Abstract: A probe for use with an imaging system, including a scanning device configured to receive a first light beam from a light source, a beam-divider configured to split the first light beam into a plurality of second light beams, and a focusing device configured to focus each of the second light beams on respective locations in an object of interest is disclosed.

Abstract: The invention relates to a device (1) for positioning a marker (2) in a 3D ultrasonic image volume (3), a system for positioning a marker (2) in a 3D ultrasonic image volume (3), a method for positioning a marker (2) in a 3D ultrasonic image volume (3), a computer program element for controlling such device (1) for performing such method and a computer readable medium having stored such computer program element. The device (1) comprises an image provision unit (11), a marker unit (12) and a display unit (13). The image provision unit (11) is configured to provide a 3D ultrasonic image volume (3) showing an object (4). The marker unit (12) is configured to position a marker (2) in the 3D ultrasonic image volume (3). The display unit (13) is configured to display the 3D ultrasonic image volume (3) and the marker (2) in a first imaging view (31) in a first imaging plane and in a second imaging view (32) in a second, different imaging plane.

Abstract: The present invention relates to a method of calculating a surgical intervention plan. Based on surface data of the patient, a surface representation of a part of the patient's body is created. From a database, a plurality of surgical methods may be selected and the geometrical parameters of a surgical plan can be adapted based on each individual surgical method. Therefore, the surgeon may easily select, which of the surgical method is appropriate for the planned surgical intervention. Furthermore, the surgical intervention plan which has been adapted according to the finally selected surgical method may then be projected onto the skin of the patient such that a drawing of the incision lines is facilitated. Furthermore, the use of a remotely activatable pen based on the current position of the pen and based on the finally selected surgical plan is presented.

Abstract: A tomographic image processing device that includes an input unit configured to input a tomographic image of a subject eye; a processor; and a memory storing computer-readable instructions therein. The computer-readable instructions, when executed by the processor, may cause the processor to execute: acquiring a tomographic image of a normal eye; acquiring a tomographic image of an eye having an abnormal portion; extracting a feature amount of the abnormal portion by using machine learning from the tomographic image of the normal eye and the tomographic image of the eye having the abnormal portion; acquiring a tomographic image of the subject eye inputted to the input unit; and determining whether the tomographic image of the subject eye includes an abnormal portion based on the feature amount.

Abstract: A medical apparatus according to an embodiment includes control circuitry. The control circuitry is configured to: acquire a three-dimensional cumulative dose distribution of an object; set a treatment target site by treatment accompanied with X-ray irradiation to the object; and determine an X-ray irradiating direction for performing the X-ray irradiation based on the three-dimensional cumulative dose distribution and the treatment target site.

Abstract: The present invention relates to a method for characterizing perfusion abnormalities in tissue by means of fractal analysis (FA) of at least one part of an interface region between adequately and abnormally perfused tissue comprising the steps of providing an imaging dataset of perfusion imaging; wherein said imaging dataset visualizes the at least one part of the interface region; optional pre-processing of said imaging dataset; applying fractal analysis to the imaging dataset; wherein said fractal analysis provides at least one fractal parameter, preferably fractal dimension (FD), of the at least one part of the interface region.

Abstract: An image processing apparatus including an identification unit configured to identify a lamina cribrosa region by analyzing tomographic image data on an eye to be inspected, a generation unit configured to generate a luminance en face image and a motion contrast en face image of the eye to be inspected by using information on the identified lamina cribrosa region, and a display control unit configured to cause a display unit to display at least one of the luminance en face image and the motion contrast en face image with the information on the identified lamina cribrosa region superimposed on the displayed image.

Abstract: Disclosed herein is a head-mounted apparatus, including: an optical sensor having a contact face for contacting with the head of a user; a supporting unit disposed around the optical sensor and configured to contact with the head of the user; and a sensor supporting mechanism configured to support the optical sensor so as to permit a movement of the optical sensor in a contact direction that is a direction perpendicular to the contact face.

Abstract: This patent document discloses techniques and devices for sensing or measuring electric currents and/or temperature based on photonic sensing techniques. The optical sensors for sensing the current or temperature can be configured as a polarization-insensitive optical sensor in either an optical transmissive configuration or an optical reflective configuration.

Abstract: Described are systems and methods for aligning and concurrently presenting guide device video data of an environment and an enhancement corresponding to the environment. With the described implementations, users may virtually experience an environment at a destination location from their own user device and also concurrently view historical and/or future representations of that environment (enhancement) concurrently with current representations of the environment. The user may select the amount of the enhancement or the guide device video data that is presented to the user as part of the experience. Likewise, the guide device video data and enhancement remain aligned as they are presented to the user.

