Abstract: A method may include obtaining a plurality of local input functions of an object, each of the plurality of local input functions being of a scanning area of the object. One of the plurality of local input functions may be obtained based on a scan for one of a plurality of table positions where a table for placing the object is located. Adjacent table positions in the plurality of table positions may correspond to an overlapping scanning area. The method may also include obtaining local input functions of at least one overlapping scanning area based on the plurality of local input functions; and determining a continuous input function of at least a portion of a target scanning area based on the local input functions of the at least one overlapping scanning area.

Abstract: A detector module may be provided. The detector module may comprise one or more detector elements. Each of the one or more detector elements may include a detector crystal, a basal board, a supporting component, and a flexible board. The detector crystal may be mounted on a side of the basal board and configured to receive rays from a subject and generate a detection signal based on the rays. The supporting component may be configured to support the basal board. The supporting component may include a concave structure for accommodating at least a portion of the flexible board.

Abstract: The present disclosure provides a camera calibration method, system, storage medium for X-ray imaging. The method may include acquiring at least one image taken by a camera to be calibrated, wherein the at least one image may include a calibration target, and the calibration target may include at least one calibration point; selecting any calibration point of the at least one calibration point as a target calibration point; determining, based on the at least one image, image coordinates of the target calibration point; obtaining a first position and a second position of an X-ray imaging device; determining, based on the first position and the second position, spatial coordinates of the target calibration point; and performing calibration on the camera to be calibrated based on the image coordinates and the spatial coordinates.

Abstract: The present disclosure relates to a system for PET imaging. The system may include a first device and a second device. The first device may include a first scanning channel. The second device may include a second scanning channel connected to the first scanning channel, a heat generating component, and a cooling assembly configured to cool the heat generating component, wherein the cooling assembly may include an inlet chamber and a return chamber, the heat generating component may be closer to a first side of the second device than at least one of the inlet chamber or the return chamber, and the first side of the second device may face the first device.

Abstract: Systems and methods for adjusting a beam-limiting device, the beam-limiting device including a plurality of movable components for shaping a radiation beam. The methods may include for each of the plurality movable components, determining an initial location of the movable component; determining a target location of the movable component; and determining, based on the initial location and the target location, a moving route of the movable component. The methods may also include causing the plurality of movable components to move along their respective moving routes. During the movement of the plurality of movable components along their respective moving routes, the shape of an irradiation region of the radiation beam passing through the beam-limiting device may remain unchanged or substantially unchanged.

Abstract: Methods and devices for magnetic resonance imaging are provided in embodiments of the present disclosure. The method may include determining, based on undersampling K-space data of a plurality of phases of an object, a first coil sensitivity map, the undersampling K-space data being obtained through Cartesian sampling, determining, based on the first coil sensitivity map and the undersampling K-space data, a plurality of intermediate reconstruction images, each of the plurality of the intermediate reconstruction images corresponding to one of the plurality of phases, and determining, based on the plurality of intermediate reconstruction images, an optimized dynamic image of the object through optimization processing.

Abstract: An imaging device is provided. The imaging device includes: one or more imaging sources; and a plurality of detectors combined by joining, the plurality of detectors being configured to receive one or more imaging beams emitted by the one or more imaging sources.

Abstract: Transmission cable assemblies and methods for suppressing common-mode currents on a transmission cable are provided. The transmission cable assembly may include a transmission cable and at least one trap fitted on the transmission cable. Each trap may include a first coil and a second coil in opposite helical directions and assembled to allow the transmission cable to insert through. The first coil and the second coil form a resonant circuit for reducing common-mode currents on the transmission cable. When there are multiple traps fitted on the transmission cable, they are spaced apart along the longitudinal axis of the transmission cable and an insulating component is placed between every two adjacent traps. The designs can make the trap filters smaller and lighter in weight while effectively reducing the impact on the local radiofrequency (B1) field.

Abstract: The disclosure relates to a system and method for image reconstruction. The method may include the steps of: obtaining raw data corresponding to radiation rays within a volume, determining a radiation ray passing a plurality of voxels, grouping the voxels into a plurality of subsets such that at least some subset of voxels are sequentially loaded into a memory, and performing a calculation relating to the sequentially loaded voxels. The radiation ray may be determined based on the raw data. The calculation may be performed by a plurality of processing threads in a parallel hardware architecture. A processing thread may correspond to a subset of voxels.

