Abstract: Tactile sensing devices, systems, and methods to image a target tissue location are disclosed. When force is applied to the tactile sensing device, voltage data is detected and visualized on a screen, indicating the target tissue location.

Abstract: An exercise feedback provision apparatus includes an acquirer configured to acquire exercise intensity information including either one or both of user biometric information and user movement information, and a controller configured to verify whether the exercise intensity information is in a predetermined range, and generate a control signal based on a result of the verifying. The apparatus further includes a feedback provider configured to output a tactile feedback based on a pattern corresponding to the control signal.

Abstract: A Home Sleep Testing (HST) device for the diagnosis of obstructive sleep apnea (OSA) and snoring. The Device has an orally mounted microprocessor and sensor set configured to measure a user's movement, sleep pattern and snoring.

Abstract: A system, apparatus and method for saliva-conductance based hydration sensors and for a wireless network comprising hydration sensors and base stations. The hydration sensors include electrodes, a means of measuring saliva conductance, a processor, memory and wireless controllers. The hydration sensors output user hydration status based on the conductance of the user's saliva. Saliva conductance is correlated with ion concentration of saliva, which is a biomarker for dehydration. Thus, saliva conductance can be a proxy for dehydration. The hydration sensors may be used in active or hostile conditions, e.g., military use. Symptoms of dehydration are delayed: fatigue and impaired judgment can occur before a user realizes he/she is dehydrated. The hydration sensors indicate dehydration to a user, thus encouraging a user to hydrate and prevent dehydration-related injuries. Data from hydration sensors may be used in determining supply delivery logistics in hostile or inaccessible terrain.

Abstract: Provided herein are methods and devices operable to monitor the hydration of a user. The wearable device for hydration monitoring includes an emitting component operable to emit light having at least three different wavelengths, a sensor operable to receive a reflected portion of the emitted light, and a processor operable to receive signals from the sensor. At least one of the wavelengths is in the range from 900 nm to 1600 nm for optical detection of a level of water. The method for hydration monitoring includes emitting light from a light emitting component operable to emit light having at least three different wavelengths and detecting light with at least one photodetector. At least three distances between the light emitting component and the photodetector are known and the at least three distances allow monitoring of at least two different tissue beds with at least two different tissue depths.

Abstract: A wearable garment including a sensor management system (SMS) network allowing scalable numbers of sensors for communication with a wearable phone. Methods of using the SMS networks are also disclosed.

Abstract: A sensor garment for monitoring an individual engaged in an athletic activity includes a garment formed of textile material, and a sensor module inseparably coupled to the textile material of the garment. The sensor module includes a single-purpose sensor configured to sense a single characteristic, and a radio antenna configured to transmit data generated by the single-purpose sensor. The sensor module includes no external port.

Abstract: A wearable device, which comprises: a ring-shaped case having an opening part formed in the middle thereof; a projector mounted at one side of the case and outputting an image; a lens part adjusting the direction and the size of the image, which is projected from the projector, so as to project the image; and a control unit for adjusting the projector and the lens part according to an image signal, can deliver visual information to a user wearing the wearable device even without a separate display unit by outputting the image onto the hand of the user.

Abstract: A wireless communication method, a wearable device, a mobile terminal, and a system are provided. In the technical solution of the present disclosure, a mobile terminal sends frequency band information to a wearable device; the mobile terminal receives a second signal sent by the wearable device, converts the second signal into a second baseband signal, receives a third signal that is sent by a base station and corresponds to the frequency band information, and coverts the third signal into a third baseband signal; and the mobile terminal acquires a radio signal corresponding to the frequency band information according to the second baseband signal and the third baseband signal. In this way, data can be received through multiple paths by using communication capabilities of multiple wearable devices, and the receiving capability of a mobile phone can be greatly improved.

Abstract: A method, apparatus and computer program, in which a body of a wearable apparatus is maintained maintaining by a link in place at a given part of skin of the user. A sensor platform is movably supported sandwiched between the body and the skin and supported by the body movably with relation to the body towards and away of the skin, when the apparatus is worn by the user. A sensor is supported by the sensor platform. The sensor produces sensor signals corresponding to a property of the skin or underlying matter. The position of the sensor platform is adjusted by an actuator with relation to the skin.