Abstract: Methods, devices and non-transitory machine readable storage mediums for displaying coronary arteries are provided. In one aspect, a method includes: obtaining a coronary artery model of the coronary arteries, obtaining values of one or more coronary artery parameters of the coronary artery model according to the coronary artery model, determining colors corresponding to the values of the one or more coronary artery parameters, and acquiring a pseudo-color coronary artery model of the coronary arteries by displaying the coronary artery model with the determined colors.

Abstract: The present invention relates to a breast cancer diagnosis device. More particularly, the present invention relates to a breast cancer diagnosis device for early detection of the presence or absence of breast cancer lesions inside the breast of a diagnosis subject. The breast cancer diagnosis device includes: an X-ray diagnosis unit generating an X-ray image of a diagnosis subject; an optical diagnosis unit generating an optical transmission image of the diagnosis subject; and a transfer unit which is coupled to the X-ray diagnosis unit and the optical diagnosis unit to transfer all or part of the X-ray diagnosis unit and the optical diagnosis unit, and sequentially transfer all or part of the X-ray diagnosis unit or the optical diagnosis unit toward the diagnosis subject.

Abstract: A method for controlling a medical apparatus (100) includes receiving a treatment plan (168) specifying a target volume (146) within an imaging volume (138) and a dose rate of radiation emitted by a radiotherapy apparatus (102). The medical apparatus (100) repeatedly acquires the motion tracking magnetic resonance data and the image magnetic resonance data using an interleaved pulse sequence. The radiotherapy apparatus (102) is controlled to radiate the target volume (146) in accordance with the treatment plan (168). A dose distribution map descriptive of a radiation dose received by the subject (144) from the radiotherapy apparatus (102) is calculated using the motion tracking magnetic resonance data, and the treatment plan (168). A diagnostic image is reconstructed using the image magnetic resonance data. A display displays the diagnostic image and the dose distribution map.

Abstract: A portable facility failure diagnosis device using detection of radiation ultrasonic waves, comprising: an ultrasonic sensor array; a data acquisition board (DAQ board) in which an electronic circuit for acquiring ultrasonic signals at a sampling frequency of the ultrasonic signals sensed by the ultrasonic sensor array is mounted on a substrate of the data acquisition board (DAQ board); a main board in which an operation processing device that processes the ultrasonic signals received from the DAQ board is mounted on the substrate and the processed ultrasonic sound source information to a display device; a data storage medium storing data processed in the operation processing device of the main board; a display device visually displaying the data processed; and an optical camera picking up an image of a direction.

Abstract: A method for determining respiratory induced blood mass change from a four-dimensional computed tomography (4D CT) includes receiving a 4D CT image set which contains a first three-dimensional computed tomographic image (3D CT) and a second 3D CT image. The method includes executing a deformable image registration (DIR) function on the received 4D CT image set, and determining a displacement vector field indicative of the lung motion induced by patient respiration. The method further includes segmenting the received 3D CT images into a first segmented image and a second segmented. The method includes determining the change in blood mass between the first 3D CT image and the second 3D CT image from the DIR solution, the segmented images, and measured CT densities.

Abstract: An Electromagnetic Interference Pattern Recognition Tomography (EMIPRT) method for use in an image reconstruction system includes generating electromagnetic field data corresponding to an object in an imaging domain, via an electromagnetic tomography system, and using the generated electromagnetic field data, repeatedly, in recursive manner, forming an undisturbed electromagnetic interference image, forming a disturbed electromagnetic interface image based on the undisturbed electromagnetic interference image, recognizing electromagnetic interference patterns in the repeatedly formed disturbed electromagnetic interface images, and forming a superposition image by nullifying or diminishing the recognized electromagnetic interference patterns from the disturbed electromagnetic interface image.

Abstract: A body thickness estimation unit estimates a body thickness of a subject for each pixel of at least one of a first radiographic image or a second radiographic image which includes a primary ray component and a scattered ray component, on the basis of the at least one of the first radiographic image or the second radiographic image. A bone part pixel value acquisition unit acquires a pixel value of a bone region of the subject from the first and second radiographic images. An information acquisition unit acquires bone mineral information indicating a bone mineral content of the bone region for each pixel of the bone region on the basis of imaging conditions in a case in which the at least one of the first radiographic image or the second radiographic image has been acquired, the body thickness for each pixel, and the pixel value of the bone region.

