A method for creating a virtual patient model includes acquiring image data of the patient from a number of directions and in a number of positions of the patient. A virtual patient is created based upon the acquired image data. The virtual patient is adjusted to a posture of the patient during a planned examination with a medical engineering examination apparatus. A patient model creation apparatus is also described. Moreover, a medical engineering examination system is described.

Various bathroom devices for the collection of data are described. In one example, a mirror cabinet includes a mirror frame, a sensor cavity, and a controller. The mirror frame is configured to support a mirror substrate that provides a reflection of one or more users in proximity of the mirror cabinet. The sensor cavity coupled to the mirror frame and is configured to support a sensor for detecting a health condition of the one or more users in proximity to the mirror cabinet. A controller is configured to analyze data received from the sensor to determine the health condition.

Disclosed herein is an apparatus for imaging nano magnetic particles using a 3D array of small magnets. A field-free region generation apparatus includes a hexahedral housing having an opening formed in the first surface thereof such that a measurement head is inserted into a spacing area, a pair of rectangular-shaped magnets installed respectively on two surfaces facing each other, among four surfaces perpendicular to the first surface of the housing, and a pair of magnet arrays installed respectively on the first surface of the housing and on another surface facing the first surface, each of the magnet arrays including multiple small magnets arranged along the edge of the opening.

A bed exit detection device (100) according to an embodiment of the present invention is mounted to a privacy rail (11) provided in the vicinity of a bed (10) to be monitored. The device (100) comprises a thermographic sensor (130) and a range sensor (40). The thermographic sensor comprises an array of sensing elements operable to generate an output value matrix from the output signals of each individual sensing element. The device (100) is also provided with a processing unit (150) operable to process the output value matrix of the thermographic sensor (130) and the distance output by the range sensor (140) so as to determine the position of a bed occupant and thereby (10) determine the likelihood of a bed exit event.

The present disclosure relates to a system and method for augmenting patient-technologist communication, before, during, and after a medical imaging procedure. In accordance with certain embodiments, a system includes a processor and a computer readable storage medium in communication with the processor. The processor executes program instructions stored in the computer readable storage medium which cause the computer processor to generate media that relates to a medical imaging procedure as a function of information in an electronic medical record that corresponds to a patient and output the media that relates to a medical imaging procedure to a display or a speaker.

An electromagnetic resonance-based disease detecting system may comprising a spectrum analyzer assembly comprised of one of a spectrum analyzer with an internal tracking generator or a spectrum analyzer with a separate signal generator, a radiating antenna electronically connected to the spectrum analyzer assembly output and configured to radiate a subject with an electromagnetic field based on a resonant frequency signal, wherein radiating a subject with the electromagnetic field generates a subject spectrum; a receiving antenna configured to receive the subject spectrum; a spectrum analyzer electronically connected to the receiving antenna and configured to receive the subject spectrum from the receiving antenna; and a processor, the processor being operatively connected to the spectrum analyzer assembly, the radiating antenna, the receiving antenna, and the spectrum analyzer, wherein the processor is configurable to store and control the resonant frequency signal generated by the spectrum analyzer assembly output control the electromagnetic field radiated from the radiating antenna; and, compare the received subject spectrum to the generated resonant frequency signal using the spectrum analyzer assembly input controlled by the processor to determine an absence or a presence of the disease condition without the use of chemical reagents or testing supplies.

An electromagnetic resonance-based disease detecting system may comprising a spectrum analyzer assembly comprised of one of a spectrum analyzer with an internal tracking generator or a spectrum analyzer with a separate signal generator, a radiating antenna electronically connected to the spectrum analyzer assembly output and configured to radiate a subject with an electromagnetic field based on a resonant frequency signal, wherein radiating a subject with the electromagnetic field generates a subject spectrum; a receiving antenna configured to receive the subject spectrum; a spectrum analyzer electronically connected to the receiving antenna and configured to receive the subject spectrum from the receiving antenna; and a processor, the processor being operatively connected to the spectrum analyzer assembly, the radiating antenna, the receiving antenna, and the spectrum analyzer, wherein the processor is configurable to store and control the resonant frequency signal generated by the spectrum analyzer assembly output control the electromagnetic field radiated from the radiating antenna; and, compare the received subject spectrum to the generated resonant frequency signal using the spectrum analyzer assembly input controlled by the processor to determine an absence or a presence of the disease condition without the use of chemical reagents or testing supplies.

An interlocking system for a joystick in a catheter procedure system includes a joystick configured to generate a first voltage output signal based on a linear activation of the joystick and a second voltage output signal based on a rotational activation of the joystick. A joystick cover is disposed over the joystick and includes an upper portion having an electrode plating on an inner surface of the upper portion and a lower portion having an inner surface. A capacitive touch detection circuit is coupled to the electrode plating of the upper portion of the joystick cover and is mounted on the inner surface of the lower portion of the joystick cover. The capacitive touch detection circuit is configured to detect a proximal change in capacitance in the electrode plating of the upper portion of the joystick cover and to generate a touch output signal to indicate whether a change in capacitance has been detected. A signal enable circuit is coupled to the joystick and the capacitive touch detection circuit and is configured to generate a linear enable voltage output signal and a rotational enable voltage output signal based on whether a change in capacitance has been detected.

Various embodiments concern video patient monitoring with detection zones. Various embodiments can comprise a camera, a user interface, and a computing system. The computing system can be configured to perform various steps based on reception of a frame from the camera, including: calculate a background luminance of the frame; monitor for a luminance change of a zone as compared to one or more previous frames, the luminance change indicative of patient motion in the zone; and compare the background luminance to an aggregate background luminance, the aggregate background luminance based on the plurality of frames. If the background luminance changed by more than a predetermined amount, then the aggregate background luminance can be set to the background luminance, luminance information of the previous frames can be disregarded, and motion detection can be disregarded.

The present disclosure relates to a transfer cart suitable for use in association with an MR scanner. The transfer cart may include a transfer table assembly coupled to the support frame such that the transfer table assembly and the horizontal support structure portion of the support frame extend substantially perpendicularly from the vertical support structure of the support frame and in substantially parallel planes to each other. The transfer table assembly may be maintained at substantially the same vertical level of a scanning bore of an MR scanner. The transfer cart may include a frame designed to dock with the MR scanner.