An apparatus for positioning a patient for medical imaging comprises a support system (10), a control unit (20) and a filter unit (30). The support system (10) comprises a patient support device (12) and an actuator (14) configured to move the patient support device. The support system (10) is located inside an electromagnetically-shielded enclosure (2). The control unit (20) is configured to adjust the position of the patient support device (12) by communicating with the support system (10) via one or more signal lines (40). The control unit (20) is located outside the electromagnetically-shielded enclosure (2). The filter unit (30) is configured to filter noise from the signal lines (40).

A medical treatment or testing mask includes a first profile having a first fastening mechanism, and a second profile, that is separate from the first profile, having a second fastening mechanism that is fastenable to the first fastening mechanism. The mask further includes a first sheet of thermoplastic material attached to the first profile and to the second profile, wherein, when the second fastening mechanism is fastened to the first fastening mechanism, the first profile and the second profile create a single frame structure.

Arrangements described herein relate to systems, apparatuses, and methods for a disposable kit containing medical items configured for a medical device including a head cradle to support a head of a subject, the disposable kit includes a container that encloses a head cradle pad configured to be affixed to the head cradle, at least one fiducial marker configured to be disposed on a location at the head of the subject, and at least one enclosure configured to cover a portion of the medical device.

A system for performing an ultrasound scan of cellular tissue includes an ultrasound scanning device having an ultrasound probe, to generate cross-sectional images of the cellular tissue. A probe enclosure houses the ultrasound probe, has a bottom formed by a flexible membrane, is configured to hold an ultrasonic coupling material, and forms a pressurizable cavity adjacent the flexible membrane. An armature supports the probe enclosure and is configured to move the probe enclosure into a position where the flexible membrane is placed adjacent to and displaced by the cellular tissue. A probe positioning assembly supports the ultrasound probe within the probe enclosure and moves the ultrasound probe over the flexible membrane with a head of the ultrasound probe submerged in the ultrasonic coupling material, the ultrasound scanning device generating the cross-sectional images of the cellular tissue as the probe positioning assembly progressively moves the ultrasound probe over the flexible membrane.

An ultrasound automatic scanning system according to an embodiment includes an ultrasound probe, a mechanical mechanism, and processing circuitry. The ultrasound probe transmits and receives ultrasonic wave. The mechanical mechanism holds and moves the ultrasound probe while an ultrasonic-wave transmission-reception surface of the ultrasound probe is pointed to a subject. The processing circuitry acquires a distance between a body surface of the subject and the ultrasonic-wave transmission-reception surface of the ultrasound probe based on reflected wave data collected while the ultrasound probe is moved by the mechanical mechanism. The processing circuitry generates, based on information of the distance, locus information of movement of the ultrasound probe when ultrasound scanning is executed on the subject. The mechanical mechanism executes ultrasound scanning on the subject by moving the ultrasound probe based on the locus information generated by the processing circuitry.

The imaging system can comprise a plurality of elongated rails, a scanhead assembly, and a small animal mount assembly. The scanhead assembly is selectively mounted onto a first rail and is constructed and arranged for movement in a linear bi-directional manner along the longitudinal axis of the first rail. The small-animal mount assembly is selectively mounted onto a second rail and is constructed and arranged for movement in a linear bi-directional manner along the longitudinal axis of the second rail. The second rail being mounted relative to the first rail such that the longitudinal axis of the second rail is at an angle to the longitudinal axis of the first rail. The imaging system can also comprise a needle injection assembly that is selectively mounted onto the third rail and is constructed and arranged for movement in a linear bi-directional manner along the longitudinal axis of the third rail. The third rail being mounted relative to the second rail and the first rail such that the longitudinal axis of the third rail is substantially coaxial to the longitudinal axis of the first rail. Alternatively, the needle injection assembly is mounted onto the first rail, such that the second rail is positioned therebetween the needle injection assembly and the scanhead assembly.

Some implementations of the disclosure are directed to an ultrasound measurement device including: multiple ultrasound sensors to capture tomographical information of a physiological structure, each ultrasound sensor comprising a transducer having a respective resonant frequency, where each transducer has a frequency response that partially overlaps with a frequency response of another transducer; and a processing device to control and process measurements made by the ultrasound sensors. The device may be incorporated in an adhesive substrate configured to be adhered to a patient's skin in alignment with an artery of the patient. The processing device may use the multiple ultrasound sensors to compute the mean arterial pressure through the artery by performing operations of: measuring a circumference of the artery using the multiple ultrasound sensors; measuring a blood flow velocity using the same ultrasound sensors; and computing the mean arterial pressure using the measured arterial circumference and blood flow velocity.

To accurately detect a shape and derive information of cartilage based on detected echoes, an ultrasonic diagnosing device includes an ultrasonic transmitter, an ultrasonic receiver, a low-frequency component extracting module, and a deriving module. The ultrasonic transmitter transmits ultrasonic waves to a cartilage in a plurality of bent states, in a state where a relative position of a wave transmitting and receiving surface to the cartilage is fixed. The ultrasonic receiver receives echo signals corresponding to respective frames in each of the plurality of bent states. The low-frequency component extracting module extracts, in a frame direction, low-frequency echo data which is echo data of a frequency component below a given frequency. The deriving module derives information of the cartilage based on the low-frequency echo data.

Disclosed is an ultrasonic diagnostic apparatus capable of easily obtaining an ultrasonic image for the same position of the same target object at different points of time. The ultrasonic diagnostic apparatus includes a probe configured to obtain ultrasonic data for an arbitrary position inside a target object, an image generator to generate an ultrasonic image for the arbitrary position using the ultrasonic data, a reference member provided to be in contact with the target object to set a reference position in the target object, a marker disposed on one side of the reference member, a sensor disposed on one side of the probe and configured to obtain a positional relationship with the marker, and a position calculator configured to calculate a positional relationship between the reference position and the arbitrary position using the positional relationship between the marker and the sensor.

Embodiments of the present invention are directed to various aspects of imaging systems, including permeable and impermeable barriers separating liquid compartments, one of which contains the object to be imaged and the other an ultrasonic transducer, a fluidic bearing between a transducer carriage and guide supporting the carriage, a linear motor for the carriage, and a location sensing device for the carriage. A method and apparatus are disclosed for performing an ultrasound scan on a body part and specifically an instrument which directly attaches to the surface of the body. This apparatus provides high resolution images and increased depth of imaging for high resolution ultrasound of targeted subsurface body tissues. Targeted tissues may include joints, ocular structures, and internal organs. The method and apparatus stabilize and provide accurate determination of the position of the body part relative to the ultrasound probe.