Abstract: A system includes an intraluminal device configured to be positioned within a body lumen of a patient, the intraluminal device comprising a proximal portion and a distal portion, wherein the intraluminal device further comprises: a sensor disposed at the distal portion; a proximal connector comprising a printed circuit board assembly (PCBA) configured to interface with a user console and disposed at the proximal portion; and a plurality of electrical wires connecting the sensor and the proximal connector, wherein the plurality of electrical wires are terminated at an angle on the PCBA such that the PCBA and electrical wires terminated thereon together are configurable to form a cross-section of 2 mm2 or less.

Abstract: A large aperture CMUT transducer array is formed of a plurality of adjacently located tiles of CMUT cells. The adjacent edges of the tiles are formed by an anisotropic etch process, preferably a deep reactive ion etching process which is capable of cutting through the die and its substrate while maintaining vertical edges in close proximity to the CMUT cells at the edge of the tile. This enables the CMUT cells of continuous rows or columns to exhibit a constant pitch over multiple CMUT cell tiles. The tiles also contain interconnect electrodes along an edge for making electrical connections to the tiles with flex circuit.

Abstract: An ultrasound device includes a transducer array (404) formed on a first side of a substrate (402). A through via (406) passes through a thickness of the substrate between the first side and a second side, opposite the first side. A conductor (410) is electrically coupled to the through via on the second side to provide signals to and from the transducer array.

Abstract: An imaging assembly for an intraluminal imaging device is provided. In one embodiment, the imaging assembly includes an imaging array positioned at a distal portion of the intraluminal imaging device. The imaging array may have a plurality of imaging elements arranged into subarrays. The imaging assembly also may include a micro-beam-former integrated circuit (IC) coupled to the imaging array at the distal portion of the intraluminal imaging device. The micro-beam-former IC includes a plurality of microchannels that may separately beam-form signals received from imaging elements of at least two subarrays. The imaging assembly further includes two or more signal lines that may couple to the micro beam-former IC. Each signal line may correspond to a specific subarray and may receive the beam-formed signals specific to corresponding subarray.

Abstract: A transducer device includes a transducer array (300) configured on a substrate (312). The substrate is configured to flex in accordance with a surface. The transducer array includes elements for transmitting and/or receiving acoustic energy. A shape sensing optical fiber (314) is disposed within the array and configured to shape sense a position of the elements in the array. Stiffeners (308) are connected to the array and configured to flex in accordance with the surface and provide a limit to an amount of flexure.

Abstract: A device for imaging within a body of a patient is provided. In one embodiment, the device includes a flexible elongate member that can be inserted into the body of the patient. The device also has an imaging assembly that is disposed at and extending a length of a distal portion of the flexible elongate member. The imaging assembly may include an array (302) of imaging elements that may have an outward surface and an inward surface. The imaging assembly may further include an integrated circuit (304) adjacent to the inward surface of the array of imaging elements. The device may further include a conductive plate (375) adjacent to and extending at least a portion of a length of the imaging assembly. The conductive plate may receive heat generated by at least one of the array of imaging elements or the integrated circuit.

Abstract: An intraluminal imaging device is provided. In one embodiment, the imaging device includes a flexible elongate member that may to be inserted into a body lumen within a patient. The flexible elongate member has a central longitudinal axis. The imaging device also has an imaging assembly that is disposed at a distal portion of the flexible elongate member. The imaging assembly comprises a flexible substrate and a plurality of ultrasound transducer elements. The plurality of ultrasound transducer elements are disposed on the flexible substrate. The flexible substrate is disposed around the central longitudinal axis of the flexible elongate member such that the ultrasound transducer elements are oriented to face away from the central longitudinal axis and the flexible substrate.

Abstract: An imaging catheter assembly is provided. The imaging catheter assembly includes an interposer including a multi-layered substrate structure, wherein the multi-layered substrate structure includes a first plurality of conductive contact pads coupled to a second plurality of conductive contact pads via a plurality of conductive lines; an imaging component coupled to the interposer via the first plurality of conductive contact pads; and an electrical cable coupled to the interposer via the second plurality of conductive contact pads and in communication with the imaging component.

Abstract: A matrix array probe including a transducer array and integrated circuitry coupled to the transducer elements dissipates heat generated by the array and integrated circuitry through the cover of the transducer probe. A pump in the probe connector pumps fluid through a closed loop system including inbound an outbound fluid conduits in the cable. The fluid conduits in the cable are separated by the cable electrical conductors for the probe. The heat transfer in the probe is done by a heat exchanger in the transducer backing block. Additional cooling may be provided by metal to metal contact with a chiller in the ultrasound system.

Abstract: An integrated circuit die (1) is disclosed that comprises a substrate (30) defining a plurality of circuit elements; a sensor region (10) on the substrate, the sensor region comprising a layer stack defining a plurality of CMUT (capacitive micromachined ultrasound transducer) cells (11); and an interposer region (60) on the substrate adjacent to the sensor region. The interposer region comprises a further layer stack including conductive connections to the circuit elements and the CMUT cells, the conductive connections connected to a plurality of conductive contact regions on an upper surface of the interposer region, the conductive contact regions including external contacts (61) for contacting the integrated circuit die to a connection cable (410) and mounting pads (65) for mounting a passive component (320) on the upper surface. A probe including such an integrated circuit die an ultrasound system including such a probe are also disclosed.

