Patent Number: 
Section: claims

1. A flexible, thin and lightweight radiation absorbing shield to be worn against a patient's body to protect against radiation emitted internally in the patient during internal radiation therapy within the patient's body, comprising:a matrix of flexible material which defines at least two radiation attenuating layers, a first, patient-adjacent layer at a side of the radiation shield intended to be placed against the patient and carrying absorber particles of mid atomic number, and an adjacent layer carrying radiation absorber particles of high atomic number, positioned to be more remote from the patient than the first layer;said attenuating layers being configured to protect the patient's skin by blocking internally emitted radiation backscattered from the layer carrying the high atomic number particles. 2. The radiation shield of claim 1, wherein the total thickness of the shield is not greater than about 2 mm. 3. The radiation shield of claim 1, wherein the flexible matrix comprises silicone. 4. The radiation shield of claim 3, wherein the silicone content of the matrix is in the range of about 5 to 75 percent. 5. The radiation shield of claim 1, wherein the high atomic number absorber particles comprise tungsten metal, and wherein the mid atomic number absorber particles comprise, alone or in combination, iron, nickel, cobalt or compounds thereof. 6. The radiation shield of claim 5, wherein the mid atomic number absorber particles include iron oxide. 7. The radiation shield of claim 1, wherein the absorber particles are of a size between about 35 and about 150 microns in diameter. 8. The radiation shield of claim 1, wherein the first layer having the mid atomic number absorber particles is less than about 5 mils thick. 9. The radiation shield of claim 1, wherein the matrix material comprises wax, providing a moldable shield material. 10. The radiation shield of claim 1, wherein the radiation shield absorbs more than fifty percent of x-ray radiation at about 50 kVp. 11. The radiation shield of claim 1, wherein the high atomic number radiation absorber particles are nonuniformly distributed in said adjacent layer, creating an absorber with regions of greater and lesser radiation absorption, for specialized applications. 12. The radiation shield of claim 1, wherein the matrix is stretchable more than 200% with return to an original shape. 13. The radiation shield of claim 12, further including a cover sheet against the first layer, the cover sheet being of stretchable fabric. 14. The radiation shield of claim 13, wherein the shield is washable without damage. 15. The radiation shield of claim 1, further including at least one dosimeter incorporated into the first layer near the patient side of the shield, with lead wires extending from the dosimeter to the exterior of the shield. 16. The radiation shield of claim 15, further including visible marking on an exterior surface of the shield, indicating positions of dosimeters and lead wires. 17. The radiation shield of claim 1, further including at least one dosimeter incorporated into the first layer near the patient side of the shield, and including shielding of the dosimeter against radiation backscattered from the radiation absorbing shield. 18. The radiation shield of claim 1, wherein the first layer contains said absorber particles of mid atomic number in such density as to pass most x-ray radiation at 50 kVp through to the adjacent, more remote layer, and in such density as to absorb substantially all x-ray radiation backscattered off the adjacent more remote layer and back into the first layer. 19. A method for protecting a patient's skin from radiation emitted internally in the patient during internal radiation therapy within the patient's body, comprising:placing against the patient a flexible, thin and lightweight radiation absorbing shield, the shield comprising a matrix of flexible material which defines at least two radiation attenuating layers, a first, patient-adjacent layer at a side of the radiation shield placed against the patient and carrying absorber particles of mid atomic number, and an adjacent layer carrying radiation absorber particles of high atomic number, positioned more remote from the patient than the first layer, andirradiating the patient internally with x-ray radiation, causing some of the radiation to penetrate out through the patient's skin and, with the radiation shield, absorbing most high energy radiation with the layer having high atomic number radiation absorber particles but causing some backscatter of low-energy radiation back toward the patient and into the mid atomic number layer, where the low-energy radiation is absorbed, thus protecting the patient's skin against backscatter radiation. 20. The method of claim 19, wherein the first layer contains said absorber particles of mid atomic number in such density as to pass most x-ray radiation at 50 kVp through to the adjacent, more remote layer, and in such density as to absorb substantially all x-ray radiation backscattered off the adjacent more remote layer and back into the first layer. 21. The method of claim 19, wherein the radiation shield absorbs more than fifty percent of x-ray radiation at about 50 kVp. 22. The method of claim 19, wherein the total thickness of the shield is not greater than about 2 mm. 23. The radiation shield of claim 1 wherein the high atomic number absorber particles comprise tungsten metal, wherein the mid atomic number absorber particles comprise, alone or in combination, iron, nickel, cobalt or compounds thereof, wherein each layer of the matrix comprises a like polymer material, and wherein the percentage of absorber particles is greater in the adjacent layer than in the first patient-adjacent layer. 24. The radiation shield of claim 23 wherein the percentage of absorber particles in the more remote adjacent layer is on the order of ninety percent with the remainder being the polymer material. 25. The radiation shield of claim 23 wherein the percentage of absorber particles in the patient-adjacent layer is on the order of fifty percent with the remainder being the polymer material. 26. The radiation shield of claim 1 wherein a small percentage of the radiation striking the layer carrying high atomic number particles is backscattered back toward the patient, and nearly all of this backscattered radiation is absorbed as it travels back through the layer carrying mid atomic number particles to the patient.