Provided herein is a dosimetry device for quantifying the dosage of radiation emitted from a radiation source, the device comprising: (i) a radiation dose indicator; (ii) an optical means to capture the color change; and (iii) a software means to compare the optical density of the dose indicator as compared to a predetermined calibration curve. Also provided herein is a method of quantifying the dosage of radiation emitted from the radiation source. Further provided herein is use of said dosimetry device in various medical, food and industrial applications.

This present disclosure provides a multi-ply radiation dosage indicator, which includes a first ply having two visible readable indicia thereon. The dual radiation sensitive zones are capable of changing opacity in response to exposure radiation. Each radiation sensitive zone can respond to an irradiation dose in tandem or independent of one another. Once the radiation sensitive zone exceeds the design exposure threshold, the visibility of the indicia is altered thereby providing an indication of irradiation exposure. The radiation sensitive zone may either be transparent or opaque and can change its opacity in response to exposure to radiation exceeding a predetermined threshold so as to change the visibility of the indicia.

Provided are methods of determining prior radiation dose exposure levels for subjects, and kits therefor. Also provided are methods of treatment.

Provided are methods of determining prior radiation dose exposure levels for subjects, and kits therefor. Also provided are methods of treatment.

Disclosed is a device for measuring radiation doses absorbed by a gel dosimeter, including in particular a polarizer for a light beam according to at least two distinct polarization angles, the polarizer being positioned between a light source and an optical detector, a unit for measuring the value of the intensity of the light beam, which intensity is measured by the optical detector, and a unit for calculating the value of a ratio of intensities of the light beam, which intensities are measured by the optical detector, for two distinct polarization angles of the light beam that is selected by the polarizer.

Disclosed is a device for measuring radiation doses absorbed by a gel dosimeter, including in particular a polarizer for a light beam according to at least two distinct polarization angles, the polarizer being positioned between a light source and an optical detector, a unit for measuring the value of the intensity of the light beam, which intensity is measured by the optical detector, and a unit for calculating the value of a ratio of intensities of the light beam, which intensities are measured by the optical detector, for two distinct polarization angles of the light beam that is selected by the polarizer.

Radiotherapy quality assurance (QA) systems and methods are provided that incorporate a shared frame of reference between a treatment plan and a measured dose distribution that allows for 3D dosimetry measurements. An on-board imaging system may provide a shared frame of reference with the radiotherapy treatment system. A dosimeter is also provided for use with the QA systems and methods. The QA systems and methods can be applied as an end-to-end test to evaluate specific parameters of a radiation therapy treatment system, such as an external beam radiotherapy system, including spatial accuracy, isocenter verification and dosimetric accuracy.

Compositions including additive manufacturing materials incorporating radiological detection materials therein are provided. Also provided are apparatus and methods, which may be utilized to monitor and measure nuclear criticality events, and determine if personnel have been exposed to ionizing radiation. The compositions, apparatus, and methods beneficially improve accuracy in assessing radiation exposure, particularly neutron exposure, and reduce degradation of the radiological detection materials.

Apparatuses (devices, systems) and methods for shielding (protecting) surroundings around periphery of regions of interest located inside objects (e.g., patients) from radiation emitted by X-ray systems towards the objects. Apparatus includes: at least one radiation shield assembly including a support base connectable to an X-ray system radiation source or detector, and a plurality of radiation shield segments sequentially positioned relative to the support base, thereby forming a contiguous radiopaque screen configured for spanning around the region of interest periphery with a radiopaque screen edge opposing the object. Radiation shield segments are individually, actively controllable to extend or contract to selected lengths with respective free ends in directions away from or towards the support base(s), for locally changing contour of the radiopaque screen edge. Applicable for shielding (protecting) medical personnel, and patients, from exposure to X-ray radiation during medical interventions or/and diagnostics.

Apparatuses (devices, systems) and methods for shielding (protecting) surroundings around periphery of regions of interest located inside objects (e.g., patients) from radiation emitted by X-ray systems towards the objects. Apparatus includes: at least one radiation shield assembly including a support base connectable to an X-ray system radiation source or detector, and a plurality of radiation shield segments sequentially positioned relative to the support base, thereby forming a contiguous radiopaque screen configured for spanning around the region of interest periphery with a radiopaque screen edge opposing the object. Radiation shield segments are individually, actively controllable to extend or contract to selected lengths with respective free ends in directions away from or towards the support base(s), for locally changing contour of the radiopaque screen edge. Applicable for shielding (protecting) medical personnel, and patients, from exposure to X-ray radiation during medical interventions or/and diagnostics.