Abstract: A sensor insertion device includes: a housing; a needle member comprising a needle portion configured to be inserted in the living body with a sensor and to be movable in the housing in an insertion direction and a pulling-out direction; a first urging member configured to urge the needle member in the insertion direction to move the needle member to a first position; a second urging member configured to urge the needle member in the pulling-out direction to move the needle member that has reached the first position to a second position; and a switching mechanism configured to perform selective switching from movement of the needle member by an urging force of the first urging member to movement of the needle member by an urging force of the second urging member when the needle member reaches the first position.

Abstract: Provided is a catheter that includes a catheter tube and a temperature sensor. The catheter tube includes a tip-flexible part and a base end part. The base end part includes a first base end section having rigidity higher than the tip-flexible part, and a second base end section having rigidity lower than the first base end section. The tip-flexible part has an axial length from 40 mm to 100 mm, the first base end section has an axial length from 200 mm to 400 mm, and the second base end section has an axial length from 200 mm to 900 mm. A value of the rigidity of each of the first and the second base end sections decreases linearly from the first base end section to the second base end section, in a region around a boundary between the first base end section and the second base end section.

Abstract: This disclosure is directed to a catheter having a basket-shaped electrode assembly with a high electrode density. The basket-shaped electrode assembly may have a plurality of spines, such as up to twelve, each with a plurality of electrodes, such as up to sixteen. The distal ends of the plurality of spines are joined at a distal hub, all of which are fashioned from a single piece of superelastic material.

Abstract: This disclosure is directed to a catheter having a basket-shaped electrode assembly with a high electrode density. The basket-shaped electrode assembly may have a plurality of spines, such as up to twelve, each with a plurality of electrodes, such as up to sixteen. The distal ends of the plurality of spines are joined at a distal hub, all of which are fashioned from a single piece of superelastic material.

Abstract: A method for assessing the orthopaedic performance of a joint of a patient can comprise implanting at least a first and second RF wirelessly detectable markers in first and second bones associated with a site and determining and storing their positions before a surgical procedure is performed. The procedure can be carried out on the site and the positions of the first and second markers can be detected and stored after the procedure has been completed. The detected positions can be used to generate a representation of the orthopaedic performance of the joint after the procedure.

Abstract: This invention provides improved optical measurements while in motion by collecting a force signal that measures how hard the optical device is pressing on the body. The force signal is used by a noise-canceling algorithm to reduce motion artifacts from the desired optical signal.

Abstract: A motion compensation system for tracking and compensating for patient motion during a medical imaging scan comprises an optical marker comprising an optically visible pattern and a mounting portion; a first optical detector positioned to digitally image the optically visible pattern along a first line of sight; a second optical detector positioned to digitally image the optically visible pattern along a second line of sight; a tracking engine configured to determine a pose of the object in six degrees of freedom by analyzing images from the first and second optical detectors; and a controller interface configured to generate tracking information based on the pose and to electronically transmit the tracking information to a scanner controller to enable compensation within a medical imaging scanner for object motion.

Abstract: A catheter with an electrode assembly has a functional electrode located at a first position on the electrode assembly and a shunting electrode located proximal to the first position. Irrigation fluid carried by the catheter may be electrically coupled with a patient's blood through the shunting electrode. The shunting electrode may be used to reduce noise in an electrocardiogram signal that results from the pump used to supply the irrigation fluid.

Abstract: Improved human health monitoring is provided in the context of sensor measurements of typical vital signs and other biological parameters, by a system and method using an empirical model of the parameters and disposed to estimate values of the parameters in response to actual measurements. Residuals resulting from the difference between the estimates and actual measurements are analyzed for robust indications of incipient health issues. Residual analysis is both more robust and more sensitive than conventional univariate range checking on vital signs.

Abstract: An apparatus for extracting a cardiovascular characteristic is provided. The apparatus may include: a first sensor configured to measure a vibration signal generated by a pulse wave of a subject; a second sensor configured to measure a pulse wave signal of the subject; a processor configured to perform an operation related to a cardiovascular characteristic on the basis of the measured vibration signal and pulse wave signal; and a main body in which the first sensor, the second sensor, and the processor are mounted.

