An example remote control for a radiographic source includes: a forward cable section configured to extend into and through a radiographic source housing, to expose a radiographic source to an exterior of the housing, and to retract into and through the radiographic source housing to retract the radiographic source into the radiographic housing; a drive cable section coupled to the forward cable section; and a drive gear configured to extend the forward cable section by driving the drive cable section in a first direction, and to retract the forward cable section by driving the drive cable section in a second direction, wherein the forward cable has a smooth exterior surface to have a lower friction than the drive cable section while traversing the radiographic source housing.

An example remote control for a radiographic source includes: a forward cable section configured to extend into and through a radiographic source housing, to expose a radiographic source to an exterior of the housing, and to retract into and through the radiographic source housing to retract the radiographic source into the radiographic housing; a drive cable section coupled to the forward cable section; and a drive gear configured to extend the forward cable section by driving the drive cable section in a first direction, and to retract the forward cable section by driving the drive cable section in a second direction, wherein the forward cable has a smooth exterior surface to have a lower friction than the drive cable section while traversing the radiographic source housing.

System for storing radioactive materials comprising: —a canister (4) containing radioactive waste; —a container (C), provided with a casing (1), a base (2) and a cover (3), and a passive helicoidal convection-based ventilation system provided with: lower air inlets (5); an area (6) of air circulation between the canister (4) and the inner surface of the container (C), and upper air outlets (7); the inlets (5) and outlets (7) have a decreasing variation of section in the direction of air circulation, are curved and facing an oblique direction with respect to the radial direction of the container, the air between said inlets (5) and outlets (7) describing an upward helicoidal path around the capsule or canister (4).

System for storing radioactive materials comprising: —a canister (4) containing radioactive waste; —a container (C), provided with a casing (1), a base (2) and a cover (3), and a passive helicoidal convection-based ventilation system provided with: lower air inlets (5); an area (6) of air circulation between the canister (4) and the inner surface of the container (C), and upper air outlets (7); the inlets (5) and outlets (7) have a decreasing variation of section in the direction of air circulation, are curved and facing an oblique direction with respect to the radial direction of the container, the air between said inlets (5) and outlets (7) describing an upward helicoidal path around the capsule or canister (4).

In general, radiation shielding systems that shield radiation from multiple directions are described. In one embodiment, a method of shielding radiation is provided, including supporting a shielding device on an object proximate a radiation source, positioning a first shielding portion in a vertical position relative to the object, positioning a second shielding portion to extend away from the first portion, the second shielding portion attached to the first portion, and shielding radiation from the radiation source by the first shielding portion and the second shielding portion such that the first and second shielding portions provide a radiation shielding zone for a healthcare practitioner.

A closure includes a body extending longitudinally along a central longitudinal axis from a first, upper surface to a second, lower surface. The body defines a cavity extending into the body from the lower surface to a third, interior surface. The cavity is sized and shaped to receive a portion of a container therein. The body includes a shroud extending from the interior surface to the lower surface, and a container insert depending from the interior surface and positioned within the cavity. The container insert is sized and shaped to fit within an opening of the container. The body further includes an outlet flow path in fluid communication with the cavity, and at least one inlet flow path in fluid communication with the cavity. The at least one inlet flow path is positioned and oriented to generate a vortex gas flow within the container when connected thereto.

A closure includes a body extending longitudinally along a central longitudinal axis from a first, upper surface to a second, lower surface. The body defines a cavity extending into the body from the lower surface to a third, interior surface. The cavity is sized and shaped to receive a portion of a container therein. The body includes a shroud extending from the interior surface to the lower surface, and a container insert depending from the interior surface and positioned within the cavity. The container insert is sized and shaped to fit within an opening of the container. The body further includes an outlet flow path in fluid communication with the cavity, and at least one inlet flow path in fluid communication with the cavity. The at least one inlet flow path is positioned and oriented to generate a vortex gas flow within the container when connected thereto.

A nuclear medicine infusion system (10) may be used to generate and infuse radioactive liquid into a patient undergoing a diagnostic imaging procedure. In some examples, the infusion system includes a frame (30) that carries a radioisotope generator (52) that generates radioactive eluate via elution. The frame may also carry a beta detector (58) and a gamma detector (60). The beta detector can be positioned to measure beta emissions emitted from the radioactive eluate supplied by the generator. The gamma detector can be positioned to measure gamma emissions emitted from a portion of the radioactive eluate to evaluate a safety of the radioactive eluate delivered by the infusion system.

A nuclear medicine infusion system (10) may be used to generate and infuse radioactive liquid into a patient undergoing a diagnostic imaging procedure. In some examples, the infusion system includes a frame (30) that carries a radioisotope generator (52) that generates radioactive eluate via elution. The frame may also carry a beta detector (58) and a gamma detector (60). The beta detector can be positioned to measure beta emissions emitted from the radioactive eluate supplied by the generator. The gamma detector can be positioned to measure gamma emissions emitted from a portion of the radioactive eluate to evaluate a safety of the radioactive eluate delivered by the infusion system.

Devices, systems, and methods for efficiently preparing and containing a small volume of liquid target material for irradiation by a cyclotron are provided. In various embodiments, a device includes a housing having a chamber and the housing has a top surface that is substantially flat. The chamber has a substantially flat base and a wall having a first portion extending from the base with a first radius of curvature and a second portion extending from the first portion having a second radius of curvature that is less than the first radius. The chamber also includes an inlet aperture, an outlet aperture, and a lip having a second surface that is substantially flat and recessed from the first surface. In various embodiments, the device includes a heat sink including a plurality of parallel fins disposed around the chamber.