Patent Application
20210353960
This invention relates generally to devices for brachytherapy. More particularly, this invention relates to devices for shielding implantable radioactive sources to achieve directional dosing, particularly at the interface between healthy and diseased tissue.
Brachytherapy is the treatment of cancer by the insertion of radioactive implants directly into the tissue near the tumor. The implants are minute radioactive pellets known as seeds. Seeds are radioactive sources covered in a biocompatible shell. The seeds may be implanted individually or inserted into a suture material which is sewn in place in tissue. Seeds, and, optionally, non-radioactive pellets known as spacers, may be lined up end-to-end in strands that are held together in a sleeve and secured by plugging the ends of the sleeve with bone wax. The loaded sleeve is then placed in a needle and inserted into the patient's tissue at the desired location. Alternatively, the seeds may be embedded into a mesh or sponge-like material, and the mesh implanted into the patient's tissue. Seeds are chosen such that they lose their radioactivity after the dose is complete so seeds that remain in the body are inert. Depending on the type of cancer and patient conditions, brachytherapy can be performed with radioactive seeds that remain in the body permanently or only temporarily.
Brachytherapy seeds come in many different isotopes, including gold-198, iridium-192, iodine-125, palladium-103 and cesium-131. Different isotopes have different radiation effects, including the intensity of the radiation, the distance it penetrates and the length of time the isotope is actively emitting radiation. The isotope is chosen for its radiation energy, intensity and half-life properties. Low dose-rate brachytherapy is a common treatment where the seeds put out a small amount of radiation over a duration of several weeks to months. High dose-rate brachytherapy procedures last only a few minutes, and commonly the radioactive material is removed at the end of the treatment session. For example, cesium-131 can deliver a high dose over a period of 30 to 45 days, maximizing dose and coverage while minimizing treatment length.
Brachytherapy is used to treat many types of cancers, including brain, head and neck, lung, breast, prostate, and gynecological cancers including cervical, ovarian, uterine, vaginal, and vulvar. Radioactive isotopes contained within the seed emit radiation in an isotropic manner, in all directions, even though the radiation-transparent shell that encases the isotopes. That means that radiation sources placed near tumors irradiate not only the tumor, but healthy tissue nearby including muscles, ligaments, and organs. For example, to treat prostate cancer with a prostate seed implant, typically all areas of the prostate are covered with seeds. That means that sensitive areas outside the prostate such as bladder, rectum, urethra and nerves run the risk of being irradiated too. The position of many tumors relative to sensitive surrounding organs requires precise delivery of the radiation to limit toxicity to the nearby organs. It would be desirable to shield healthy tissue from radiation.
It would be advantageous to have an implantable brachytherapy source that emits directional radiation to treat diseased tissue while sparing healthy tissue from radiation.
The present invention is a cradle made of radiation-shielding material which holds one or more radioactive seeds. The cradle surrounds all but a portion of the seed, and the portion of the cradle that does not surround the seeds creates an aperture through which the radiation escapes the cradle. The cradle reflects and absorbs radiation from the seed, resulting in directional dosing toward diseased tissue and away from healthy tissue. In a preferred embodiment the cradle has four walls and a bottom, forming a cavity into which the seed is secured with biocompatible epoxy. The side opposite the bottom is typically open, but may instead be made of a material that is transparent, or semi-transparent, to radiation. The cradle wall thickness, bottom thickness, and cavity height determine the direction, shape, and intensity of the radiation dispersion. Cradles may be attached to a biocompatible mesh to form a sheet with directional radiation.
As used herein, a cradle 14 is a solid mass that has a cavity 15 therein sized to accommodate one or more seeds. The cradle may have different external shapes depending on the need, such as a sphere, a hemisphere or half-round, a quarter round, an ovoid, a square box, or other shape. In a preferred embodiment, the external shape of a cradle 14 is like an open rectangular box, having four walls and a bottom, forming an internal rectangular cavity 15 into which the seed 7 is placed and secured. The side opposite the bottom is typically completely open, forming a 5-sided box. See
The cradle provides shielding, as opposed to the shielding being a part of the radiation source itself. That is, the radiation shield is the cradle in which the seed is disposed, as opposed to the shield being integral with the seed. The cradle may hold high-dose rate or low-dose rate radiation sources. The cradle does not pass through a needle. Instead, the loaded cradles are implanted into the patient. The cradles may themselves be attached to the patient's tissue or the cradles may be attached to a substrate that is attached to the patient's tissue.
Changing cradle wall or cradle bottom thickness or cradle cavity height changes the direction, shape and intensity of the radiation dispersion. For rectangular cradles, cradle wall thickness, cradle bottom thickness, and cradle cavity height determine the direction and shape of the radiation dispersion. Cradle wall thickness T is typically the same for all walls and the bottom, but certain walls or the bottom, or both, may have different thicknesses in certain applications. Cradle cavity height H is typically the same for all cavity walls, but certain walls may have different heights in certain applications.
