A magnetic resonance imaging system includes a bore, a table configured to support a patient being imaged and movable to move the patient in and out of the bore, a motion sensor, a controller configured to detect patient motion based on changes in an RF signal from the motion sensor. The motion sensor includes a self-resonant spiral (SRS) coil excited by a drive signal to radiate a magnetic field having a predefined resonant frequency and a driver-receiver coupled to the SRS coil and configured to generate the drive signal to excite the SRS coil and to receive the RF signal from the SRS coil. The motion sensor is located such that a portion of the patient is within the magnetic field while the patient is being imaged in the bore.

The present invention relates to a resuscitation chamber apparatus for administering hyperbaric oxygen to a patient. More particularly, the present invention relates to a hyperbaric oxygen compatible critical care chamber apparatus preferably for use in emergency departments and/or prehospital ambulance management of patients. In a preferred embodiment of the present invention, the apparatus is a resuscitation monoplace hyperbaric chamber preferably used in critical care management of acutely ill or injured patients in prehospital emergency medical services (EMS) settings or in hospital emergency departments. The apparatus preferably allows a critical care shock or arrested patient to be pressurized preferably without compromise for application of best medical equipment, medications and human resuscitating intervention.

Disclosed herein is a medical system (400) comprising a magnetic resonance imaging system (402) configured for acquiring magnetic resonance imaging data (444, 444′) from a subject (418) within an imaging zone (408). The medical system further comprises a subject support (100) configured for supporting at least a portion of the subject within the imaging zone, wherein the subject support comprises a radiotherapy couch top (102) 5 configured for receiving the subject. The radiotherapy couch top comprises a flat surface (104) configured for supporting the subject. The radiotherapy couch top further comprises a head support region (110) configured for receiving a head of the subject, wherein the head region comprises a depression (108). The head region is configured for receiving a flat head support plate (112). The medical system further comprises a flat head support plate. The flat head support plate is configured to form part of the flat surface (104′) when installed in the head region.

A mobile medical imaging device that allows for multiple support structures, such as a tabletop or a seat, to be attached, and in which the imaging gantry is indexed to the patient by translating up and down the patient axis. In one embodiment, the imaging gantry can translate, rotate and/or tilt with respect to a support base, enabling imaging in multiple orientations, and can also rotate in-line with the support base to facilitate easy transport and/or storage of the device. The imaging device can be used in, for example, x-ray computed tomography (CT) and/or magnetic resonance imaging (MRI) applications.

According to one embodiment, a bed system that is mechanically and electrically connectable to a main body of a medical image diagnosis apparatus includes a traveling unit and an interface. The traveling unit provided between the bed system and a floor surface. The interface configured to receive an operation of locking or unlocking driving of the traveling unit. The operation on the interface of locking or unlocking driving of the traveling unit is interlocked with electrical connection between the bed system and the main body.

Systems and methods are provided for delivering images to a patient before and/or during a medical procedure in which a patient is translated on a table relative to a gantry. In various example embodiments, images are projected to the patient while preserving the projected field size during table motion, thereby potentially reducing patient anxiety by providing a more immersive patient viewing experience. In some example embodiments, the projected field size is maintained by a display system that is secured to the table such that both a projector and a projection screen are fixed relative to the table, and relative to the patient, during translation of the table. In some example embodiments, a reduction in patient anxiety may be achieved by projecting images as virtual images that are perceived by the patient as residing at a depth that lies beyond the confined spatial region in which the patient resides.

An apparatus having a longitudinal axis and an upper surface for supporting an individual at least partially positioned on a bed or other support structure, such as, for example, a bed within a magnetic resonance imaging (MRI) machine, is disclosed. The individual can have hips, legs and an upper back. The apparatus comprises a bladder that is configured to be positioned beneath the hips of the individual. The bladder has a first end and an opposed second end that is spaced from the first end along the longitudinal axis. The bladder is configured to expand upon receiving air from an air supply in order to elevate the hips of the individual relative to the upper back of the individual. A valve is in fluid communication with the bladder. The valve is configured to selectively allow air from the air supply into the bladder. The apparatus can be nonferrous.

Parametric model based computer implemented methods for determining the stiffness of a bone and systems for estimating the stiffness of a bone in vivo. The computer implemented methods include determining a complex compliance frequency response function Y(f) and an associated complex stiffness frequency response function H(f) and independently fitting a parametric mathematical model to Y(f) and to H(f). The systems include a device for measuring the stiffness of the bone in vivo and a data analyzer to determine a complex compliance frequency response function Y(f) and an associated complex stiffness frequency response function H(f).

A gradient coil assembly for a magnetic resonance imaging device is disclosed. The gradient coil assembly comprises a cylindrical carrier with conductors forming three gradient coils associated with three orthogonal physical gradient axes. The cylindrical carrier comprises at least two radial through openings at different angular positions. At least one of the conductors runs through at least one area of the carrier located circumferentially between the through openings.

A magnetic resonance tomography unit and a method is provided in which a patient couch may be moved in relation to the longitudinal direction into the patient tunnel in the transversal direction into a left-hand side extreme position and an opposite-lying right-hand side extreme position. Using an image acquisition facility in the left-hand side extreme position a right-hand side part is acquired and in the right-hand side extreme position a left-hand side part of the outer contour of the predetermined object is acquired. Using the image acquisition facility, the outer contour of the object is subsequently created from the left-hand side part of the outer contour and also from the right-hand side part of the outer contour.