Abstract: A shaving unit and/or electric shaver having a lighting module for providing an optical heating function at a skin-contacting surface of the shaving unit is disclosed. An encapsulation arrangement for components of the lighting module using a potting material is described. The potting material encapsulates, on both an upper and lower side, a carrier to one or more lighting elements are mounted.

Abstract: A device, system, and method determines a reading environment by synthesizing downstream needs. The method at a workflow server includes receiving a request from a physician device utilized by a referring physician, the request directed to performing an imaging procedure. The method includes determining at least one normalized need from the request, the normalized need corresponding to the referring physician. The method includes generating information to be included in a reading environment based on the at least one normalized need, the information assisting an image interpreter in interpreting the imaging procedure.

Abstract: Some embodiments are directed to a circuit compiling device for compiling a function into a binary circuit and a function evaluation device for evaluating a function using such a binary circuit. The binary circuit comprises conjunction subcircuits each computing a conjunction of function input bits and XOR subcircuits each computing a function output bit. Each function output bit may be represented as a sum of interpolation terms, the plurality of function input bits and the interpolation terms of the one or more function output bits together forming a plurality of interpolation terms. A conjunction subcircuit computes an interpolation term as a conjunction of two interpolation terms. A XOR subcircuit computes a function output bit as a XOR of interpolation terms. Thereby, the first interpolation term and second interpolation term are also used in XOR subcircuits, hence the binary circuit has a smaller number or likelihood of ineffective faults.

Abstract: A system includes a reconstructor (314) configured to reconstruct cone beam projection data to generate cone beam artifact corrected short scan cone beam volumetric image data. A method includes reconstructing, with a reconstructor, cone beam projection data to generate cone beam artifact corrected short scan cone beam volumetric image data. A computer-readable storage medium storing computer executable instructions which when executed by a processor of a computer cause the processor to: reconstruct cone beam projection data to generate cone beam artifact corrected short scan cone beam volumetric image data.

Abstract: A system comprises an imaging device for imaging within a body of a patient. The imaging device comprises a flexible elongate member and an imaging assembly disposed at a distal portion of the flexible elongate member. The imaging assembly comprises an array of imaging elements and a plurality of electronic components configured to perform an electrical function associated with imaging within the body of the patient using the array of imaging elements. Each of the plurality of electronic components is radiopaque such that the plurality of electronic components comprises a radiopaque pattern at the distal portion of the flexible elongate member. A method of imaging within a patient body comprises receiving a radiographic image representative of an ultrasound imaging device positioned within the patient body and determining an orientation of the ultrasound imaging device using a radiopaque pattern of a plurality of electronic components in the radiographic image.

Abstract: An X-ray system is described with a scatter radiation shielding device to be mounted underneath an operating table. The shielding device (10) comprises one or more layers of a radiation blocking material (6) and a cut-out (8) in the one or more layers. The cut-out extends from a point in or near a center of the one or more layers towards an edge to allow radiation transmission to pass. The shielding device is rotatable around a rotation axis. The shielding device substantially reduces the scatter radiation originating from the patient.

Abstract: The present disclosure describes ultrasound systems configured to enhance flow imaging and analysis by adaptively adjusting one or more imaging parameters in response to acquired flow measurements. Example systems can include an ultrasound transducer and one or more processors. Using the system components, mean flow velocity magnitude and acceleration can be determined within a target region during an acquisition phase, which may include a cardiac cycle. One or more adjusted flow imaging parameters, such as adjusted ensemble length, temporal smoothing filter length and/or step size, can be determined based on the acquired flow measurements to increase the signal quality of newly acquired ultrasound echo signals. The adjusted flow imaging parameters can then be applied by the ultrasound transducer during a second acquisition phase.