Abstract: A cancerous lesion identifying method via hyper-spectral imaging technique comprises steps of: acquiring a plurality of first pathology images via an endoscopy, wherein the first pathology images are cancerous lesion images respectively; importing the first pathology images into an image processing module to acquire a plurality of first simulating spectra of the first pathology images so as to generate a principle component score diagram in accordance with the first simulating spectra; defining a plurality of triangle areas in the principle component score diagram in accordance with the first simulating spectra; determining whether a principle component score of a second simulating spectrum of a second pathology image is within any one of the triangle areas; and confirming the second pathology image belongs to one of the cancerous lesion images when the principle component score of the second simulating spectrum is within any one of the triangle areas.

Abstract: A system for determining biological information of a subject includes a surface configured to display an image of a subject positioned in front of the surface, a sensor configured to identify data of the subject, and an analysis and control unit configured to analyse the data and determine biological information of the subject based on the data.

Abstract: The invention relates to a source-detector arrangement (11) of an X-ray apparatus (10) for grating based phase contrast computed tomography. The source-detector arrangement comprises an X-ray source (12) adapted for rotational movement around a rotation axis (R) relative to an object (140) and adapted for emittance of an X-ray beam of coherent or quasi-coherent radiation in a line pattern (21); and an X-ray detection system (16) including a first grating element (24) and a second grating element (26) and a detector element (6); wherein the line pattern of the radiation and a grating direction of the grating elements are arranged orthogonal to the rotation axis; and wherein the first grating element has a first grating pitch varied dependent on a cone angle (?) of the X-ray beam and/or the second grating element has a second grating pitch varied dependent on the cone angle of the X-ray beam.

Abstract: A medical image diagnosis apparatus according to an embodiment includes obtaining circuitry, detecting circuitry, deriving circuitry, and controlling circuitry. The obtaining circuitry is configured to obtain image data of a patient. The detecting circuitry is configured to detect each of a plurality of sites of the patient from the image data. The deriving circuitry is configured to derive information about a structuring member in the patient, on the basis of a detection result obtained by the detecting circuitry. The controlling circuitry is configured to determine an injection condition for a contrast agent to be administered to the patient for a contrast-enhanced scan, on the basis of the information about the structuring member.

Abstract: An apparatus for cone beam computed tomography can include a support structure, a scanner assembly coupled to the support structure for controlled movement in at least x, y and z orientations, the scanner assembly can include a DR detector configured to move along at least a portion of a detector path that extends at least partially around a scan volume with a distance D1 that is sufficiently long to allow the scan volume to be positioned within the detector path; a radiation source configured to move along at least a portion of a source path outside the detector path, the source path having a distance D2 greater than the distance D1, the distance D2 being sufficiently long to allow adequate radiation exposure of the scan volume for an image capture by the detector; and a first gap in the detector path.

Abstract: The invention relates to a medical x-ray imaging apparatus which is specifically designed for enabling three-dimensional imaging of relatively small volumes from the area of extremities of a patient. The apparatus includes a support construction (1) supporting a substantially ring-shaped structure (2), an O-arm (2), which in turn supports imaging means (21, 22) and which O-arm (2) is arranged with an examination opening (4). The imaging means (21, 22) are arranged movable within the O-arm (2). A positioning support (8) is arranged in connection with said examination opening (4) whose location with respect to the O-arm (2) is arranged adjustable.

Abstract: A patient imaging system for creating visual representations for analysis includes an imaging source and a patient support disposed proximate the imaging source configured to receive and support the patient. An imaging device is disposed adjacent to the patient support and incorporates at least one detector, one or more slats cooperating with the at least one detector and a collimator disposed between the one or more slats and patient support having a plurality of links adjustably positionable on the collimator. The plurality of links receive and support imaging plates that may be adjusted to provide a variety of image settings such that the imaging device and imaging source define a pre-determined imaging volume in an imaging region for the patient positioned in the imaging system.

