The present invention includes new medical techniques involving radiation and electromagnetic actuation of reagents deployed and directed within bodily fluids (e.g., the bloodstream, digestive tract, or lymph ducts) of a patient. In one aspect of the invention, a medical reagent and/or particle is provided with multiple dipoles, oriented differently in three-dimensional space, allowing a remote control system to drive the acceleration and three-dimensional orientation of the medical agent or particle according to a three-dimensional path. In some embodiments, the medical reagent and/or particle is energized remotely to an activation energy level, and then driven into the treatment target. The design of each small-scale machine may include different sub-devices and electrostatic charges or magnetic dipoles, at different surface or internal locations. In some aspects, the sub-devices include actuable housings and other sub-devices, to deliver drugs or other factors at specific locations commanded by the control system or a user.

A polymeric radiation-source with customized geometries to maximize receipt of radiation into treatment areas that is formed from either radioisotopes molecularly bonded to a polymer or radioisotopes encased within a polymer.

An X-ray system is described with a scatter radiation shielding device to be mounted underneath an operating table. The shielding device (10) comprises one or more layers of a radiation blocking material (6) and a cut-out (8) in the one or more layers. The cut-out extends from a point in or near a center of the one or more layers towards an edge to allow radiation transmission to pass. The shielding device is rotatable around a rotation axis. The shielding device substantially reduces the scatter radiation originating from the patient.

The disclosure pertains to a strontium-90 sealed radiological or radioactive source, such as may be used with treatment of the eye or other medical or industrial processes. The sealed radiological source includes a radiological insert within an encapsulation. The encapsulation may include increased shielding in the center thereof.

A radiation shield assembly is described, configured to block radiation emanating from a radiation source from reaching a user. Two shields are supported by a support arm, and are configured to rotate and translate relative to one another about the support arm's longitudinal axis. This allows the shield to be easily configured and reconfigured as necessary to visualize various parts of a patient's body via radiography. The assembly is articulated to overcome difficulties in maneuvering it around an operating room. Such articulation may come in the form of a dual-sleeve configuration for jointing the shield, in the form of adjustable wheels on the floor sand, or both.

Disclosed is a moderator for moderating neutrons, including a substrate and a surface treatment layer or a dry inert gas layer or a vacuum layer coated on the surface of the substrate, wherein the substrate is prepared from a moderating material by a powder sintering device through a powder sintering process from powders or by compacting powders into a block, and the moderating material includes 40% to 100% by weight of aluminum fluoride; wherein the surface treatment layer is a hydrophobic material; and the surface treatment layer or the dry inert gas layer or the vacuum layer is used for isolating the substrate from the water in the environment in which the substrate is placed. The surface treated moderator can avoid the hygroscopic or deliquescence of the moderating material during use, improve the quality of the neutron source and prolong the service life.

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.

Systems and methods for providing a real time visualization of scattered radiation in a medical facility are provided. A number of visualization devices such as augmented reality (“AR”) tracking devices, electronic displays, or projection devices are in electronic communication with a controller and configured to display a visualization of scattered radiation. Position data is received from the position sensors associated with individuals in the medical facility, the AR tracking devices, radiation producing medical equipment, or radiation scattering medical equipment, and the visualization is adjusted accordingly.

Systems and devices for applying radiation to a target area, for example for maintaining functioning drainage blebs or functioning drainage holes in the eye, e.g., to reduce intraocular pressure (IOP) of an eye being treated for glaucoma. The systems and devices of the present invention provide for the application of beta radiation to the target area, wherein the beta radiation can function to inhibit or reduce the inflammation and/or fibrogenesis that may occur after insertion of an implant into the eye or introduction of a hole for the purpose of draining aqueous humor to maintain a healthy intraocular pressure. By reducing inflammation and/or fibrogenesis, the implant, the hole, the blebs, or other related structures or tissues can remain functioning appropriately.

A method for creating or evaluating a radiation shield for a radiation therapy treatment can include receiving, using one or more computing devices, three-dimensional (3D) imaging data, generating, using the one or more computing devices, a 3D volume of a portion of patient from the 3D imaging data, determining, using the one or more computing devices, a region of interest for receiving radiation therapy for the 3D volume of the portion of the patient, generating, using the one or more computing devices, a 3D model of a radiation shield from the 3D volume of the portion of the patient and the region of interest, the 3D model having an inner surface that contours an exterior surface of the 3D volume, and causing, using the one or more computing devices, a 3D printer to construct a radiation shield from the 3D model of the radiation shield.