Abstract: The present invention relates to an oxytocin release stimulation device (10?) that can be arranged at or close to skin of a user (40). The oxytocin release stimulation device (10?) comprises a lighting unit (14?) and a control unit (16?). The control unit (16?) controls the lighting unit (14?) such that the lighting unit (14?) provides light with specific wavelengths and radiant exposures to the skin of the user (40) for a duration that ensures stimulation of a release of oxytocin. Release of oxytocin allows to stimulate a milk ejection reflex and thus to support milk extraction, e.g. when the oxytocin release stimulation device (10) is used with a breast pump (100?). The oxytocin release stimulation device (10?) can furthermore allow to reach an oxytocin level during pregnancy that allows to reduce the risk of postpartum depression or that allows to facilitate induction of labor.

Abstract: A diagnostic electrocardiogram system employing an electrode lead system (40) for generating one or more electrode signals indicative of electrical activity of a subject heart (10). The diagnostic electrocardiogram system further employs a diagnostic electrocardiograph (50) coupled to the electrode lead system (40) for communicating (e.g., listing, displaying and/or printing a subject electrocardiogram (20) and one more diagnostic electrocardiograms (30) designated as a morphology match to the subject electrocardiogram (20). The subject electrocardiogram (20) includes one or more interpretations of ECG features derived from tire electrical activity of the subject heart (10) as indicated by tire electrode signal(s) (e.g., an algorithmic interpretation and/or an electrocardiographer interpretation of the subject electrocardiogram (20)). The diagnostic electrocardiogram(s) includes one or more diagnoses of ECG features derived from recorded electrical activity of diagnosed heart(s) (11) (e.g.

Abstract: A method for identifying two or more infections as related or non-related infections based on an estimated genetic relatedness of the two or more infections, comprising: (i) receiving, for each of two or more infected patients, infection-relevant information comprising an antibiotic resistance profile for the patient's infection, a geo-temporal record for the patient, and a caregiver history for the patient; (ii) estimating, using a trained genetic relatedness model, a genetic relatedness of at least two of the two or more infections; (iii) comparing the estimated genetic relatedness between at least two of the two or more infections to a predetermined threshold; (iv) identifying, based on the comparison, the at least two of the two or more infections as a related infection or a non-related infection.

Abstract: Imaging data (20) are acquired by a PET scanner (6) or other imaging device. Iterative image reconstruction of the imaging data is performed to generate a reconstructed image (22). The iterative image reconstruction includes performing an update step (24) that includes an edge preserving prior (28) having a spatially varying edge preservation threshold (30) whose value at each image voxel depends on a noise metric (32) in a local neighborhood of the image voxel. The noise metric may be computed as an aggregation of the intensities of neighborhood image voxels of the reconstructed image in the local neighborhood of the image voxel. The edge preserving prior may be a Relative Difference Prior (RDP). For further noise suppression, during the iterative image reconstruction image values of image features of the reconstructed image that have spatial extent smaller than a threshold (38) may be reduced.

Abstract: Disclosed herein is a medical system (100, 300). The execution of machine executable instructions (120) causes a processor (104) to: receive (200) measured gradient echo k-space data (122); receive (202) an off-resonance phase map (124); reconstruct (204) an initial image (126) from the measured gradient echo k-space data; calculate (206) an upsampled phase map (128) from the off-resonance phase map; calculate (208) an upsampled image (130) from the initial image; calculating (210) a modulated image (132) by modulating the upsampled image with the upsampled phase map; calculate (212) a corrected image (134) comprising iteratively. The iterative calculation comprises: calculating (214) updated k-space data by applying a data consistency algorithm (138) to a k-space representation of the modulated image and the measured gradient echo k-space data and calculating (216) an updated image (142) from the updated k-space data.

Abstract: Systems and methods for encoding radiofrequency, RF, data, e.g., electrical signals, by a microbeamformer are disclosed herein. The microbeamformer may use a pseudo-random sampling pattern (700) to sum samples of the RF data stored in a plurality of memory cells. The memory cells may be included in a delay line of the microbeamformer in some examples. The summed samples may form an encoded signal transmitted to a decoder which reconstructs the original RF data from the encoded signal. The decoder may use knowledge of the pseudo-random sampling pattern to reconstruct the original data in some examples.