Abstract: A radioemission scanner (12) is operated to acquire tomographic radioemission data of a radiopharmaceutical in a subject in an imaging field of view (FOV). An imaging system is operated to acquire extension imaging data of the subject in an extended FOV disposed outside of and adjacent the imaging FOV along an axial direction (18). A distribution of the radiopharmaceutical in the subject in the extended FOV is estimated based on the extension imaging data, and further based on a database (32) of reference subjects. The tomographic radioemission data are reconstructed to generate a reconstructed image (26) of the subject in the imaging FOV. The reconstruction includes correcting the reconstructed image for scatter from the extended FOV into the imaging FOV based on the estimated distribution of the radiopharmaceutical in the subject in the extended FOV.

Abstract: A medical imaging system for detecting ionizing radiation. The system includes one or more pixilated imagers positioned to acquire patient image data and one or more position sensors positioned to acquire patient position data. Once the patient image data and patient position data are acquired, one or more processors operably connected to each of the one or more pixilated imagers and one or more position sensors calculate a three-dimensional mass distribution based on patient image data and patient position data.

Abstract: Provided is a method of generating a virtual x-ray image, the method including: obtaining a 3-dimensional (3D) image of a patient; determining a projection direction of the 3D image in consideration of a position relationship between an x-ray source of an x-ray device and the patient; and generating a virtual x-ray image by projecting the 3D image on a 2D plane in the determined projection direction.

Abstract: Special displays of medical images are generated that help a radiologist better detect nodules by exploiting the inherent human visualization abilities of detection of symmetry, asymmetry, motion and relative motion. A Region of Interest (ROI) on an x-ray (mammogram, CT-scan, MRI, or other medical image) is selected and the data within the ROI is copied such that a new display now has two or more copies of the information within the ROI. This copy may contain the same relative positions as the original image, or may be a mirror image of the original data. The ROI is moved over the medical image in search of nodules. This movement can be random, under the direct control of the radiologist, systematically moved by a computer algorithm, or some combination of the above.

Abstract: Disclosed is a dental X-ray imaging apparatus having a radiographing housing so as to provide a stable radiographing environment to an examinee. The dental X-ray radiographing apparatus includes a radiographing unit including a rotary arm, an X-ray generator, and an X-ray sensor, and a radiographing housing for covering an upper part, an outside and an inside of an operating range of the radiographing unit. The imaging apparatus further includes a lifter configured to move the radiographing housing, and a handle frame disposed at a lower part of the radiographing housing with a variable height and including a chin rest, wherein the lifter moves the radiographing housing such that the distance between the chin rest and the radiographing housing is constant.

Abstract: A method and apparatus for generating a tooth panoramic image, and a panoramic machine for photographing teeth. The method comprises: determining a frame frequency of a reference detector, and determining a frame frequency of a photographing detector according to the frame frequency of the reference detector; photographing the teeth of a user according to the frame frequency of the photographing detector so as to generate a plurality of images; performing shift superposition on the plurality of images so as to generate a first panoramic image; acquiring a fuzzy region in the first panoramic image; and performing frame frequency adjustment on each row in the fuzzy region so as to form a clear image, and fusing the clear image and the first panoramic image so as to generate a second panoramic image.

Abstract: Intraoral three-dimensional (3D) tomosynthesis imaging systems, methods, and non-transitory computer readable media are used to generate one or more two-dimensional (2D) x-ray projection images and to reconstruct, using a computing platform, the one or more 2D x-ray projection images into one or more 3D images of an object, such as teeth of a patient, which can then be displayed on a monitor in order to enhance diagnostic accuracy of dental disease. The intraoral 3D tomosynthesis imaging system can include a wall-mountable control unit connected to one end of an articulating arm, the other end of which is connected to an x-ray source, which is configured to generate x-ray radiation that is acquired by an x-ray detector held at a desired position by an x-ray detector holder that is removably coupled to a collimator at an emission region of the x-ray source.