Abstract: One or more embodiments of the present disclosure relate to a radiotherapy target device. The radiotherapy target device may include: a target component including a target body and a support supporting the target body; and a housing surrounding the target component. The housing may include a first surface and a second surface allowing radiation beams to pass through.

Abstract: The present disclosure provides a system and method for couch position calibration. The method may include obtaining one or more first images of a couch at one or more first locations in a first device, each of the one or more first images corresponding to one of the one or more first locations, wherein the couch includes a mark, and the mark intersects a first reference plane of the first device at a plurality of first points of the mark; determining, in each of the one or more first images, a first position of a representation of each of the plurality of first points; obtaining correlation information between the first position and actual position of each of the plurality of first points; and determining one or more calibration images based on the correlation information and the one or more first images.

Abstract: According to an aspect of the present disclosure, a beam control device for radiotherapy is provided. The beam control device may include an electron beam generator configured to emit an electron beam for radiotherapy toward a subject in a first direction. The beam control device may further include a first deflection device configured to generate a defocused electron beam by defocusing the electron beam in a second direction, the second direction being different from the first direction.

Abstract: A 3D anatomical model of one or more blood vessels of a patient may be obtained using CT angiography, while a 2D image of the blood vessels may be obtained based on fluoroscopy. The 3D model may be registered with the 2D image based on a contrast injection site identified on the 3D model and/or in the 2D image. A fused image may then be created to depict the overlaid 3D model and 2D image, for example, on a monitor or through a virtual reality headset. The injection site may be determined automatically or based on a user input that may include a bounding box drawn around the injection site on the 3D model, a selection of an automatically segmented area in the 3D model, etc.

Abstract: The present disclosure provides a gantry for an X-ray system. The gantry may include a base section, a lifting section, and a swing section. The base section may be configured to move. A first end of the lifting section may be connected to the base section. A first end of the swing section may be rotatably connected to a second end of the lifting section. A radiation assembly may be disposed on a second end of the swing section.

Abstract: A method and system for scanning are provided. The method may include obtaining one or more images of a target subject acquired by an imaging device; determining a three-dimensional (3D) geometric model of the target subject based on the one or more images; obtaining an anatomical structure model of at least a portion of the target subject; obtaining a combination model by combining the 3D geometric model of the target subject and the anatomical structure model of at least a portion of the target subject; and determining one or more scanning parameters of the target subject based on the combination model.

Abstract: The present disclosure provides a medical device and a control system. The control system may achieve a motion control of the medical device: obtaining a target position of the medical device, determining a target motion path of the medical device according to a current position and the target position of the medical device, and controlling the medical device to move from the current position to the target position along the target motion path. The control system may also perform an information registration control method for the medical device: obtaining load change information related to the medical device, and determining an operation instruction related to a registration record of the medical device based on the load change information and a preset change condition. The medical device may include a radiation source, a detector, a C-arm, and a display.

Abstract: The present disclosure relates to a system for PET imaging. The system may include a detector module and an electronics module. The detector module may include a scintillator array having N rows of scintillators arranged in a first direction and M columns of scintillators arranged in a second direction, a first set of photosensors coupled to the scintillator array and extending in the second direction, and a second set of photosensors coupled to the scintillator array and extending in the first direction. The electronics module may detect a first set of electrical signals generated by the first set of photosensors and a second set of electrical signals generated by the second set of photosensors, and identify a scintillator within the scintillator array that has interacted with an impinging radiation ray relating to an electrical signal of the first set of electrical signals or the second set of electrical signals.

Abstract: The embodiments of the present disclosure provide a biosensor, the biosensor includes a working electrode, the working electrode includes an enzyme membrane layer, the enzyme membrane layer includes a sensitive moiety immobilized with an oxidized natural polymer compound as a cross-linking agent, and the oxidized natural polymer compound is obtained by oxidizing a natural polymer compound.

Abstract: A method for determining a centerline of a blood vessel in an image associated with a subject is provided. The method includes obtaining a centerline model used for identifying a centerline of a blood vessel and identifying the centerline of the blood vessel based on the centerline model.

Abstract: Multiple predictions about the position of an object during a time period may each indicate the position of the object at a respective time during the time period. Respective validity indications corresponding to the multiple predictions may each indicate an accuracy of the corresponding prediction. Whether a change has occurred in a distribution of the predictions from a first subset of predictions to a second subset of predictions during the time period may be determined. If the change has occurred, a prediction from the first subset of predictions or the second subset of predictions may be selected, based on the validity of the predictions and/or the detection of a motion, as a best indication of the position of the object.