Abstract: The present invention relates to an ECG electrode connector (1) and an ECG cable. To eliminate a trunk cable of a conventional ECG cable arrangement, the ECG electrode connector (1) is configured for mechanically and electrically connecting an ECG electrode with a lead wire. It comprises a connection arrangement (10) for mechanically connecting the ECG electrode connector (1) with an ECG electrode (100), a lead wire terminal (14) for connection with a signal line (301) of a lead wire (300), a shield terminal (15) for connection with a shield (302) of the lead wire (300), an electrode contact (17) for contacting an electrical contact (101) of the ECG electrode (100), a voltage clamping element (13) coupled between the lead wire terminal (14) and the shield terminal (15), and a resistor (16) coupled between the lead wire terminal (14) and the electrode contact (17).

Abstract: The present disclosure advantageously describes ultrasound imaging arrays that comprise ergonomic, non-rectangular shapes, as well as associated systems and methods. Non-rectangular transducer arrays allow for ergonomic probe shapes that improve patient comfort, maneuverability of the ultrasound device, and operator workflow. For example, an ultrasound imaging device can include an array of acoustic elements comprising a non-rectangular perimeter. The array includes a plurality of active elements configured to emit ultrasound energy and receive echoes corresponding to the emitted ultrasound energy, and a plurality of buffer elements surrounding the plurality of active elements at the non-rectangular perimeter of the array of acoustic elements. An edge seal comprising a sealing material is positioned at least partially around the plurality of buffer elements, and a buffer element of the plurality of buffer elements is spaced from at least one other buffer element by the sealing material of the edge seal.

Abstract: The present invention relates to a device, system and method for detection of pulse and/or pulse-related information of a patient.

Abstract: The present disclosure describes ultrasound imaging systems and methods configured to generate ultrasound images based on undersampled ultrasound data. The ultrasound images may be generated by applying a neural network trained with samples of known fully sampled data and undersampled data derived from the known fully sampled data to a acquired sparsely sampled data. The training of the neural network may involve training adversarial generative network including a generator and a discriminator. The generator is trained with sets of known undersampled data until the generator is capable of generating estimated image data, which the classifier is incapable of differentiation as either real or fake, and the trained generator may then be applied to unknown undersampled data.

Abstract: An imaging system (202) includes an X-ray radiation source (210) configured to emit radiation that traverses an examination region. The imaging system further includes a controller (220). The controller is configured to control an X-ray tube peak voltage of the X-ray radiation source to switch between at least two different X-ray tube peak voltages during a kVp switched spectral scan. The controller is further configured to control a grid voltage of the X-ray radiation source to follow the X-ray tube peak voltage during the spectral scan. The controller adjusts the grid voltage based on a predetermined mapping between a currently applied X-ray tube peak voltage and a corresponding grid voltage for a given focal spot size, thereby maintaining the given focal spot size throughout the spectral scan.

Abstract: An internal element (310) for a feeding bottle (100) is provided, the feeding bottle comprising a teat component (110), and a container component (120), which together define a bottle volume extending longitudinally between a base end of the container component, and a top end of the teat component. The internal element (310) comprises a disc element (620) configured to be positioned within the bottle volume extending transverse the longitudinal axis, and further comprises one or more tab elements (640) protruding from an outer periphery (630) of the disc element for being received between interfacing parts of a coupling arrangement (340, 342) of the bottle.

Abstract: The invention relates to a method of MR imaging of an object (10) positioned in an examination volume of a MR device (1). It is an object of the invention to enable efficient spiral MR imaging even in situations of strong Bo inhomogeneity. The method of the invention comprises: subjecting the object (10) to an imaging sequence comprising at least one RF excitation pulse and sinusoidally modulated magnetic field gradients, acquiring MR signals along two or more spiral k-space trajectories (31, 32, 33) as determined by the sinusoidal modulation of the magnetic field gradients, wherein the origins of the spiral k-space trajectories are offset from each other, and reconstructing an MR image from the acquired MR signals. Moreover, the invention relates to a MR device (1) and to a computer program for a MR device (1).