Abstract: The invention relates to a computed tomography radiological apparatus including: an X-ray source (22) capable of emitting an X-ray beam longitudinally towards an object, a device (32) for simultaneously splitting the beam into a plurality of beam portions each having a defined propagation direction relative to the longitudinal direction of emission of said X-ray beam, several sensors (20a-c) intended to receive beam portions which irradiated the object and are arranged transversely side by side relative to the longitudinal direction of the beam, the assembly consisting of X-ray source-splitting device-sensors being capable of turning about an axis of rotation (24) and of adopting different geometric orientations that are angularly shifted with respect to one another in order to, on the one hand, irradiate the object along each one of said geometric orientations of said assembly with the plurality of X-ray beam portions, and, on the other hand, to receive along each one of these geometric orientations the p

Abstract: The invention describes a device suspension arrangement comprising a ceiling region, at least one mobile device comprising a ceiling interface with at least one freely rotatable element arranged to partially protrude from the ceiling interface to facilitate movement of the suspended device to an arbitrary ceiling position; and at least one magnetic field generator realised to generate a magnetic field between the ceiling region and the ceiling interface of a mobile device. The invention further describes a mobile device for use in such a device suspension arrangement.

Abstract: In a tomographic image display device, an MIP-axis setting unit sets a predetermined axis of a subject as an MIP-axis. A position information calculation unit sets each position of three-dimensional volume data obtained for different regions of interest at three-dimensional positions corresponding to positional relationships between the MIP-axis and the region of interest. A three-dimensional data integration unit integrates each of the three-dimensional volume data in which three-dimensional positions are set into single three-dimensional data, and an MIP image generation unit projects an MIP image onto the integrated three-dimensional data in one or more projection directions orthogonal to the MIP-axis. In the MIP image, projection images of each of three-dimensional volume data are projected at positions corresponding to a positional relationship between the MIP-axis and the regions of interest.

Abstract: A medical image diagnostic apparatus according to an embodiment includes memory circuitry and processing circuitry. The memory circuitry stores therein a plurality of anatomical landmarks in a subject in association with a plurality of groups. The processing circuitry generates three-dimensional image data of the subject. The processing circuitry selects at least one group among the groups based on set examination information and a type of scan to be performed, and detects a site of the subject corresponding to at least one group, based on anatomical landmarks corresponding to a selected group. The processing circuitry controls to output information indicating a detected site.

Abstract: The present invention provides a method, including: obtaining a first image from a first imaging modality; identifying on the first image from the first imaging modality obtaining a second image from a second imaging modality; generating a compatible virtual image from the first image from the first imaging modality; mapping planning data on the compatible virtual image; coarse registering of the second image from the second imaging modality to the first image from the first imaging modality; identifying at least one element of the mapped planning data from the compatible virtual image; identifying at least one corresponding element on the second imaging modality; mapping the at least one corresponding element on the second imaging modality; fine registering of the second image from the second imaging modality to the first image from the first imaging modality; generating a third image.

Abstract: An X-ray computer tomography (CT) apparatus according to an embodiment includes processing circuitry. The processing circuitry an operation to change information relating to a range of a part that is defined based on a plurality of anatomical landmarks in any one of image data of a subject and image data of a virtual patient image. The processing circuitry performs any one of a first setting processing and a second setting processing, the first setting processing of changing a part of the anatomical landmarks to define the range of the part, the second setting processing of setting, for a part of the anatomical landmarks, a position departed therefrom by a predetermined length in a predetermine direction as an actual anatomical landmark.

Abstract: In an X-ray CT device according to an embodiment, reconstruction circuitry reconstructs a positioning image from projection data collected based on a detection signal of transmitted X-rays in positioning imaging performed at a first tube current. Circuitry detects body parts of a subject included in the positioning image. Storage stores information pieces relating to body parts, image quality levels for each of the information pieces relating to the body parts, and an X-ray count value corresponding to each of the image quality levels in an associated manner. The circuitry selects an image quality level corresponding to a desired body part. The circuitry acquires a second tube current based on the first tube current, an X-ray count value in the positioning imaging, and an X-ray count value associated with the selected image quality level. The circuitry controls an X-ray tube to perform main imaging based on the second tube current.

Abstract: A system having an X-radiation generator; an X-radiation detector, and a portable computing device. The X-radiation detector has a first wireless communication module, and a non-volatile memory. The X-radiation detector is configured to self-trigger acquisition of an X-radiation image upon detecting X-radiation generated by the X-radiation generator, store the acquired X-radiation image in the non-volatile memory, transmit a lower-resolution version of the X-radiation image via the first wireless communication module, and transmit the X-radiation image to a server via the first wireless communication module. The portable computing device has a second wireless communication module, and a digital screen.