Abstract: A scanner of a blood flow measurement apparatus of an embodiment alternately performs first scan and second scan for first and second cross sections both intersecting an interested blood vessel. An image forming unit forms one or more images of the first cross section including a phase image of the first cross section and an image of the second cross section. A blood vessel region specification unit specifies a first blood vessel region in any of the one or more images of the first cross section and a second blood vessel region in the image of the second cross section. A gradient calculation unit calculates a gradient of the interested blood vessel at the first cross section based on the first and second blood vessel regions. A blood flow information generation unit generates blood flow information based on the phase image and the gradient.

Abstract: A method of making a breast or chest mask that includes enhancing a bust size of a three dimensional (3D) image of a user that illustrates a current body shape, comparing the enhanced 3D image to the current body shape 3D image and subtracting the bust size of the enhanced 3D image from the current body shape 3D image to produce a breast mask product with dimensions based on the compared 3D images.

Abstract: There are included an acquiring unit configured to acquire a parameter regarding capturing of a first tomographic image of an eye to be examined, an acquiring unit configured to acquire a parameter regarding capturing of a second tomographic image of the eye to be examined, wherein capturing of the second tomographic image is being performed after capturing of the first tomographic image, and a warning unit configured to issue a warning against capturing of the second tomographic image in accordance with a comparison between the parameter regarding capturing of the first tomographic image and the parameter regarding capturing of the second tomographic image.

Abstract: A method for generating an image is provided. The method comprises capturing a first set of image pixels by an ultrasonic sensor comprising an array of ultrasonic transducers using a first beamforming pattern, wherein the first beamforming pattern comprises a first pattern of transmit signals routed to a plurality of ultrasonic transducers of the ultrasonic sensor. The method further comprises capturing a second set of image pixels at the ultrasonic sensor using a second beamforming pattern, wherein the second beamforming pattern comprises a second pattern of transmit signals routed to the plurality of ultrasonic transducers. The second beamforming pattern is different than the first beamforming pattern. The second set of image pixels corresponds to an edge region of the ultrasonic sensor. The method additionally comprises combining the first set of image pixels and the second set of image pixels to form the image.

Abstract: This positioning system (100) for a bone resecting instrumentation comprising a resection driver (2), comprises at least one of a gyroscopic sensor (8) integral in motion with the resection driver (2) and adapted to sense a deviation angle (?) with respect to a reference direction (X), and at least one positioning marker (12; 140) marking a fixed position on the reference direction (X), and a depth sensor (10; 18) integral in motion with the resection driver (2), for detecting a resection depth (d) based on the relative longitudinal positions of the positioning marker (12; 140) and the depth sensor (10). The invention also concerns a positioning kit including such a positioning system and a separate electronic device.

Abstract: A system (1) and a corresponding method enable an enhanced roadmapping visualization without unnecessary device-footprints. The system (1) includes an x-ray imaging device (3) for acquiring x-ray images and a calculation unit (5). The x-ray imaging device (3) is adapted for acquiring a first x-ray image (21) with an interventional device (17) present in the vessels (19) while no contrast agent is present in the vessels (19) and a second x-ray image (23) with the interventional device (17) present in the vessels (19) while contrast agent is present in the vessels (19). The calculation unit is adapted for creating a roadmap image (27) by subtracting the first x-ray image (21) from the second x-ray image (23) and automatically minimizing the visibility of the interventional device (17) in the roadmap image (27). A display unit (7) is adapted to display the roadmap image (27) or an overlay of a current fluoroscopy image (31) with the roadmap image (27).

Abstract: A patient management system of an embodiment includes a server, a plurality of ophthalmic examination apparatuses assigned to a plurality of patients, and a plurality of computers installed in a plurality of medical institutions. The ophthalmic examination apparatuses and computers are communicable with the server via a communication line. The server manages the account of each patient, and the account of each medical institution. Test data obtained by each of the ophthalmic examination apparatuses is stored in the account of a corresponding patient. The server sends information stored in the account of a patient to a computer installed in one of the medical institutions assigned in advance to the patient.

Abstract: A method is for training a convolutional neural network of a compensation unit. The method includes: provisioning a machine learning device, the machine learning device being designed for training the convolutional neural network; provisioning a start compensation unit, including an untrained convolutional neural network, on or at the machine learning device; provisioning a training image dataset including a plurality of medical training input images and at least one training output image, wherein a reference object is shown essentially without motion artifacts in the at least one training output image and the reference object concerned is contained in the plurality of medical training input images with different motion artifacts; and training the convolutional neural network of the compensation unit in accordance with a principle of machine learning, using the training image dataset. A compensation unit, a machine learning device, a control device for controlling a medical imaging system are also disclosed.

