An analyzer (124) includes a quantifier (204) configured to quantify an amount of contrast material representing scar tissue created by ablation for tissue of interest in contrast enhanced imaging data and a recommender (210) configured to generate a signal indicative of a recommendation to further ablate the tissue of interest in response to the quantified amount of the contrast material not satisfying a pre-determined threshold. A method includes obtaining contrast enhanced image data indicative of scar tissue created by ablation of tissue of interest, quantifying an amount of contrast material for the scar tissue in the tissue of interest, and generating a signal indicative of a recommendation to further ablate the tissue of interest in response to the quantified amount of the contrast material not satisfying a pre-determined threshold.

A system and method utilizing a camera device containing an inertial measuring unit or similar orientation mechanism to calibrate alignment of the camera device according to a primary image such as displayed on an imaging screen, and then utilizing this calibration data to guide the system or user in acquiring a spatially aligned digital image using the camera device. Steps include recording the spatial orientation of the camera in at least two spatial dimensions when aligned with the primary image, and guiding camera alignment relative to the imaging screen when taking a picture.

Improved systems and devices for pre-caching of related medical imaging are provided. A medical imaging order may be received from a medical facility that includes medical imaging of a site generated by a medical imaging device. The medical imaging order may include metadata, such as user data, site data, and modality data. A search may be executed for supplemental medical imaging of the user using the user data. The supplemental medical imaging may be filtered using the site data to return only that medical imaging related to the site. The filtered supplemental medical imaging may be prioritized using the modality data. The prioritized supplemental medical imaging may be appended to the request, and the request may be transmitted to a radiologist for generation of a medical imaging report.

The invention provides, in some aspects, a system for implementing a rule derived basis to display volumetric image sets. In various embodiments of the invention, the selection of the images to be displayed, the generation of the 3-D volumetric image from measured 2-D images including the rendering parameters and styles, the choice of viewing directions and 2-D projection images based on the viewing directions, the layout of the projection images, and the formation of a video can be determined using a rule derived basis. In an embodiment of the present invention, the user is presented with sequential images making up a video displayed based on their preferences without having to first manually adjust parameters. The present invention allows for novel ways of viewing such images to detect microcalcifications and obstructions when reviewing Digital Breast Tomosynthesis and other volumetric mammography images.

The present disclosure relates to systems and methods for configuring a medical device for a medical procedure. The systems may perform the methods to initialize a gantry angle of a medical device of a new scan. The systems may also perform the methods to obtain a pre-set gantry angle associated with the new scan. The systems may also perform the methods to determine whether the initialized gantry angle is consistent with the pre-set gantry angle. The systems may also perform the methods to adjust the initialized gantry angle of the medical device to the pre-set gantry angle in response to a determination that the initialized gantry angle is inconsistent with the pre-set gantry angle.

An X-ray detector includes a plurality of photodiodes arranged in a matrix shape and respectively connected to switching devices, a plurality of gate lines formed in a first direction and connected to the switching devices; a plurality of data lines, wherein N data lines are formed in each second-direction column of the matrix shape, wherein N is greater than 1; and a read-out circuit connected to the plurality of data lines and configured to read out photocurrents from the plurality of photodiodes and convert the photocurrents into X-ray image data, wherein each of switching devices included in each second-direction column of the matrix shape is connected to one of the N data lines.

Systems and methods are disclosed for determining individual-specific blood flow characteristics. One method includes acquiring, for each of a plurality of individuals, individual-specific anatomic data and blood flow characteristics of at least part of the individual's vascular system; executing a machine learning algorithm on the individual-specific anatomic data and blood flow characteristics for each of the plurality of individuals; relating, based on the executed machine learning algorithm, each individual's individual-specific anatomic data to functional estimates of blood flow characteristics; acquiring, for an individual and individual-specific anatomic data of at least part of the individual's vascular system; and for at least one point in the individual's individual-specific anatomic data, determining a blood flow characteristic of the individual, using relations from the step of relating individual-specific anatomic data to functional estimates of blood flow characteristics.

A medical radiology system comprises an external x-ray source (1) and a CMOS image sensor (2) that is connected via a USB link (4) by way of USB peripheral of a device (3) for digitally processing the image data of the sensor. A tracking device is placed on the USB link (4) in order to continuously read and decode the data transmitted over this link in a way that is transparent to the device and to the sensor, and to detect, in the transmitted data stream, one particular datum (XAMC=1) representing a signal indicating detection, by the sensor, that a sufficient dose of radiation has been received. On detection of this particular datum, the tracking device sends an electrical signal Stop-X to the radiation source, in order to stop the emission of the radiation. The system is especially suitable for taking dental radiology images with an intra-oral CMOS sensor.

A radiographing system includes a mobile terminal configured to store an examination time of a subject that is based on examination-related information about the subject, a radiographing apparatus configured to take a radiation image of the subject based on the examination-related information and to store an imaging time of the radiation image, and an association unit configured to associate the radiation image with the examination-related information based on the imaging time and the examination time.

A method, apparatus and computer program product provide improved image processing techniques. An example of a method includes receiving a source image, programmatically identifying a plurality of anatomical elements within the source image through use of a computer vision technique, determining a first region of the source image corresponding to a first anatomical element, determining a second region of the source image corresponding to a second anatomical element, applying at least one first configuration setting to the first region, applying at least one second configuration setting to the second region, the at least one second configuration setting different from the at least one first configuration setting, and generating a merged image, wherein the merged image comprises the first region as visualized according to the at least one first configuration setting and the second region as visualized according to the at least one second configuration setting.