Abstract: Evaluating dose performance of a radiographic imaging system with respect to image quality using a phantom, a channelized hotelling observer module as a model observer, and a printer, a plaque, or an electronic display includes scanning and producing images for a plurality of sections of the phantom using the radiographic imaging system, wherein the plurality of sections represent a range of patient sizes and doses and wherein the sections of the phantom contain objects of measurable detectability. Also included is analyzing the images to determine detectability results for one or more of the contained objects within the images of the plurality of sections of the phantom, wherein the analyzing includes using a channelized hotelling observer (CHO) module as a model observer; and displaying, via the printer, the plaque, or the electronic display, a continuous detectability performance measurement function using the determined detectability results.

Abstract: Provided is a method for data analysis and processing of an elasticity detection device, and an elasticity detection device. The method includes: transmitting, by each elasticity detection device, a detection result to a cloud server if a communication connection between the elasticity detection device and the cloud server is determined to be normal so that the cloud server can store the detection result in a database. The elasticity detection device transmits a data analysis request to the cloud server, and the cloud server obtains from the database data to be analyzed corresponding to an analysis keyword, analyzes the data to be analyzed to obtain an analysis result, and transmits the analysis result to the elasticity detection device. Thus, the elasticity detection device can obtain a comprehensive and accurate analysis result for different analysis requirements by means of storage and analysis capability of the cloud server on massive detection results.

Abstract: A device, method, and system for using an acoustic radiation force resulting from focused ultrasound energy in order to generate an internal force remotely and to measure quantitatively tissue elasticity in vivo and non-invasively.

Abstract: Systems and methods of automatically controlling, on a graphical user interface used by a physician, display views of an anatomic structure of a patient. Such systems and methods of automatically controlling display views of an anatomic structure of a patient can facilitate visualizing a position of a medical device relative to the anatomic structure during a medical procedure directed to the anatomic structure. In certain implementations, the systems and methods of the present disclosure provide automatic display views of a cardiac catheter relative to a three-dimensional model of a patient's heart cavity during a medical procedure such as cardiac ablation.

Abstract: There are provided an ultrasound image generating apparatus, which generates a high-quality ultrasound image even in a deep portion of a subject, and a control method thereof. In an ultrasound image (Img), for a portion (Ar1) equal to or less than a depth threshold value (D1), a real scanning line (L1) obtained from an acoustic wave echo signal is used. In the ultrasound image (Img), for a portion (Ar2) deeper than the depth threshold value (D1), an interpolation scanning line (L2) located between the real scanning lines (L1) is generated from an acoustic wave echo signal having a positional deviation between a focusing position of ultrasound waves and an observation target position. Also for a portion deeper than the interpolation scanning line (L2), a high-quality ultrasound image (Img) is obtained.

Abstract: A system for sensing a position of an ultrasound imaging device includes an ultrasound (US) imaging device, and a position sensor mount, and a position sensor. The position sensor mount includes an elastic body portion, a first rigid shell disposed on a distal portion of the elastic body portion, a second rigid shell disposed on a proximal portion of the elastic body portion, and a first adhesive disposed on the first rigid shell. The position sensor is mounted on the first rigid shell and configured to sense position information of the US imaging device in a coordinate system. The US imaging device is received by the position sensor mount and circumscribed by the first adhesive.

Abstract: An ultrasound endoscope includes: an insertion portion configured to be inserted into a living body; an ultrasound transmitting and receiving unit; a balloon surrounding the ultrasound transmitting and receiving unit; a water supply port for supplying water to the balloon; an operating unit provided at a proximal end side of the insertion portion; a cable extending from the operating unit; a channel provided in the insertion portion and leading to the water supply port to supply water toward the water supply port; a pipe provided in the cable; a cylinder provided at the operating unit, one end of the channel and one end of the pipe being opened to the cylinder; an injection port provided in the pipe; and a duct having one end leading to the pipe via the injection port and having the other end to which a syringe for injecting water or supplying air is attachable.

Abstract: Provided is a handheld ultrasound scanner and a process for using the same. The handheld ultrasound scanner includes transducers, electromagnetic wave generating means, electromagnetic wave receiving means, control means, processing means, and/or a containment casing.