The patient couch (1) serves for carrying out radiological medical imaging examinations by X-ray, tomography, nuclear magnetic resonance and other imaging methods. The person rests thereon in lying position for the creation of tomographic and other images. The patient couch is equipped with a capturing device, for measuring the patient's body or certain sites of the patient's body by optical, laser-optical, mechanical or electromechanical methods and/or devices. The couch has footrests for positioning the soles of the feet as when standing on vertical supporting faces with natural spreading of the feet, as well as portions for capturing at least the positions of the knee joints, the hip joint, the pelvic bone, the shoulders and the head. Further, the couch is equipped with pressure sensors for measuring the local supported weights of the various supported body sites, for reproducibly capturing the position of the skeleton with regard to its center axis as well as any rotations of shoulder and/or hip.

A system and computer-implemented method for analysing or monitoring a subject, the method comprising: identifying one or more objects of interest that have been segmented from a first image comprising any of a baseline scan, a follow-up scan or a reference image of the subject; identifying predefined landmarks of the objects; determining reference morphometries pertaining to the objects by performing morphometrics on the objects by reference to the landmarks; selecting one or more regions of interest (ROIs) from the objects according to the reference morphometries, comprising identifying respective locations of the ROIs relative to the reference morphometries; performing a first analysis of the one or more ROIs; performing at least one corresponding second analysis of the one or more ROIs in respectively at least one second image comprising any other of a baseline scan, a follow-up scan or a reference image; and generating a comparison of one or more results of the first analysis and one or more corresponding results of the second analysis.

The present invention relates to Electrical Impedance Tomography (hereinafter “EIT”) wearable technology and Telemedicine to provide cloths that can scan and image the human body safely and affordable detecting and monitoring cancer, pneumonia and a patient's medical condition in real time anywhere in the world with an Internet connection.

An apparatus includes a communication interface and at least one processor. The processor is configured to obtain a size of a lumen in each of a plurality of aortic zones and first information for each of the plurality of aortic zones based on segmentation results of an aorta and the plurality of aortic zones within the aorta; and visualize the size of the true lumen, the first information, and a ratio between the size of the true lumen and the first information in each of the plurality of aortic zones by using a visualization segment corresponding to each of the plurality of aortic zones.

For topogram predication from surface data, a sensor captures the outside surface of a patient. A generative adversarial network (GAN) generates the topogram representing an interior organ based on the outside surface of the patient. To further adapt to specific patients, internal landmarks are used in the topogram prediction. The topogram generated by one generator of the GAN may be altered based on landmarks generated by another generator.

The present invention discloses a medical image fusion apparatus and method. The medical image fusion apparatus comprises: a display unit configured to display a plurality of medical images in layers in one window on a screen, wherein the arrangement direction of the plurality of medical images is different from the extension direction of the plane on which each medical image exists; an operation detection unit configured to detect an operation of selecting the medical images to be fused from the plurality of medical images; and a fused image generation unit configured to generate a fused image of the medical images to be fused according to the selection operation, wherein the display unit is further configured to display the fused image in a predetermined region in the window.

A system is suggested comprising an optical sensing means and a processing unit. The optical sensing means may include an optical guide with a distal end, wherein the optical guide may be configured to be arranged in a device to be inserted into tissue in a region of interest. The processing unit may be configured to receive information of a region of interest including different tissue types as well as of a path through the tissues, to determine a sequence of tissue types along the path, to determine a tissue type at the distal end of the optical guide based on information received from the optical sensing means, to compare the determined tissue type with the tissue types on the path, to determine possible positions of the distal end of the optical guide on the path based on the comparison of tissue types, and to generate a signal indicative for the possible positions.

A laser based vascular illumination system utilizing a FPGA for detecting vascular positions, processing an image of such vasculature positions, and projecting the image thereof onto the body of a patient.

A method for performing an examination includes at least one magnetic resonance-based and at least one further examination step. An examination object is positioned during the entire examination on an upper side of a transfer plate that is positioned on an object table during the magnetic resonance-based examination. At least one coil holder that includes at least one local coil or by which at least one coil device is supported is used during the magnetic resonance-based examination step. The coil holder is arranged on the examination object during the magnetic resonance-based examination step exclusively. The coil holder is supported during the magnetic resonance-based examination steps by at least one mounting, into which a supporting section of the coil holder engages and/or which engages into the supporting section of the coil holder.

A portable sensing system device and method for providing microwave or RF (radio-frequency) sensing functionality for a portable device, the device comprising: a portable device housing configured to be carried by a user; and a sensing unit within said housing configured to characterize an object located in proximity to the portable system, said sensing unit comprising: a wideband electromagnetic transducer array said array comprising a plurality of electromagnetic transducers; a transmitter unit for applying RF signals to said electromagnetic transducer array; and a receiver unit for receiving coupled RF signals from said electromagnetic transducers array.