Abstract: Embodiments of the present invention provide an augmented reality by defining a model representing a real-world system. After defining the model, a plurality of model simulations are performed using the defined model which produce predicted field data that is stored in memory. In turn, data from one or more sensors in the real-world system is received and the defined model is calibrated using the received field data relative to the stored predicted field data. Then, an augmented reality of the real-world system is provided using the calibrated model.

Abstract: The present invention provides a surgical controlling system, comprising: a. at least one surgical tool configured to be insertable into a surgical environment of a human body for assisting a surgical procedure; b. at least one location estimating means configured to real-time locate the 3D spatial position of said at least one surgical tool at any given time t; c. at least one movement detection means communicable with a movement's database and with said location estimating means; and, d. a controller having a processing means communicable with a controller's database, said controller configured to control the spatial position of said at least one surgical tool; said controller's database is in communication with said movement detection means.

Abstract: A medical image processing apparatus according to an embodiment includes processing circuitry. The processing circuitry sets a first region of interest in a region corresponding to cardiac muscle on a cross-section of a heart included in image data. The processing circuitry further sets a second region of interest that is larger than the first region of interest in a region including the region. The processing circuitry determines a threshold for determining a range of signal values used for blood flow dynamic analysis on the image data based on a frequency distribution of signal values in the first region of interest. The processing circuitry carries out blood flow dynamic analysis on the second region of interest using signal values included in a range based on the threshold.

Abstract: A system and method of providing composite real-time dynamic imagery of a medical procedure site from multiple modalities which continuously and immediately depicts the current state and condition of the medical procedure site synchronously with respect to each modality and without undue latency is disclosed. The composite real-time dynamic imagery may be provided by spatially registering multiple real-time dynamic video streams from the multiple modalities to each other. Spatially registering the multiple real-time dynamic video streams to each other may provide a continuous and immediate depiction of the medical procedure site with an unobstructed and detailed view of a region of interest at the medical procedure site at multiple depths. A user may thereby view a single, accurate, and current composite real-time dynamic imagery of a region of interest at the medical procedure site as the user performs a medical procedure.

Abstract: An image processing system (IPS) includes an input port (IN) for receiving a surface image of an outer layer (OL) of a current biomechanical assembly (TOR). The surface image is acquired by a surface imaging apparatus (DSC) along at least one imaging direction. The assembly includes relative to the imaging direction behind the outer layer, an inner wall (RC) element coupled from behind to the outer layer. The image processing system further includes a wall estimator (WE) configured to provide an estimate for geometrical data of the inner wall element (RC), the estimate being based on image information as per the surface image.

Abstract: An ultrasonic medical system comprising a tracking probe and a catheter is used for tracking a target inside human body. The ultrasonic probe has additional ultrasound sensors embedded around its main transducer array. A catheter is built with ultrasound transmitters at its distal end and sends active sound signals during each probe scanning cycle. The probe sensors track the 3D position of the target catheter using triangulation principle. The target position is rendered in the 3D anatomic context defined by the ultrasound images.

Abstract: Methods for magnetic resonance fingerprinting (“MRF”) that are more robust to patient motion than conventional MRF techniques are described. The methods described in the present disclosure provide an image reconstruction algorithm for MRF that decreases the motion sensitivity of MRF.

Abstract: A portable positron emission tomography (PET) scanner includes a rotatable scan detector ring which can be rotated 90 degrees for imaging a patient in a vertical or horizontal orientation. In the vertical orientation, a patient can be standing or seating such that the aperture of the scan detector ring is raised to allow the patient to be within the scanning region and lower to perform the image scanning on the patient. In the horizontal orientation, a patient must be lying down on a platform whereby the platform is moved within the aperture of the scan detector ring to perform the image scanning on the patient. In this horizontal orientation, the scan detector ring is also stowed and secured to be moved to other scanning locations.

Abstract: Methods and systems for acquiring a plurality of data vectors at a first frequency and a plurality of data vectors at a second frequency, where the first frequency is greater than the second frequency. The plurality of first frequency data vectors can be formed into a first set of data vectors and the plurality of second frequency data vectors can be formed into a second set of data vectors. A first filter can be applied to the first set of data vectors to form a first modified data set and a second filter can be applied to the second set of data vectors to form a second modified data set. Based on the first and second modified data sets, a frequency response of an item in the imaging view can be determined. Using the determined frequency response of the item, an image is created on a display.

