A radiotherapy apparatus for an animal comprises a treatment part including an accommodation space for placing an animal, an irradiation part including an electron generator and a linear accelerator coupled to one side of the electron generator and disposed in a direction perpendicular to the treatment part, the linear accelerator being configured to emit radiation toward the treatment part, and an image acquisition part located at a preset interval from the treatment part along an irradiation direction of the radiation and configured to obtain an image of an irradiation area when the radiation is applied, wherein the radiation has an output of 1 MeV to 2 MeV so as to be applied to a diseased part located within a predetermined distance range from epidermis of the animal.

Methods for setting up, maintaining and operating a radiopharmaceutical infusion system, that includes a radioisotope generator, are facilitated by a computer of the system. The computer may include pre-programmed instructions and a computer interface, for interaction with a user of the system, for example, in order to track contained volumes of eluant and/or eluate, and/or to track time from completion of an elution performed by the system, and/or to calculate one or more system and/or injection parameters for quality control, and/or to perform purges of the system, and/or to facilitate diagnostic imaging.

An x-ray micro-beam radiation production system is provided having: a source of accelerated electrons, an electron focusing component configured to focus the electrons provided by the source, and a target which produces x-rays when electrons impinge thereon from the source. The electron focusing component is configured to focus the electrons provided by the source such that they impinge at a focal spot having a width δ formed on a surface of the target. The focusing component is configured to move the electron beam relative to the target such that the focal spot moves across the target surface in the width direction, and/or the target is movable relative to the focusing component such that the focal spot moves across the target surface in the width direction, the surface velocity of the focal spot across the target surface in the width direction being greater than v.sub.t where:formula (I), k, ρ and c denoting respectively the heat conductivity, the density and the heat capacity of the target material, and d denoting the electron penetration depth in the target material.

[00001]$v_t=\frac{\pi k}{4\rho c}.Math.\frac{\delta }{d^2},$

An x-ray micro-beam radiation production system is provided having: a source of accelerated electrons, an electron focusing component configured to focus the electrons provided by the source, and a target which produces x-rays when electrons impinge thereon from the source. The electron focusing component is configured to focus the electrons provided by the source such that they impinge at a focal spot having a width δ formed on a surface of the target. The focusing component is configured to move the electron beam relative to the target such that the focal spot moves across the target surface in the width direction, and/or the target is movable relative to the focusing component such that the focal spot moves across the target surface in the width direction, the surface velocity of the focal spot across the target surface in the width direction being greater than v.sub.t where: formula (I), k, ρ and c denoting respectively the heat conductivity, the density and the heat capacity of the target material, and d denoting the electron penetration depth in the target material. $\begin{array}{cc}{v}_t=\frac{\pi k}{4\rho c}.Math.\frac{\delta }{d^2},& \left(I\right)\end{array}$

A method can comprise irradiating an active element having an initial total activity between zero and thirty curies of ytterbium-169 and a volume between about two cubic millimeters and about four cubic millimeters. Irradiation can be ceased before the active element surpasses a total activity of thirty curies and an activity concentration of ten curies per cubic millimeter.

A minimally invasive neutron beam generating device is provided. The minimally invasive neutron beam generating device includes a proton accelerator, a target, and a neutron moderator. The proton accelerator is connected to a first channel, the target is located at one end of the first channel, and the neutron moderator covers the end of the first channel so that the target is embedded in the neutron moderator. In addition, the neutron moderator includes an accommodating element for accommodating a moderating substance, and the accommodating element is retractable.

Infusion system configurations and assemblies facilitate routing of infusion circuit tubing lines. Tubing lines are routed into and out from compartments of a shielding assembly for the infusion system, at locations which prevent kinking and/or crushing of the lines, and/or provide for ease in assembling the circuit. A plurality of the lines may be held together by a support frame to form a disposable infusion circuit subassembly, that can further facilitate routing of the lines.

According to the present invention, disclosed is a radiotherapy apparatus for an animal, comprising: a treatment part including an accommodation space for placing an animal thereon; an irradiation part including an electron generator and a linear accelerator coupled to one side of the electron generator and placed in a direction perpendicular to the treatment part for emitting radiation toward the treatment part; and an image acquisition part, positioned at a predetermined interval with the treatment part along the direction of the emitting of radiation, for acquiring an image of an irradiation area when radiation is emitted, wherein an output of radiation is between 1 and 2 MeV so that radiation is emitted to an affected area positioned within a predetermined distance from the epidermis of the animal.

A method for preparing for brachytherapy, a brachytherapy method, and a brachytherapy system are provided and involve using an applicator to be placed onto a radiation source, and an applicator guide to be inserted into an object to be irradiated. The applicator guide being formed such that the applicator can be inserted into the applicator guide. A position and orientation of the applicator guide are sensed by a navigation system, a position and orientation of an insertion assistance graphic object in a graphical representation are determined based on the sensed position and orientation of the applicator guide by a data processing device and the insertion assistance graphic object is displayed in the graphical representation by a display device. By its shape and being presented in the graphical representation, the insertion assistance graphic object is suitable for making it easier for a viewer to insert the applicator into the applicator guide.

Real-time X-ray dosimetry sensing in intraoperative radiation therapy (IORT). According to one aspect, a treatment head comprises at least one X-ray component configured to facilitate generation of therapeutic radiation in the X-ray wavelength range. A resilient balloon is disposed over the treatment head and configured for receiving therein a fluid to facilitate X-ray treatment of a tumor cavity. A plurality of X-ray sensing elements is disposed at a plurality of locations distributed on the interior or exterior of the resilient balloon and configured for sensing X-ray radiation emanating from the treatment head. A control system is provided that is responsive to data received from the X-ray sensing elements to determine a magnitude of X-ray radiation detected at each of the X-ray sensing elements.