in the body is determined on the basis of the measured distance. The invention also relates to a device for determining the position of a catheter introduced along a guide wire inserted into a body, which device includes sensor means for measuring the distance traveled by the catheter on the guide wire and means for determining the position of the catheter on the basis of the measured distance.

Abstract: A probe for insertion into a living body includes a sheath configured to be inserted into a living body, and a shaft positioned in the sheath. The shaft includes a tip portion configured to obtain diagnostic data at a distal portion thereof. The sheath includes a resin layer or a metal layer of at least one layer, and wherein the resin layer or the metal layer includes a spiral-shaped slit which is continuous from a distal portion to a proximal portion. The spiral-shaped slit includes a distal slit portion having the highest slit density, a middle slit portion which is continuous with the distal slit portion and which also has a lower slit density than the distal slit portion, and a proximal slit portion which is continuous with the middle slit portion and which also has a higher slit density than the middle slit portion.

Abstract: An ultrasonic diagnosis system includes an ultrasonic diagnosis device for diagnosis according to a signal from a first ultrasonic probe for extracorporeal use. A second ultrasonic probe detects an object for in-vivo diagnosis. An adapter inputs and/or outputs between the ultrasonic diagnosis device and the second ultrasonic probe. The adapter includes a holder chamber for holding the ultrasonic diagnosis device. A diagnosis device connector is for connection with the ultrasonic diagnosis device. A probe connector is for connection with the second ultrasonic probe. An input/output device is for transmission and/or reception between the probe connector and the diagnosis device connector. In addition to the ultrasonic diagnosis device, a picture-in-picture processing unit operates for picture-in-picture processing of an ultrasonic or endoscopic image. Furthermore, a processor connector is for connection with an endoscope processor for receiving a signal from the endoscope to create an endoscopic image.

Abstract: In an ultrasonic endoscope, excessive temperature rise due to heat generated from ultrasonic transducers and/or an image pickup device is prevented. The ultrasonic endoscope includes: an ultrasonic transducer part including plural ultrasonic transducers for transmitting and receiving ultrasonic waves, and a backing material provided on a back of the plural ultrasonic transducers and having plural signal terminals provided on a surface opposite to the plural ultrasonic transducers; a signal line holding part including a highly heat conducting filler filling a space holding a group of shield lines electrically connected to the ultrasonic transducers via the plural signal terminals, and coupled to the backing material; and a highly heat conducting layer provided in contact with the signal line holding part, and thereby coupled to the signal line holding part.

Abstract: The apparatus and methods described herein enable an operator to simultaneously collect images and spectroscopic information from a region(s) of interest using a multiple modality imaging and/or spectroscopic probe, configured as a catheter, endoscope, microscope, or hand held probe. The device may incorporate, for example, an ultrasonic transducer and a fiber optic probe to translate images and spectra. The apparatus and methods may be used in any suitable cavity, for example, the vascular system of a mammal.

Abstract: The present invention relates to an ultrasonic probe including a piezoelectric element, a first acoustic matching layer provided on the front face of the piezoelectric element and formed of a solid inorganic material, and a second acoustic matching layer provided on the first acoustic matching layer and formed of a mixture of an organic resin and 10 to 30% by volume of oxide powder with a density of 6.5 g/cm3 or more.

Abstract: The present invention relates to a method and apparatus for imaging the mechanical properties of a tissue region from within an endocavity of a patient. The apparatus generally comprises an ultrasound probe, a vibration assembly translationally coupled to probe and operable to vibrate the probe along a vibration plane, and a rotation assembly rotationally coupled to the vibration assembly and operable to rotate the probe and vibration assembly about a selected rotational range. The method generally comprises inserting an ultrasound probe into an endocavity of a patient, vibrating the probe along a vibration plane thereby causing deformational excitement of a tissue region contacted by the probe, capturing a first series of ultrasound images of the tissue region, rotating the vibration plane relative to the tissue region by a selected angular rotation, and capturing a second series of ultrasound images of the tissue region.

Abstract: A transducer wiring pad group provided in a distal end portion of an ultrasound transducer printed circuit board provided with signal patterns that transmit and receive signals to and from a plurality of ultrasound transducers, a flexible printed circuit board wiring pad group arranged in a longitudinal axis direction of the ultrasound transducer printed circuit board, a second signal pattern group that is connected between the transducer wiring pad group and the flexible printed circuit board wiring pad group and bends at substantially degrees in the middle thereof, and a relay flexible printed circuit board that is connected to the flexible printed circuit board wiring pad group and changes a direction of a signal pattern into the longitudinal axis direction are provided.

Abstract: An acoustic access disconnect detection system is useful for detecting when an access needle has become dislodged or when blood is leaking. The acoustic disconnect detection system includes an acoustic transmitter and one or more acoustic sensors placed upstream of an access site of a patient, the sensors suitable for generating and detecting an acoustic signal that is intended to pass unobstructed through the access site. The acoustic transmitter may be placed on a therapy machine for generating an acoustic signal. The acoustic sensor is mounted downstream of the transmitter, such as on the therapy machine where blood is pumped to or returned from the patient, on the patient, or on the therapy machine where blood is entering the therapy machine. The therapy machine, such as a dialysis machine, may be programmed not to start or continue operation unless the acoustic signal is within certain parameters.

Abstract: The present invention provides intravascular diagnostic catheters that include a centrally disposed intravascular ultrasound (IVUS) imaging element and radially extendable, wall-contacting optical probe arms of a novel design for improving the IVUS imaging aspect of combined IVUS and optical analysis. In one embodiment, the dimension of the portion of the probe arm(s) that is in the field-of-view of the IVUS imaging element is minimized. In another embodiment, thin tethers are disposed in the field-of-view of the IVUS imaging element, rather than a continuation of the probe arm itself into the IVUS field. In still another embodiment, the probe arms at least substantially do not impinge on the field-of-view of the IVUS imaging element and tethers that are not within the field-of-view of the IVUS imaging element are used to control the probe arms, thereby providing a clear field-of-view for the IVUS imaging element.

Abstract: A ultrasonic transducer of the invention comprises: a transducer cell including a first electrode and a second electrode disposed separated from the first electrode by an air gap portion; and an electret for applying a potential difference between the first electrode and the second electrode. The electret is disposed in a region where at least a part thereof does not overlap with the transducer cell when viewed from a transmitting direction of ultrasonic waves.