Abstract: A matrix array probe including a transducer array and integrated circuitry coupled to the transducer elements dissipates heat generated by the array and integrated circuitry through the cover of the transducer probe. A pump in the probe connector pumps fluid through a closed loop system including inbound an outbound fluid conduits in the cable. The fluid conduits in the cable are separated by the cable electrical conductors for the probe. The heat transfer in the probe is done by a heat exchanger in the transducer backing block. Additional cooling may be provided by metal to metal contact with a chiller in the ultrasound system.

Abstract: A backing block for an ultrasonic transducer array stack of an ultrasound probe is formed as a composite structure of graphite foam impregnated with an epoxy resin. The epoxy resin penetrates the porous foam structure at least part-way into the depth of the graphite foam block and, when cured, provides the backing block with good structural stability. The composite graphite foam backing block is bonded to the integrated circuit of a transducer to provide high thermal conductivity away from the transducer and good acoustic attenuation or scattering of rearward acoustic reverberations.

Abstract: A matrix array probe including a transducer array and integrated circuitry coupled to the transducer elements dissipates heat generated by the array and integrated circuitry through the cover of the transducer probe. A pump in the probe connector pumps fluid through a closed loop system including inbound an outbound fluid conduits in the cable. The fluid conduits in the cable are separated by the cable electrical conductors for the probe. The heat transfer in the probe is done by a heat exchanger in the transducer backing block. Additional cooling may be provided by metal to metal contact with a chiller in the ultrasound system.

Abstract: An ultrasound device includes a transducer array (404) formed on a first side of a substrate (402). A through via (406) passes through a thickness of the substrate between the first side and a second side, opposite the first side. A conductor (410) is electrically coupled to the through via on the second side to provide signals to and from the transducer array.

Abstract: A transducer device includes a transducer array (300) configured on a substrate (312). The substrate is configured to flex in accordance with a surface. The transducer array includes elements for transmitting and/or receiving acoustic energy. A shape sensing optical fiber (314) is disposed within the array and configured to shape sense a position of the elements in the array. Stiffeners (308) are connected to the array and configured to flex in accordance with the surface and provide a limit to an amount of flexure.

Abstract: An acoustic probe includes a plurality of acoustic array components separated and spaced apart from each other. Each of the acoustic array components includes: an array of acoustic element circuits disposed contiguous to each other at a first pitch; a plurality of pads each corresponding to one of the acoustic element circuits and formed within a circuitry area of the corresponding acoustic element circuit, the pads being disposed at a second pitch; a plurality of interconnection bumps each corresponding to one of the pads and being disposed in electrical connection with the corresponding pad, wherein the interconnection bumps are disposed at a third pitch; and a plurality of acoustic transducer elements on the interconnection bumps. The acoustic transducer elements are disposed at a fourth pitch. At least two of the first, second, third, and fourth pitches are different than each other.

Abstract: A large aperture CMUT transducer array is formed of a plurality of adjacently located tiles of CMUT cells. The adjacent edges of the tiles are formed by an anisotropic etch process, preferably a deep reactive ion etching process which is capable of cutting through the die and its substrate while maintaining vertical edges in close proximity to the CMUT cells at the edge of the tile. This enables the CMUT cells of continuous rows or columns to exhibit a constant pitch over multiple CMUT cell tiles. The tiles also contain interconnect electrodes along an edge for making electrical connections to the tiles with flex circuit.

Abstract: An ultrasound probe is formed with protected interconnects, thereby resulting in a more robust probe. The interconnects are mounted between an array of transducer elements and an integrated circuit. The array of transducer elements are coupled to the interconnect via flip chip bumps or other structures. Underfill material fixedly positions the interconnects to the integrated circuit. A method of making the transducer assembly is provided.

Abstract: The invention relates to a capacitive micro-machined ultrasound transducer (CMUT) cell (6) comprising a cell floor (31) having a first electrode (7); a cell membrane (5) having a second electrode (7?) which opposes the first electrode and vibrates during transmission or reception of acoustic energy; a transmitter/receiver coupled to the first and second electrodes which causes the cell membrane to vibrate at an acoustic frequency and/or receives signals at an acoustic frequency; and an acoustic lens (13), overlaying the cell membrane, and having an inner surface opposing the cell membrane and an outer, patient-facing surface. According to the present invention the acoustic lens comprises at least one layer of a material selected from the group of: polybudatiene, polyether block amide (PEBAX), polydimethylsiloxane (PDMS) and buthylrubber.

Abstract: The present invention relates to an ultrasound transducer assembly (100) comprising ultrasound transducer elements (175, 175a) for transmitting ultrasound waves in a general transmission direction (A). Each of or each of part of the ultrasound transducer elements (175, 175a) comprises a piezoelectric layer (110, 110a) having a top surface, a bottom surface and a side surface with respect to the general transmission direction (A), as well as a bottom electrode layer (111, 111a) and a top electrode layer (112, 112a). A conductive layer (125) is applied at least partly on the side surface of at least one specific one (110a) of the piezoelectric layers, such that the conductive layer (125) is connected to the top electrode layer (112a) and the bottom electrode layer (111a) of said specific piezoelectric layer (110a).