The width of the cavity 15 inside the cradle 14 is the inside-inside width between the walls of the cradle 14, which for walls of the same thickness can be calculated as the width of the cradle 14 W minus (2×cradle 14 wall thickness T). The length of the cavity 15 is the inside-inside length of the cavity which, for walls of the same thickness, can be calculated as the length of the cradle 14 L minus (2×cradle 14 wall thickness T). The depth of the cavity 15 can be calculated as the height of the cradle 14 H minus the bottom thickness.
Table 1 is an example of the dimensions of a cradle 14 and cavity 15 formed therein, where the cradle 14 wall and bottom thickness T is 0.200 mm.
Table 2 shows the dimensions of commercially available Cs-131 seeds, available commercially from Isoray, Inc.
The cavity 15 is sized to receive the seed, and the tolerance between the seed and cavity is sized to permit easy manufacture. In one embodiment, the cavity 15 is sized to provide 0.1 mm space between the seed 7 and each wall, when the seed 7 is centered in the cavity. The cavity width and length are generally fixed, but the cradle outside dimensions vary around the fixed cavity size, given the changes to cradle wall thickness, bottom thickness and wall height desired to change the shape and direction of the emitted dose.
The cradle may take on other form factors to accommodate other seed shapes and doses, especially as such form factors are approved for use by the FDA. The cradles may be manufactured in bulk to accommodate standard seed sizes, for example by additive manufacturing, molding, casting or milling.
The cradle wall and bottom are made from biocompatible material that blocks at least the energy or energies of the treatment radiation emitted from the seed. These materials are referred to herein as radiopaque materials. For example, x-rays are blocked by radiation-shielding material such as metals including Co—Cr, Co—Cr alloys, and Au Iridium, Platinum, Tantalum, Tungsten or other suitable biocompatible material. Radiopaque materials may prevent or permit transmission of wavelengths that are different from the wavelength or wavelengths of the treatment radiation emitted from the seed. The cradle may be made of a radiopaque material that is biodegradable or radiation-degradable material and, once degraded, leaves the seeds behind. In such case the rate of degradation is chosen such that it occurs after the seed's emissions are so low as to not damage nearby tissue that was originally shielded. Materials that are conducive to constructing cradles by additive manufacturing are advantageous, including Co—Cr, Co—Cr alloys, Au—Ir, Pt, Ta, and W. Non-metal biocompatible materials may be used to make the cradle.
The walls and bottom of the cradle should be substantially inflexible, which means that while there may be a limited amount of flex in the cradle material, the cradle should stand upright with the seed in it. In a preferred embodiment, the cradle walls and bottom are rigid.
The cradle retains the seed in the cavity such that the seed is not accidentally dislocated from the cradle during shipping, implantation, or after implantation. The seed is retained in the cradle either permanently or for a period of time sufficient for the seed's radiation levels to be low enough to not damage healthy tissue. In one embodiment, biocompatible medical-grade epoxy is used to permanently attach the seed 7 to the cradle 14 in the cavity 15. Other biocompatible adhesives may be used. Alternatively or in combination with the adhesive, a cradle may be sized to permit a friction fit or snap fit between the seed and the cradle to retain the seed in the cradle.
In some embodiments a radiographic marker, such as a gold wire, dot or other structure that is visible during medical imaging may be incorporated into the cradle to increase visibility of the devices during medical imaging.
The resulting isodose lines show that for the seed in the cradle the dose is distributed asymmetrically away from the origin, with the dose distributed relatively evenly in one direction while blocked in the other. By placing the seed-loaded cradle assembly 17 with the cavity opening toward the tumor and the cradle bottom toward the healthy tissue, the cancer tissue is irradiated while the healthy tissue is spared.
To prevent migration of individual seeds and cradle combinations, the seed-loaded cradle assemblies 17 may be attached to a substrate 19, such as a biocompatible mesh or a wafer that is similar to a surgical sponge. In a preferred embodiment, the substrate 19 is bendable but resilient, so that a piece of the substrate with cradle assemblies 17 attached can be gently folded or rolled up to a smaller size for implantation and then unfurled to its original shape once placed in the body at the desired location. The biocompatible mesh may be cut to customize a shape of the mesh for implantation.
In some embodiments that mesh is radio-transparent and provides no shielding in addition to the cradle. In other embodiments, the mesh itself may provide additional shielding, under the cradles or adjacent to them or both.
