An afterloading device for effectuating a brachytherapy treatment, comprising a first elongated flexible transport element, arranged to maneuver a radiation source between a storage position inside the afterloading device and a treatment position outside the afterloading device, the afterloading device further comprising a second elongated flexible transport element, having at least one transducer, the second transport element being arranged to move the at least one transducer between a first transducer position and a second transducer position.

Interstitial brachytherapy is a cancer treatment in which radioactive material is placed directly in the target tissue of the affected site using an afterloader. The accuracy of radiation placement is monitored during the cancer treatment. The location plan for the radioactive material may be adjusted during the cancer treatment based on real-time analysis of the location and dosage of radiation measured in, at and around the target tissue of the affected site.

Embodiments of the disclosure may be drawn to brachytherapy applicators. Exemplary applicators may include an interstitial tube having a body with a proximal end and a distal end and a central conduit extending from the distal end of the body, wherein the central conduit includes a proximal opening, a distal opening, and a channel extending from the proximal opening to the distal opening, and wherein the proximal opening is offset from an axis of the body. The proximal opening may be configured to fluidly connect to a brachytherapy guide tube, and the channel of the central conduit may be dimensioned to receive at least one of a needle or a catheter therethrough.

A delivery system and method for radiation shielded brachytherapy has a drive assembly, and a plurality of shield assemblies, pivotally mounted to the drive assembly, each having a tubular body defining an outer surface and a bore longitudinally extending between opposite ends of the tubular body. Each of the shield assemblies has radiation shielding material extending about a circumferential portion of the tubular body and disposed between the outer surface and the cavity. An interlocking system is operatively mounted to the rotating assembly, and engages a group of the plurality of shield assemblies. The interlocking system is configured for transmitting a rotational input received from a driving mechanism to the group of shield assemblies, for synchronously rotating each shield assembly of the group about their respective longitudinal axis.

A brachytherapy afterloader device, comprises at least one transmit wire that is suitable for being inserted and driven in an advance or retract motion in an external first delivery channel and for delivering drive energy to a test field source, which is arranged at a distal end region of the transmit wire, for generating a magnetic test field; at least one receive wire that is suitable for being inserted and driven in an advance or retract motion in an external second delivery channel for a measurement of the magnetic test field, the receive wire having a transducer that is configured to detect magnetic-field changes in the magnetic test field; and a wire driving unit which is configured to controllably advance or retract the transmit wire and the receive wire in response to a corresponding test drive control signal.

Misconnected applicators are eliminated in a brachytherapy treatment system by associating the output channels of an afterloader with the channel numbers after the applicators have been coupled to the output channels. In addition, the brachytherapy treatment system ensures the delivery of a proper dose by identifying the exact locations of the distal ends of the applicators right before the radiation treatment is to begin, and determining the final dose based on the exact locations.

A method and apparatus for marking a target with a radiopaque marker is disclosed. The method may include providing a radiopaque filament and inserting at least portion of the radiopaque filament into tissue. The filament may extend continuously and at last partially around a perimeter of the target so that the filament is disposed in a plurality of surgical planes to demarcate the target with the radiopaque maker.

A method and apparatus for marking a target with a radiopaque marker is disclosed. The method may include providing a radiopaque filament and inserting at least portion of the radiopaque filament into tissue. The filament may extend continuously and at last partially around a perimeter of the target so that the filament is disposed in a plurality of surgical planes to demarcate the target with the radiopaque maker.

A method and apparatus for marking a target with a radiopaque marker is disclosed. The method may include providing a radiopaque filament and inserting at least portion of the radiopaque filament into tissue. The filament may extend continuously and at last partially around a perimeter of the target so that the filament is disposed in a plurality of surgical planes to demarcate the target with the radiopaque maker.

A sensing apparatus for sensing the presence of a radioactive source, or check- dummy- or sensor cable, at a point along mg the sensing apparatus during a brachytherapy procedure. The sensing apparatus comprises a transfer tube comprising a first end and IC a second end. The second end being downstream of the first end. The sensing apparatus further comprises sensing means operable to detect the presence of a radioactive source, or check- dummy- or sensor cable, at a point downstream of the first end of the transfer tube. The reason for the plurality of “prisms” or the semispheres, is that they are orientation independent to the light fibers, simplifying assembly. Alternatively the plurality of prisms may be substituted by two half-spherical “prisms”. Between the prisms, a light blocking surface need to be placed to avoid optical short circuits.