Provided are foldable electronic device and method for estimating bio-information by using the same. The foldable electronic device may include: a main body part including a first main body and a second main body that are configured to be folded toward each other or unfolded from each other along a fold line where the first main body and the second main body meet; an image sensor part including a first image sensor and a second image sensor which are disposed at the first main body; and a processor configured to obtain a contact image of an object from the first image sensor disposed at the first main body and obtain an image of a marker that is displayed on the second main body, from the second image sensor disposed at the first main body, when the object is in contact with the first image sensor and the main body part is folded along the fold line, and estimate bio-information based on the contact image of the object and the image of the marker.

A registration fixture is configured for use with a medical imaging system. The registration fixture comprises a rigid internal structure comprising a plurality of fiducial markers arranged in a predefined pattern. The registration fixture further comprises a housing configured to surround the rigid internal structure. The registration fixture is configured to be mounted on a patient table.

In a method and apparatus for supporting a user when positioning an accessory for a magnetic resonance examination on an examination object, the actual position of the accessory is acquired by an acquisition unit, and a target position of the accessory is determined by a determination unit. The actual position and the target position of the accessory are compared with regard to deviation of the actual position from the target position of the accessory. Output information representing any deviation that is found to exist is provided to a user via an output unit.

A system for superimposing virtual anatomical landmarks on an image includes a medical positioning system (MPS) for producing location readings with respect to points within a region of interest in accordance with an output of a location sensor disposed in a medical device. A coordinate system of the MPS is registered with an image coordinate system. A control unit receives a signal from a user to record a location reading when the medical device is at a desired point in the region of interest where the user desires to place a virtual landmark, modifies the recorded location reading for motion compensation, transforms the motion-compensated location reading from the MPS coordinate system to the image coordinate system to produce a target location, and then superimposes a representation of the virtual landmark on the image at the target location.

Systems and methods use a three-dimensional snapshot of an infant, child, adolescent, or adult where the subject may have bent legs and an unaligned head position, to provide an estimate of human length. The system identifies anatomical features from the digital information and generates a virtual skeleton. The cumulative distances between pseudo-joints of the virtual skeleton provide an estimate of human length. Comparing length estimates from multiple three-dimensional snapshots of the same individual acquired over time provide an indication of growth of the infant, child, or adolescent. Daily estimates of length can detect growth faltering sooner than less frequent estimates of length, which can lead to timely intervention.

The present invention is related to a system and method to ensure the reproducibility of the position of the feet and lower parts of the legs during Magnetic Resonance Imaging (MRI) studies, and to obtain robust quantitative information through the time. The system includes a device that is inserted into the radiofrequency coils of any MRI equipment. The device includes a foot support section, a leg support section and a base adapted to allow that the abovementioned sections be fixed in it. With this device and method, and through external and internal markers, quantitative studies of the evolution of pathophysiological phenomena that affect the anatomy and physiology of the feet and lower parts of the legs are performed.

The ability to capture an undistorted image of the foot or foot and ankle is essential to the production of effective custom orthotics and shoes. This patent solves the problem of providing an accurate three-dimensional measurement of an undistorted foot/ankle by using a system involving the automated and controlled orbit of a point cloud capture device around the foot/ankle with the foot/ankle in a non-weight bearing position so as to capture a three-dimensional image.

A patient support apparatus includes a sensor capable of detecting vital signs and includes structures for monitoring the vital signs and providing local and/or remote indications to caregivers if the vital signs fall outside of acceptable limits.

A system for contactless monitoring of gas levels within an incubator, the system comprising at least one gas sampling line having a proximal end exposed to the internal space of the incubator, and a distal end associated with a monitoring unit for receiving a gas sample obtained from the incubator via the proximal end.

This disclosure relates to the technique for acquiring a three-dimensional image of the human body for the purpose of manufacturing customized orthopedic braces.