MRI for radiotherapy simulation, planning and/or treatment guidance requires accurate motion assessment and real-time tumor monitoring. Clinical image-guided radiotherapy requires precise quality assurance of targeted tumor geometry and motion phase and amplitudes for both MRI and CT images. In various embodiments, the MRI-CT compatible phantom described herein is designed to validate the accuracy and performance of clinical procedures in both a 4D MRI sequence and 4D CT imaging, and to provide equivalent dynamic image contrast and quality for both imaging modalities. Additionally described is a PET compatible phantom.

A radiotherapy equipment is provided. The radiotherapy equipment comprises at least two radiation apparatuses, the radiation apparatuses are configured to be capable of emitting radiation beams, the radiation beams emitted by at least two of the radiation apparatuses intersect at an intersection point, the radiation apparatuses are rotatable circumferentially about a rotation axis, and radiation positions of at least two of the radiation apparatuses are positioned at different cross-sections with respect to the rotation axis.

The present disclosure provides a radiation therapy device and system. The radiation therapy device includes a first treatment head and a second treatment head. A beam emitted from the second treatment head intersects with a beam emitted from the first treatment head at an intersection point. The first treatment head is an X-ray treatment head, and the second treatment head is an X-ray treatment head, a multi-source focusing treatment head, or an intensity-modulated treatment head. The radiation therapy device may increase a dose rate at the intersection point.

A Nuclear Medicine (N-M) imaging system including a gantry having a stationary stator and a rotor rotatably mounted on the stator and including detection units. The rotor is driven by a rotor driving assembly including a linear encoder. The detection units mounted on the rotor include scanning columns having one or more Multi-Pixel Photon Counter (MPC) mounted on one or more extendable arm. The gantry also includes flat cables connecting the controller with gantry components, e.g., the scanning column Multi-Pixel Photon Counters (MPC). The scanning columns are pivotably moveable by a scanning column driver system including a rotary encoder.

Systems and methods for a laser-assisted topical treatment of nail fungal infections are provided. The laser-assisted topical treatment includes a laser that is configured to output a beam that penetrates the infected nail and creates a channel therethrough. The laser-assisted topical treatment further includes a treatment agent comprising a vehicle and a drug. The treatment agent is applied to an exterior surface of the infected nail so that the treatment agent may flow into the channel.

The present invention provides a focused radiotherapy apparatus comprising: at least one source part, provided with a plurality of radioactive sources arranged thereon; at least one collimation part enclosing the source part, and comprising a plurality of collimators aligned corresponding to the radioactive sources, the radiation rays emitted by the plurality of radioactive sources passing through the collimators and then converging to a focal point for treatment.

The present invention provides a focused radiotherapy apparatus comprising: at least one source part, provided with a plurality of radioactive sources arranged thereon; at least one collimation part enclosing the source part, and comprising a plurality of collimators aligned corresponding to the radioactive sources, the radiation rays emitted by the plurality of radioactive sources passing through the collimators and then converging to a focal point for treatment.

The present disclosure relates to a source body, a radiotherapy device and a drive method thereof, belonging to the field of medical technologies. The source body is provided with a plurality of radioactive sources, and an angle between the plurality of radioactive sources in a longitudinal direction is within a preset angle range. The source body, the radiotherapy device and the drive method thereof can protect sensitive tissues and organs in a treatment process.

Devices, systems, and methods for repositioning organs, such as the rectum, during radiation therapy treatments, are described.

An apparatus for laser therapy comprises a frame on which a plurality of lasers slide at several wavelengths in motorized and automated manner for applying the laser on and through the skin and mucous membranes of a patient. The frame is also motorized, allowing installation on the patient without moving the patient from bed. The apparatus is programmed to determine treatment autonomously on the basis of parameters determined by the apparatus during pretreatment and to vary treatment parameters in real time for treatment optimization and safety purposes.