Abstract: A system for coordinating radiation therapy and imaging processes includes a radiation therapy system an radiation source mounted on a robotically-controlled system to move the radiation source about a subject to direct radiation to a target area in the subject according to a treatment plan. The system also includes an imaging system configured to acquire imaging data from a subject. The imaging system and the radiation therapy system are independently movable. The system also includes a coordination system configured to coordinate operation of the imaging system to acquire the imaging data from the subject during movement of the radiation source about the subject according to the treatment plan to avoid collisions of the radiation therapy system with the imaging system.

Abstract: A garment for bringing an EM transducer to contact with a thoracic skin surface area of a wearer is disclosed. The garment comprises a thoracic garment having a EM transducer placement portion and a pressure applying element associated with the EM transducer placement portion for applying a pressure on an EM transducer secured in an associated the EM transducer placement portion when the thoracic garment is worn by a wearer so that the EM transducer applies a respective pressure on a thoracic skin surface area of the wearer.

Abstract: Disclosed herein are methods for patient setup and patient target region localization for the irradiation of multiple patient target regions in a single treatment session. Virtual localization is a method that can be used to register a patient target region without requiring that the patient is physically moved using the patient platform. Instead, the planned fluence is updated to reflect the current location of the patient target region by selecting a localization reference in the localization image, calculating a localization function based on the localization reference point, and calculating the delivery fluence by convolving the localization function with a shift-invariant firing filter. Mosaic multi-target localization partitions a planned fluence map for multiple patient target regions into sub-regions that can be individually localized.

Abstract: An ultrasound diagnostic apparatus (1), which performs a compression test with respect to at least two points of a popliteal vein and a common femoral vein of a subject, includes an ultrasound probe (15), an image acquisition unit (8) that acquires an ultrasound image by transmitting an ultrasound beam toward the subject from the ultrasound probe (15), a vein detection unit (9) that detects the popliteal vein included in the ultrasound image, and an operation guiding unit (10) that guides a user, in a case where the compression test of the popliteal vein is performed, to operate the ultrasound probe such that the ultrasound probe (15) is positioned at a position in which only one popliteal vein is included in the ultrasound image based on the number of the popliteal veins detected by the vein detection unit (9).

Abstract: An X-ray detector according to an embodiment is an X-ray detector configured by arranging a plurality of detector modules, and includes a first detector module, a second detector module, a voltage application circuit, a first transmission circuit, and a first reception circuit. The second detector module is adjacent to the first detector module among the detector modules. The voltage application circuit is disposed in each of the detector modules, and applies a voltage to a plurality of detection elements included in each of the detector modules. The first transmission circuit is disposed in the first detector module, and transmits a signal based on the voltage from the voltage application circuit of the first detector module. The first reception circuit is disposed in the second detector module, and receives a signal transmitted from the first transmission circuit.

Abstract: A computed tomography (CT) machine system and a state monitoring method are described. The CT machine system comprises a drum-shaped component, a 3D camera, and a control system. The drum-shaped component comprises a cylindrical body, with the center of the cylindrical body being provided with a hollow portion which is rotationally symmetrical about the central axis of the cylindrical body, a rotating component disposed in the cylindrical body rotating about the central axis, a plurality of trigger marks arranged in the rotating component, and a window provided in the cylindrical body. The 3D camera generates image data that is transferred to the control system, from which the control system determines state data of the CT machine. The 3D camera captures an image of the trigger marks through the window to generate marked image data.

Abstract: Treatment instrument with movable handle and fixed handle includes biasing member for biasing the movable handle in an opening direction and an assist system with attraction force, e.g., magnetic force, to attract the movable handle in a closing direction toward the fixed handle. Range of movement of movable handle includes first movable range and second movable range. The second movable range occurs when a second gripping piece, e.g. a jaw, is in contact with respect to a first gripping piece, e.g., a vibration transmission member, and the movable handle is then further moved in a direction toward the fixed handle to a fully closed position. In the second movable range, attraction forces associated with the assist system are smaller than biasing force from the biasing member so that, upon release of a gripping force by an operator, the movable handle moves away from the fixed handle.

Abstract: The present invention provides a PHHM for the measurement of a subject's BP and, optionally, one or more other vital signs, comprising a housing located on a PHHCD or a hand-held component of a computing system; a blood flow occlusion means located in the housing such that, when the housing is located on the PHHCD or the hand-held component, an open surface of the blood flow occlusion means is available to be pressed against a body part of the subject or to have a body part of the subject pressed against it; a pressure sensor adapted to provide an electrical signal indicative of the pressure applied to or by the open surface; a means for detecting the flow of blood in the body part of the subject when pressure is applied to or by the open surface; and means for receiving electrical signals from the pressure sensor and the blood flow detecting means and for transmitting electrical signals indicative of the pressure and blood flow to the processor of the PHHCD or the computing system, wherein the processor of t

Abstract: Systems and methods for positioning in medical systems are provided. The system may obtain data associated with a scanning range of a subject. The system may also obtain an image of the subject on a couch of a medical radiation device. The image may be acquired by an imaging device when the couch is at a first position. The system may determine a position of the scanning range of the subject in the image. The system may further cause, based on the position of the scanning range in the image, the couch to move to a second position. The scanning range of the subject may be in a radiation region of the medical radiation device when the couch is located at the second position.

