Systems and methods can include a system for positioning an ultrasound probe proximal to anatomy of a patient on a radiation couch including a substantially planar base including engagement features to directly or indirectly index the substantially planar base to the radiation couch and a centrally located guide extending longitudinally along a top side of the base, a probe holder, configured to be coupled to, to translate longitudinally, and to be user-accessed and user-controlled from within, a central region of the substantially planar base, a clamp, configured to localize the probe holder at a specified location along a translation path in the central region of the substantially planar base, leg supports shaped to accommodate a patient's legs from behind, the pair of leg supports being shaped and arranged to provide a space therebetween that can accommodate an ultrasound probe holder.

A treatment head (20, 20) includes an ultrasound imaging probe (22) which generates a sonogram (24) of internal anatomy of a subject (25), and a HIFU transducer 26 which emits HIFU energy (31) into the subject. A chair (28) includes a chair-frame (30) and a seat (32). When the subject is sitting in the chair, a perineum (34) of the subject is acoustically coupled to the treatment head. Control circuitry (36) (a) controls movement of the treatment head relative to the seat, (b) operates the ultrasound imaging probe to generate at least one sonogram of internal anatomy of the subject through the perineum of the subject, and (c) operates the HIFU transducer to emit HIFU energy into the body of the subject through the perineum of the subject. Other embodiments are also described.

Disclosed is a robotic ultrasound system comprising an ultrasound probe and a transport mechanism for moving the ultrasound probe in at least one direction. The robotic ultrasound system also comprises a scanning bed comprising the transport mechanism and the ultrasound probe, the scanning bed having a fluid filled portion for the ultrasound probe, wherein a fluid of the fluid filled portion allows transmission of ultrasound waves from the ultrasound probe to a surface of the robotic ultrasound system.

A robotic system for performing an automatic ultrasound scan on a body part of a patient. The system comprises a support surface for supporting the body part, a display, and a robotic arm. The robotic arm is configured to hold an ultrasound probe and move the ultrasound probe to obtain the automatic ultrasound scan of the body part supported by the support surface. The display is integrated into the support surface and adapted for supporting at least part of the body part to be scanned.

A system and method of producing a medical support device is disclosed. The disclosure determining a three-dimensional shape of the medical support device for supporting an anatomical body part of a patient, the method executed by a computer and including acquiring body part geometry data describing a geometry of the anatomical body part; acquiring medical procedure data describing a medical procedure to be carried out on the patient; acquiring atlas data describing a general three-dimensional shape of the anatomical body part; determining, based on the body part geometry data and the medical procedure data and the atlas data, support device geometry data describing the geometry of the support device. The method and system further includes generative forming of the device by issuing at least one control command to the generative forming device for forming the medical support device based on the support device geometry data.

Described herein are systems and methods of processing immobilization molds for application of treatment, A computing system may generate a three-dimensional mold model of immobilization mold within with a subject is to be positioned for application of a treatment. The computing system may subtract a three-dimensional scan of at least a portion of the subject from the three-dimensional mold model to define an opening therein. The computing system may remove, from the three-dimensional mold model, a first portion to define an imprint in the opening from a first axis along which the subject is to enter. The computing system may remove, from a second portion of the three-dimensional mold model remaining with the removal of the first portion, inward protrusions into the imprint of relative to the second axis intersecting the first axis.

An acoustic wave apparatus is used, the apparatus comprising: a supporting member supporting an examinee and having insertion opening; a subject holding member holding the subject; a transducer array including transducers and being distant from the subject holding member; a load acquiring unit acquiring a load value applied between the supporting member and the subject holding member based on an amount of deformation of the subject holding member; a memory unit storing a first load reference value determined based on the amount of deformation of the subject holding member and an area applied with the load when the subject holding member and the transducer array come into contact with each other; a comparing and determining; and an interlock controlling unit.

Systems, processes, and apparatuses are provided for imaging a body part of a patient such as an eye of the patient. In some embodiments, a process is provided for adjusting the readings from an ultrasound probe to account for the different speeds of sound through different portions of the eye. In various embodiments, a process is provided for combing multiple images of the body part together. In some embodiments, a process is provided for determining the diameter of the lens of the eye.

Provided herein are imaging systems such as a system for quantitative tomography and a laser optoacoustic ultrasonic imaging system assembly (LOUISA) for imaging a tissue region, for example, a breast, in a subject. Generally, the system components are a laser that emits instant pulses of laser light in a wavelength cycling mode, fiberoptic bundles or optical arc-shaped fiber bundles configured to deliver laser light, an imaging module with an imaging tank, an optoacoustic array(s) of ultrawide-band ultrasonic transducers and ultrasound array(s) of ultrasonic transducers and a coupling medium and an electronics subsystem. Also provided is a method for imaging quantitative functional parameters and/or molecular parameters and anatomical structures in a volumetric tissue region of interest, such as a breast, in a subject utilizing the system for quantitative tomography.

The present disclosure is directed to a precision ultrasound scanner for imaging, for example, the prostate in a way that produces a superior image of the prostate while removing the iatrogenic risk and patient discomfort associated with other methods of providing an ultrasound image of the prostate. The present disclosure describes an apparatus and method for forming a high precision image of the prostate from outside the patient's body wherein the resolution in sufficient to image, for example, cancerous lesions on the surface of the prostate. To achieve such images, coded excitation, tissue harmonic imaging, advanced transducers operating in the 10 MHz to 40 MHz range is used to achieve a useable signal-to-noise reflection while being able to position the imaging transducer as close as possible to the prostate without risk or discomfort to the patient.