The invention provides a method for locating radioactive material implanted in a living body, the method having the steps of implanting a stent into the body, the stent containing the radioactive material; imaging the body to determine a first position of the stent relative to remote points on the body; determining a second position of the stent at a second time later than the time of the implanting step; and measuring the distance between said first position and said second position. Also provided is a system for determining movement of a radiation source implanted in a living body, the device having a radiographic film overlaying a region of the body so as to oppose the radiation source, whereby the film is positioned relative to a reference point on the body; a grid disposed between the film and the body; and a radio-opaque substrate overlaying the film.

Methods, systems, and compositions for maintaining functioning drainage blebs to reduce intraocular pressure (IOP) of an eye being treated for glaucoma. The methods, systems, and compositions feature the combination of a minimally invasive glaucoma surgery (MIGS) implant or procedure and the application of beta radiation to the bleb. The beta radiation can function to inhibit or reduce the inflammation and/or fibrogenesis that typically occurs after insertion of a MIGS implant and leads to bleb failure. By reducing inflammation and/or fibrogenesis, the MIGS implant and the blebs can remain functioning appropriately.

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.

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.

Methods, systems, and compositions for maintaining functioning drainage blebs to reduce intraocular pressure (IOP) of an eye being treated for glaucoma. The methods, systems, and compositions feature the combination of a minimally invasive micro sclerostomy (MIMS) procedure and the application of beta radiation to a target area. The beta radiation can function to inhibit or reduce the inflammation and/or fibrogenesis that typically occurs after a MIMS procedure and leads to hole and/or bleb failure. By reducing inflammation and/or fibrogenesis, the MIMS holes and/or blebs can remain functioning appropriately.

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.

The invention provides a method for locating radioactive material implanted in a living body, the method having the steps of implanting a stent into the body, the stent containing the radioactive material; imaging the body to determine a first position of the stent relative to remote points on the body; determining a second position of the stent at a second time later than the time of the implanting step; and measuring the distance between said first position and said second position. Also provided is a system for determining movement of a radiation source implanted in a living body, the device having a radiographic film overlaying a region of the body so as to oppose the radiation source, whereby the film is positioned relative to a reference point on the body; a grid disposed between the film and the body; and a radio-opaque substrate overlaying the film.

The present invention provides a means for achieving greater ability to negotiate small radii like 5 mm of curvature in the human body to treat tumors, for example, with radioactive materials. This is accomplished by incorporating the source capsule into a flexible housing, which, in its simplest configuration, eliminates the direct connection of the source capsule to the driving cable, adding a degree of flexibility that is not available with a direct connection of the source capsule to the driving cable as in the presently available source capsules, and further providing segmented source capsules, and further providing devices for shielding of tissue using the segmented source assemblies.

Methods, systems, and compositions for maintaining functioning drainage blebs to reduce intraocular pressure (IOP) of an eye being treated for glaucoma. The methods, systems, and compositions feature the combination of a minimally invasive glaucoma surgery (MIGS) implant or procedure and the application of beta radiation to the bleb. The beta radiation can function to inhibit or reduce the inflammation and/or fibrogenesis that typically occurs after insertion of a MIGS implant and leads to bleb failure. By reducing inflammation and/or fibrogenesis, the MIGS implant and the blebs can remain functioning appropriately.

Provided herein is technology relating to analysis of images and particularly, but not exclusively, to methods and systems for determining the area and/or volume of a region of interest using optical coherence tomography data. Some embodiments provide for determining the area and/or volume of a lesion in retinal tissue using three-dimensional optical coherence tomography data and a two-dimensional optical coherence tomography fundus image.