A particle beam treatment apparatus includes an irradiator that has an irradiation nozzle which irradiates an irradiation target with a particle beam and that is capable of moving rotationally in a vicinity of the irradiation target, a moving floor that extends on an annular trajectory surrounding the irradiation target along a rotation circumferential direction of the irradiator and that is movable on the annular trajectory depending on a position of the irradiator, a movable cover that is supported pivotably with respect to the irradiator or the moving floor and that covers a gap between the irradiator and the moving floor, and an adjusting mechanism that adjusts a pivoting position of the movable cover depending on the position of the irradiator such that a gap between the movable cover and the moving floor is covered.

A tissue displacement/separation device includes a seamless bladder constructed of a biodegradable polymer. The bladder is expandable from a collapsed or rolled state for insertion into a body between a first and second tissue to an expanded state for separating the first and second tissue.

A radiation treatment device is provided. The device includes an imaging unit and a single radiotherapy unit adjacent to a second end of the imaging unit. The imaging unit includes a first opening at a first end of the imaging unit adapted to receive a patient; at least one imaging source; and at least one imager arranged opposite the imaging source. The imaging source and the imager are rotatable about the rotational axis. The radiotherapy unit includes a source body carrying radioactive sources and a collimator having collimation channels. The collimation channels permit treatment beams emitted by the radioactive sources to be projected inside the imaging unit and focused at an intersection point located within an imaging beam of the imaging unit. The source body and the collimator are arranged concentric about the rotational axis and close a second opening at the second end.

A radiotherapy device and a control driving method thereof are provided. The radiotherapy device includes a radiation source apparatus having a plurality of radiation sources, a source carrier and a collimator. The source carrier includes a source box and a source box region conforming to a shape of the source box, the source box is detachably fixed at the source box region, the plurality of radiation sources are mounted in the source box, the source box is provided with a first connecting part, the source carrier is provided with a second connecting part, and the first connecting part is configured to connect the second connecting part.

Described are means for the direct and continuous connection of a catheter to the lumen of any tubular anatomical structure, or ductus, without medically significant leakage. A port implanted at the body surface with piping to a periductal collar allows drug or radionuclide delivery that bypasses the upstream lumen. The port allows injection, infusion, aspiration, or attachment of an automatic ambulatory pump. A superparamagnetic nanoparticle carrier-bound drug, for example, can be introduced into the lumen to pass downstream until the particles, with or without the drug still bound, are drawn into the lumen wall by a magnetized jacket surrounding the ductus. Such constitutes a method of drug targeting whereby a segment of a vessel or the territory supplied by a branch of that segment can be circumscribed for exposure to the drug. A jacket with side-entry connector positioned in surrounding relation to a lesion requiring treatment can itself be magnetized.

An apparatus for suspending one or more items is disclosed. The apparatus includes a vertical back plate, a vertical front plate, and a connector plate for connecting the vertical front plate to the vertical back plate. The apparatus further comprises an angulated base member attached to the vertical front plate at an obtuse angle. An arched hanging member for receiving one or more articles to be hanged is provided on the apparatus, the arched hanging member comprising a rounded ball end to avoid tears and perforations to the one or more suspended items.

Controlling unit for a radiation source includes a mains-driven power supply terminal connectable to a mains-driven power supply, a battery-driven power supply terminal connectable to a battery-driven power supply, a failsafe power supply terminal, a processor unit to control the radiation source, and a patient-in-place sensor unit to provide a respective signal to the processor unit. The failsafe power supply terminal is connected to the mains-driven power supply terminal via a first diode and to the battery-driven power supply terminal via a second diode and he processor unit is connected to the failsafe power supply terminal to receive power from the higher voltage power supply terminal of the mains-driven power supply terminal and the battery-driven power supply terminal, respectively. The processor unit is adapted to shut down the radiation source in case a patient-not-in-place signal is provided.

Methods and systems are described for a rotating shield brachytherapy device. As disclosed herein, the rotating shield brachytherapy (RSBT) apparatus may comprise a radiation source, a drive assembly, a catheter, and an applicator. The applicator can have an outer surface and opposed proximal and distal end portions and a longitudinal axis extending along a length of the catheter. The distal end portion of the catheter can comprise one or more radiation shields and is configured to receive the radiation source. The drive assembly can be configured to engage the proximal end portion of the catheter to selectively rotate the catheter about the longitudinal axis.

An IORT device (10) for radiotherapy treatment of cancer patients, comprising a source of particles, an accelerating device (11), which sends a beam of particles (12) on a target (14) through an applicator (15), a scattering filter (16), which allows the distance between the source of particles and the target (14) to be kept within a range compatible with the use of IORT devices (10) in standard operating rooms, and an optical system for collimating the beam of particles (12), which is placed between the scattering filter (16) and the applicator (15); specifically, the optical collimating system of the beam of particles comprises a primary screen (17), configured to shield the radiation produced by the scattering filter (16), a secondary screen (18), configured to shield the photons produced on the primary screen (17), and a collimating apparatus (19), which provides for housing the monitor chambers (20).

Systems and methods for the delivery of linear accelerator radiotherapy in conjunction with magnetic resonance imaging in which components of a linear accelerator may be placed in shielding containers around a gantry, may be connected with RF waveguides, and may employ various systems and methods for magnetic and radio frequency shielding.