Abstract: An endoscope having an outer shaft member with a distal end forming a distal end of the endoscope and an optics member with a distal end. The optics member is located inside the outer shaft member. The optics member defines a viewing direction of the endoscope, the viewing direction being tilted relative to a longitudinal axis of the outer shaft member. The endoscope further has optical fibers comprising an optically transparent material and provided and conditioned for the transport of illumination light to the distal end of the endoscope. The endoscope further has a segment located between an outer surface region of the distal end of the optics member and an inner surface region of the distal end of the outer shaft member. The orientation of distal ends of the optical fibers is defined by the segment.

Abstract: A medical imaging system and method is described. The system comprises: a microwave antenna array comprising a transmitting antenna and a plurality of receiving antennae, wherein the transmitting antenna is configured to transmit microwave signals so as to illuminate a body part of a patient and the receiving antennae are configured to receive the microwave signals following scattering within the body part; a marker configured to be applied to the surface of the skin of the body part and to scatter the microwave signals; a processor configured to process the scattered microwave signals and generate an image of the internal structure of the body part and the marker so as to identify a region of interest within the body part relative to the position of the marker.

Abstract: The present invention relates to localization of a vascular treatment and quantification of a part of a vascular structure. It is described to provide (12) at least one first image comprising a representation of a region of interest of a vascular structure. At least one second image comprising a representation of the region of interest of the vascular structure is provided (14). Between an acquisition of the at least one first image and an acquisition of the at least one second image, a vascular treatment might have been applied to the region of interest of the vascular structure, wherein the representation of the region of interest of the vascular structure relates to spatial extension information of the vascular structure at least in one image plane. At least one reference image from an image set formed from the at least one first image and the at least one second image is selected (16).

Abstract: An electronic payment terminal includes a light guide to guide the light from at least one light source internal to the electronic payment terminal to the exterior of the electronic payment terminal. The light guide is integrated with a contactless payment module integrated with the electronic payment terminal and additionally includes at least one shock-absorbing pad extending beyond the external surface of the electronic payment terminal.

Abstract: In part, the invention relates to systems and methods of calibrating a plurality of frames generated with respect to a blood vessel as a result of a pullback of an intravascular imaging probe being pullback through the vessel. A calibration feature disposed in the frames that changes between a subset of the frames can be used to perform calibration. Calibration can be performed post-pullback. Various filters and image processing techniques can be used to identify one or more feature in the frames including, without limitation, a calibration feature, a guidewire, a side branch, a stent strut, a lumen of the blood vessel, and other features. The feature can be displayed using a graphic user interface.

Abstract: A plurality of analysis functions each corresponding to an organ are managed, and organ information is stored in such a manner as to correlate with a corresponding type of analysis function. The organ information indicates which of a plurality of regions included in the organ is to be subjected to thinning. Specification of one of the analysis functions is received from a user, and medical image data is acquired. A plurality of regions of an organ included in the acquired medical image data are identified. The identified plurality of regions of the organ, a region to be subjected to thinning is determined on the basis of the stored organ information and the received type of the analysis function. Thinning is performed on the determined region of the organ. An image of the thinned region is displayed together with an image of a region not subjected to thinning.

Abstract: Medical image data is identified, and a lung field region and an emphysema region in each of a plurality of tomographic images are extracted. A mechanism is provided, which is capable of calculating the ratio of the emphysema region to the lung field region, and displaying an image of the medical image data and a value representing the calculated ratio in association with each other.

Abstract: Apparatus, methods, and other embodiments associated with NMR fingerprinting are described. One example NMR apparatus includes an NMR logic that repetitively and variably samples a (k, t, E) space associated with an object to acquire a set of NMR signals that are associated with different points in the (k, t, E) space. Sampling is performed with t and/or E varying in a non-constant way. The NMR apparatus may also include a signal logic that produces an NMR signal evolution from the NMR signals, and a characterization logic that characterizes a resonant species in the object as a result of comparing acquired signals to reference signals. The NMR signal evolution may be assigned to a cluster based on the characterization of the resonant species. Cluster overlay maps may be produced simultaneously based, at least in part, on the clustering. The clusters may be associated with different tissue types.

