A transparent ultrasound transducer device for multi-mode optical imaging on a target is provided. The device includes a transparent piezoelectric transducer, one or more wires, and an optical lens. The transparent piezoelectric transducer of a first acoustic impedance is configured to receive acoustic waves from the target. The transparent piezoelectric transducer has a first surface and a second surface. The first surface and the second surface are coated with transparent electrically conductive coatings. The optical lens is contacted with and optically coupled to the first surface of the transparent piezoelectric transducer. The optical lens is made of a material with a second acoustic impedance, and the first and second acoustic impedances are substantially similar to minimize an acoustic impedance mismatch such that sensitivity of the device is improved.

A device comprises a miniature transducer having an altered backing geometry that can be placed within different casing sizes of an imaging probe device. The backing geometry extends along a longitudinal axis of the imaging probe and provides an angle (e.g., 45-degree angle) configured to reflect ultrasound and/or light waves/signals in a direction perpendicular to the longitudinal axis of the imaging probe. This design is configured to enable ultrasound and/or light waves/signals to be redirected and dampened within the transducer to preserve a suitable signal to noise ratio while minimizing the required depth of the backing.

In one embodiment, a medical data processing apparatus includes processing circuitry. The processing circuitry obtains medical data relating to a subject, and outputs medical diagnostic image data obtained by performing predetermined processing on the medical data, along with standardized medical image data based on the medical data, the standardized medical image data being standardized for machine learning without performing part or all of the predetermined processing.

A photoacoustic tomography system includes a first ring-shaped mirror having a central axis therethrough and configured to converge light inwardly towards the central axis and a subject, and an adjustment mechanism configured to move the first ring-shaped mirror along the central axis to a plurality of different positions. Each position of the plurality of different positions allows the first ring-shaped mirror to illuminate a respective ring of light around a respective portion of the subject, and an acoustic signal detector is movable along the central axis such that acoustic signals can be detected from the respective portion of the subject when illuminated by the first ring-shaped mirror while at each respective position of the plurality of different positions.

Apparatuses, systems, and methods for performing real-time analysis of bone tissue during a surgical procedure are disclosed herein. In some embodiments, the method includes receiving at least one measurement of at least one tissue sample from a hybrid multi-wavelength photoacoustic measurements (MWPM) component. The method can also include identifying one or more reference cases, from a plurality of reference cases, based on correlations between the at least one measurement and previous measurements in each of the plurality of reference cases. Once the reference cases are identified, the method can include determining at least one bone condition of the patient and sending the at least one determined bone condition to a computing device accessible by a surgeon. In some embodiments, the method also includes creating a three-dimensional (3D) map the tissue sample using the at least one measurement and sending the 3D map to the computing device.

An acoustic wave diagnostic apparatus 1 includes a display unit 7; an operation unit 16; a measurement item designation acceptance unit 13 that accepts designation of a measurement item; a detection and measurement algorithm setting unit 9 that sets a detection and measurement algorithm according to a measurement item; a position designation acceptance unit 14 that accepts designation of a measurement position; a measurement unit 8 that detects a measurement target and sets a caliper on the measurement target to perform measurement on the basis of the measurement position and the detection and measurement algorithm; a contour detection unit 10 that detects a contour of the measurement target; a caliper movable range limit unit 11 that limits a movable range of the caliper on the contour of the measurement target according to a modification request of the caliper; and a modification acceptance unit 15 that accepts a modification of the caliper through the operation unit 16, in which the measurement unit 8 performs measurement using the modified caliper.

A method of compressing tissue during a surgical procedure is disclosed. The method comprises obtaining a surgical instrument comprising an end effector, wherein the end effector comprises a first jaw and a second jaw, establishing a communication pathway between the surgical instrument and a surgical hub, and inserting the surgical instrument into a surgical site. The method further comprises compressing tissue between the first jaw and the second jaw, determining a location of the compressed tissue with respect to at least one of the first jaw and the second jaw, communicating the determined location of the compressed tissue to the surgical hub, and displaying the determined location of the compressed tissue on a visual feedback device.

A device and method of using the device to detect the presence and composition of clots and other target objects in a circulatory vessel of a living subject is described. In particular, devices and methods of detecting the presence and composition of clots and other target objects in a circulatory vessel of a living subject using in vivo photoacoustic flow cytometry techniques is described.

A surgical visualization feedback system is disclosed. The surgical visualization feedback system comprises an emitter assembly configured to emit electromagnetic radiation toward an anatomical structure. The emitter assembly comprises a structured light emitter configured to emit a structured light pattern on a surface of the anatomical structure and a spectral light emitter configured to emit spectral light capable of penetrating the anatomical structure. The surgical visualization feedback system further comprises a waveform sensor assembly configured to detect reflected electromagnetic radiation corresponding to the emitted electromagnetic radiation and a control circuit in signal communication with the waveform sensor assembly. The control circuit is configured to receive an input corresponding to a selected surgical procedure, determine an identity of a targeted structure within the anatomical structure based on the selected surgical procedure and the reflected electromagnetic radiation, and confirm the determined identity of the targeted structure through a user input.

This disclosure relates to a portable medical device comprising:

a medical equipment for the acquisition of data and a carrier system, wherein the medical equipment comprises:
a processing unit configured to process the data acquired using a probe linked to a processing unit,
and wherein the carrier system is configured to equip the body of the user of the device with the medical equipment.