Abstract: A parenteral nutritional diagnostic system, apparatus, and method are disclosed. In an example, a parenteral nutritional diagnostic apparatus determines muscle quantity and muscle quality of a patient's psoas muscle to determine a nutritional status of the patient. An image interface is configured to receive a medical image including radiodensity data related to imaged tissue of the patient. The apparatus also includes a processor configured to use the medical image to determine a tissue surface area for each different value of radiodensity and determine a distribution of the tissue surface area for each radiodensity value. The processor is configured to determine muscle quality by locating a soft tissue peak within the distribution that corresponds to a local peak in at a region related to at least one of muscle tissue, organ tissue, and intramuscular adipose tissue. The processor determines the nutritional status of the patient based on the soft tissue peak.

Abstract: An ultrasonic diagnostic device according to an embodiment includes reception circuitry and processing circuitry. The reception circuitry outputs a plurality of reception signals corresponding to a plurality of reception scanning lines for each time of transmission/reception of ultrasonic waves performed by an ultrasonic probe. The processing circuitry performs filter processing on each of a plurality of first reception signals output from the reception circuitry based on a first ultrasonic wave transmitted from the ultrasonic probe using at least one specific second reception signal among a plurality of second reception signals output from the reception circuitry based on a second ultrasonic wave the sound field of which is adjacent to or partially overlapped with a sound field of the first ultrasonic wave. The processing circuitry generates image data based on the first reception signals subjected to the filter processing.

Abstract: Methods and systems are provided for adaptive scan control. In one embodiment, a method includes, upon a first contrast injection of a first contrast bolus, processing acquired projection data of a subject to measure a contrast signal of the first contrast bolus, setting a timing for a second contrast injection of a second contrast bolus to a fallback injection timing, and responsive to identifying an adaptive injection timing for the second contrast injection based on the contrast signal before the fallback injection timing is reached, updating the timing for the second contrast injection to the adaptive injection timing and commanding initiation of the second contrast injection at the adaptive injection timing, otherwise commanding initiation of the second contrast injection at the fallback injection timing.

Abstract: For decision support based on perfusion in medical imaging, a machine-learned model, such as a model trained with deep learning, generates perfusion examination information from CT scans of the patient. Other information, such as patient-specific information, may be used with the CT scans to generate the perfusion examination information. Since a machine-learned model is used, the perfusion examination information may be estimated from a spatial and/or temporally sparse number of scan shots or amount of CT dose. The results of perfusion imaging may be provided with less than the current, standard, or typical radiation dose.

Abstract: A thermal image analyzer includes a processor to receive a thermal image from at least one portable electronic device, with the thermal image being of an anatomical area of a patient, and determine an assessment on vascular health of the patient based on comparing the thermal image to a database of thermal images. The processor transmits the assessment in real-time to the at least one portable electronic device.

Abstract: Systems and methods are provided for imaging coronary trees via registration of angiographic projections with computed tomographic data. In one example, a method for imaging a coronary artery of interest in a patient may include acquiring computed tomography (CT) imaging data depicting a coronary tree, acquiring a single angiographic projection of the coronary artery of interest, registering the single angiographic projection to the CT imaging data, and determining a fractional flow reserve (FFR) of the coronary artery of interest based on the single angiographic projection registered to the CT imaging data.

Abstract: The invention relates to systems and methods to assist physicians in decision making for stroke patients. In particular the systems and methods can be used to assist physicians to decide on whether a patient with an acute ischemic stroke has a large vessel occlusion (LVO) and should be transferred from a community hospital to a larger hospital to undergo an endovascular thrombectomy procedure.

Abstract: The invention provides for a medical apparatus (100, 200, 300, 500) comprising an optical imaging system (106) configured for acquiring a series of optical images (544) descriptive of cardiac motion of a subject (102). The medical apparatus further comprises a memory (534) for storing machine executable instructions (540). The medical apparatus further comprises a processor (530) for controlling the medical apparatus. Execution of the machine executable instructions causes the processor to repeatedly: acquire (400) a series of images using the optical imaging system, wherein the series of images are acquired at a rate of at least 10 frames per second; and derive (402) a cardiac motion signal (546) from the series of images, wherein the cardiac motion signal is derived by tracking motion of at least a group of pixels within the series of images.

Abstract: The invention provides an ultrasound production source comprising a body containing an ultrasound transducer presenting in front an emission face, the body including an opening (5) defined by a tubular wall (6) and arranged so that the emission face of the ultrasound transducer faces towards the opening (5), the tubular wall (6) being provided externally with at least one thread (17) of a screw thread assembly system for co-operating with at least one complementary thread (16) either of a fastener ring (15) for fastening a flexible membrane (8) on the body, or of a protective cover, or of a ring fitted with an alignment system.

Abstract: A method and system are provided for measuring post-translational modification of proteins in a subject. The method comprises recording of infrared radiation within a predetermined wavenumber range and attenuated by an integument of the subject, such that the integument is still attached to the subject. The method further comprises the step of comparing the attenuation of infrared radiation to a predetermined value for deriving information regarding post-translational modification of proteins in the integument.

Abstract: Disclosed herein are methods and apparatus for the imaging of brain electrical activity from electromagnetic measurements, using deep learning neural networks where a simulation process is designed to model realistic brain activation and electromagnetic signals to train generalizable neural networks and a residual convolutional neural network and/or a recurrent neural network is trained using the simulated data, capable of estimating source distributions from electromagnetic measurements, and their temporal dynamics over time, for pathological signals in diseased brains, such as interictal activity and ictal signals, and physiological brain signals such as evoked brain responses and spontaneous brain activity.