The mesh is preferably a biocompatible non-resorpable metal that does not degrade when subject to radiation, such as titanium mesh which is available commercially in standard sizes. Alternatively, the mesh may be biodegradable and, once degraded, leaves the cradle-seed assemblies behind.
In one example, the substrate is a 6″×6″ bioabsorbable knitted flat mesh of Vicryl® (Polyglactin 910) prepared from the synthetic bioabsorbable copolymer 10% polylactide (PLA) and 90% polyglycolide (PGA). The mesh is compatible with ethylene oxide sterilization, non-reactive, biocompatible and is bioabsorbable within approximately 56-70 days post-implant. This mesh is available commercially.
The cradle assemblies 17 are preferably attached to the mesh by weld, sutured or biocompatible epoxy. In a preferred embodiment, the bottom of the cradle 14 is attached to the mesh so that there is shielding between the seed and the mesh and the radiation is emitted generally away from the mesh.
Alternatively, a wall of the cradle 14 is attached to the mesh so that there is shielding between the seed and the mesh and the radiation is emitted generally perpendicularly away from the mesh. In another version, the open side of the cradle 14 is attached to the mesh so that there is no shielding between the seed and the mesh and the radiation is emitted generally perpendicularly towards the mesh. Mesh may be attached to either the cancerous tissue or healthy tissue.]
Instead of using a mesh to prevent migration of individual seeds, the seed-loaded cradle assemblies 17 may instead be sutured or adhered to a patient's tissue. Individual cradles or chains of cradles may be sutured or adhered in place.
A patient is diagnosed with rectal cancer invasive to the pelvic floor. The patient's physician develops a radiation treatment plan having a prescribed dose of 60 Gy at a tissue depth of 5 mm. This is accomplished using 50 cradle assemblies. Each cradle is made of Co—Cr, with a 1.0 mm wall and bottom thickness and a cavity height of 0.48 mm. Each cradle loaded with a Cs-131 seed with an air kerma strength of 2.4 U. The cradle assemblies are attached in a 5×10 array to a 6 cm×11 cm rectangle of mesh, evenly distributed with 1 cm on-center spacing on the x-y plane. Note that the treatment is dependent on the array of cradles and independent of the size of the mesh to which they are attached, which may be trimmed to a desired size for attachment to the patient's tissue. The mesh is sutured to the patient's pelvic floor, with the therapeutic radiation directed toward the pelvic floor (down), sparing the intestines from radiation exposure.
A patient is diagnosed with retroperitoneal carcinoma. The patient's physician develops a radiation treatment plan having a prescribed dose of 60 Gy at a tissue depth of 10 mm. This is accomplished using 72 cradle assemblies. Each cradle is made of Co—Cr, with a 0.20 mm wall and bottom thickness and a cavity height of 0.52 mm. Each cradle loaded with a Cs-131 seed with an air kerma strength of 3.0 U. The cradle assemblies are attached in a 6×12 array to a 7 cm×13 cm rectangle of mesh, evenly distributed with 1 cm on-center spacing on the x-y plane. Note that the treatment is dependent on the array of cradles and independent of the size of the mesh to which they are attached, which may be trimmed to a desired size for attachment to the patient's tissue. The mesh is sutured to the patient's abdomen, with the therapeutic radiation directed toward the abdominal wall, sparing the intestines from radiation exposure.
A patient is diagnosed with ovarian cancer with pelvic floor invasion. The patient's physician develops a radiation treatment plan having a prescribed dose of 40 Gy at a tissue depth of 5 mm. This is accomplished using 64 cradle assemblies. Each cradle is made of Tantalum, with a 0.10 mm wall thickness, 0.15 mm bottom thickness, and a cavity height of 0.42 mm. Each cradle loaded with a Cs-131 seed with an air kerma strength of 1.5 U. The cradle assemblies are attached in an 8×8 array to a 9 cm×9 cm rectangle of mesh, evenly distributed with 1 cm on-center spacing on the x-y plane. Note that the treatment is dependent on the array of cradles and independent of the size of the mesh to which they are attached, which may be trimmed to a desired size for attachment to the patient's tissue. The mesh is sutured to the patient's pelvic floor, with the therapeutic radiation directed toward the pelvic floor (down), sparing the intestines from radiation exposure.
While there has been illustrated and described what is at present considered to be the preferred embodiment of the present invention, it will be understood by those skilled in the art that various changes and modifications may be made and equivalents may be substituted for elements thereof without departing from the true scope of the invention. Therefore, it is intended that this invention not be limited to the particular embodiment disclosed, but that the invention will include all embodiments and equivalents falling within the scope of the appended claims.
This application claims the benefit of co-pending U.S. Provisional Application No. 63/024,062 filed May 13, 2021.
| Number | Date | Country | |
|---|---|---|---|
| 63024062 | May 2020 | US |