Abstract: An apparatus, system, and method where the ultrasound transducer position registration is automated, calculates the position of each pixel in the ultrasound image in reference to the predetermined anatomical reference points (AR) and can store the information on demand. The graphic interface associated with the ultrasound image allows for the instant display of selected targets position coordinates relative to anatomical reference points, in the ultrasound images. This system would significantly reduce the ultrasound examination time, by eliminating the time consuming manual labeling of images and speeding up the target finding at subsequent examinations, enhance correlation capability with other diagnostic imaging modalities like CT scans, MRI, mammograms, decrease human errors and fatigue, provide an easy, uniform, method of communicating the target position among healthcare providers.

Abstract: A three-dimensional image processing apparatus includes a three-dimensional image acquisition unit that acquires a three-dimensional image obtained by imaging a test object; a graphical structure generation unit that generates a graphical structure of a tubular structure included in the three-dimensional image; a contour information acquisition unit that acquires contour information on the tubular structure at each point on the graphical structure; a viewpoint information acquisition unit that acquires viewpoint information in the tubular structure; a projection point specification unit that specifies projection points from respective points on the graphical structure on the basis of the viewpoint information and the graphical structure; and a projection image generation unit that generates a projection image obtained by projecting the contour information at the projection points on a two-dimensional plane.

Abstract: An image processing apparatus includes a tomographic signal obtaining unit that obtains tomographic signals of light beams, the light beams respectively having a different polarization from each other and being obtained by splitting combined light obtained by combining return light and reference light, the return light being from an object to be inspected that is irradiated with measuring light, and an information obtaining unit that obtains three-dimensional polarization tomographic information, and three-dimensional motion contrast information of the object to be inspected, by commonly using at least one of the obtained tomographic signals. In addition, an extracting unit extracts a specific region of the object to be inspected using the obtained three-dimensional polarization tomographic information, and an image generating unit generates a motion contrast enface image of the extracted specific region using the obtained three-dimensional motion contrast information.

Abstract: A method for generating an image is provided. The method comprises capturing a first set of image pixels by an ultrasonic sensor comprising an array of ultrasonic transducers using a first beamforming pattern, wherein the first beamforming pattern comprises a first pattern of transmit signals routed to a plurality of ultrasonic transducers of the ultrasonic sensor. The method further comprises capturing a second set of image pixels at the ultrasonic sensor using a second beamforming pattern, wherein the second beamforming pattern comprises a second pattern of transmit signals routed to the plurality of ultrasonic transducers. The second beamforming pattern is different than the first beamforming pattern. The second set of image pixels corresponds to an edge region of the ultrasonic sensor. The method additionally comprises combining the first set of image pixels and the second set of image pixels to form the image.

Abstract: A method and apparatus for capturing a magnetic resonance image in which processes of generating T1 contrast for different regions of an object overlap with each other, thereby obtaining a magnetic resonance image having an improved contrast between different tissues within a short time. Therefore, a time required for obtaining a magnetic resonance image may be reduced, and a magnetic resonance image enabling improved diagnosis of a disease or other abnormal condition may be provided.

Abstract: An ophthalmic imaging apparatus of an embodiment includes a data acquisition unit, a blood vessel enhanced image forming unit, and a blood vessel gradient distribution determination unit. The data acquisition unit is configured to acquire a three dimensional data set of a fundus of a subject's eye using optical coherence tomography (OCT). The blood vessel enhanced image forming unit is configured to form a blood vessel enhanced image based on the three dimensional data set. The blood vessel gradient distribution determination unit is configured to determine a blood vessel gradient distribution that shows gradients of blood vessels at a plurality of locations in the fundus, based on the blood vessel enhanced image.

Abstract: The disclosure herein provides methods, systems, and devices for improving optical coherence tomography machine outputs through multiple enface optical coherence tomography angiography averaging techniques. The embodiments disclosed herein can be utilized in ophthalmology for employing optical coherence tomography (OCT) for in vivo visualization of blood vessels and the flow of blood in an eye of a patient, which is also known generally as optical coherence tomography angiography (OCTA).

Abstract: An ultrasound scanning apparatus, a breathing machine, a medical system and a related method. The ultrasound scanning apparatus comprises an ultrasound scanning unit, an ultrasound controller for controlling the operation of the ultrasound scanning unit, detecting the operation state of the ultrasound scanning unit, generating a first enable signal when detecting that the operation state of the ultrasound scanning unit is transferred from an operating state to a nonoperating state and generating a second enable signal when detecting that the operation state of the ultrasound scanning unit is transferred from the nonoperating state to the operating state, and an enable output end for transmitting the first enable signal or the second enable signal to the breathing machine to control the running of the breathing machine.