This invention describes a system for generating multiple simultaneous tunable electron and photon beams and monochromatic x-rays for all field simultaneous radiation therapy (AFSRT), tumor specific AFSRT and screening for concealed elements worn on to the body or contained in a container. Inverse C
This invention describes a system for generating multiple simultaneous tunable electron and photon beams and monochromatic x-rays for all field simultaneous radiation therapy (AFSRT), tumor specific AFSRT and screening for concealed elements worn on to the body or contained in a container. Inverse Compton scattering renders variable energy spent electron and tunable monochromatic x-rays. It's spent electron beam is reused for radiation with electron beam or to generate photon beam. Tumor specific radiation with Auger transformation radiation is facilitated by exposing high affinity tumor bound heavy elements with external monochromatic x-rays. Heavy elements like directly iodinated steroid molecule that has high affinity binding to estrogen receptor in breast cancer and to iodinated testosterone in prostate cancer or with directly implanted nanoparticles into the tumor are exposed with tuned external monochromatic x-rays for tumor specific radiation therapy. Likewise, screening element's atom's k, l, m, n shell specific Auger transformation radiation generated by its exposure to external monochromatic x-rays is used to screen for concealed objects. Multiple beam segments from a beam storage ring or from octagonal beam lines are simultaneously switched on for simultaneous radiation with multiple beams. The beam on time to expose a tumor or an object is only a few seconds. It also facilitates breathing synchronized radiation therapy. The intensity modulated radiation therapy (IMRT) and intensity modulated screening for concealed objects (IMSFCO) is rendered by varying beam intensities of multiple simultaneous beams. The isocentric additive high dose rate from simultaneously converging multiple beams, the concomitant hyperthermia and chemotherapy and tumor specific radiation therapy and the AFSRT's very low radiation to the normal tissue all are used to treat a tumor with lower radiation dose and to treat a radioresistant and multiple times recurrent tumors that heave no other alternative treatments.
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1. A system for generating multiple simultaneous tunable mostly monochromatic x-ray beams for imaging, tumor specific radiation therapy, comparative imaging and image pixel analysis of an object exposed with multiple beams of varying energies and said system's spent electron beam generating X-ray fo
1. A system for generating multiple simultaneous tunable mostly monochromatic x-ray beams for imaging, tumor specific radiation therapy, comparative imaging and image pixel analysis of an object exposed with multiple beams of varying energies and said system's spent electron beam generating X-ray for image guided all field simultaneous radiation therapy and whole body and container imaging and said system comprising: an electron linear accelerator generating a plurality of electron beams having multiple tunable energies;a plurality of laser beams having varying wave lengths interacting with the plurality of electron beams to generate a plurality of tunable monochromatic x-rays of variable energies;a short diameter circular or octagonal beam storage ring, which stores said electron beams and said generated tunable monochromatic x-rays;a switch which simultaneously switches a duration of the generated monochromatic x-rays to picoseconds in time;the plurality of tunable monochromatic x-rays are directed towards a plurality of treatment heads;the plurality of tunable monochromatic x-rays are simultaneously irradiated from the treatment heads to an object at different angles for imaging and radiation therapy;a plurality of stationary collimated detectors, which receive the plurality of tunable monochromatic x-rays irradiated from different angles, that are attenuated by the object;imaging the object with the simultaneously attenuated monochromatic x-raysdetected by the plurality of stationary collimated detectors; and performing image pixel analysis. 2. A system for image guided all field simultaneous radiation therapy as in claim 1, where multiple simultaneous laser beams of varying wave lengths from different angels interacts with accelerated electron beam to generate inverse Compton scattering and multiple simultaneous tunable energy monochromatic x-rays. 3. A system for image guided all field simultaneous radiation therapy as in claim 1, where tunable energies multiple simultaneous photon and electron beams generated from spent electron beams of inverse Compton scattering interaction of electron and laser beams. 4. A system for image guided all field simultaneous radiation therapy as in claim 1, further consisting of tunable energies multiple simultaneous monochromatic x-rays generated from inverse Compton scattering interaction of electron and varying wavelengths laser beams. 5. A system for image guided all field simultaneous radiation therapy as in claim 1, where tunable energies multiple simultaneous monochromatic x-rays generated from inverse Compton scattering interaction of laser beams and varying energy electron beams. 6. A system for generating multiple simultaneous tunable monochromatic x-rays as in claim 1, where a plurality of segments of electron beam and its collilinear monochromatic x-ray beam are steered within a common circular beam storage ring equipped with bending and collimating magnets, electron beam segment deflecting magnets for simultaneous switching of collilinear electron and x-ray beam segments from the beam storage ring into separate beam line pipes leading to therapy unit's treatment heads and to imaging x-ray unit's heads for image guided all filed simultaneous radiation therapy and imaging. 7. A system for generating multiple simultaneous tunable monochromatic x-rays as in claim 6, wherein tumor specific radiation therapy and screening for concealed elements worn on to the body or contained in a container is with spent electron beam or photon generated from spent electron beam or with monochromatic x-ray tuned to tissue bound element's atom specific k, l, m, n shell binding energies and its Auger transformation radiation. 8. A system for generating multiple simultaneous tunable monochromatic x-rays for imaging and tumor specific radiation therapy as in claim 7, where an external monochromatic x-ray beam is tuned to the k-shell electron binding energy of a tumor seeking element's atom or a nano particle element that is implanted into the tumor to generate locally propagating characteristic photon and Auger electrons radiation that is confined within the tumor for tumor specific radiation therapy. 9. A system for generating multiple simultaneous tunable monochromatic x-rays for imaging and tumor specific radiation therapy as in claim 8, where an external monochromatic x-ray beam is tuned to 33.2 keV to elicit iodine specific characteristic photon and Auger electrons from iodinated steroid molecules that is bound to steroid receptors of the cell like estrogen receptor bound iodinated estrogen in breast cancer and testosterone receptor bound iodinated testosterone in prostate cancer. 10. A system for generating multiple simultaneous tunable monochromatic x-rays for imaging and tumor specific radiation therapy as in claim 7, further consisting of external monochromatic x-ray beam tuned to 10 to 200 keV for imaging with mostly monochromatic x-rays to minimize increased incidence of cancer from radiological examinations with polychromatic bremsstrahlung x-rays like those with computerized tomography. 11. A system for image guided all field simultaneous radiation therapy and detection of canceled objects as in claim 1, further consisting of imaging with multiple simultaneous monochromatic x-ray computerized tomography is by simultaneous switching of picoseconds duration beamlets from a beam storage ring. 12. A system for generating multiple simultaneous tunable monochromatic x-rays as in claim 1, further consisting of multiple simultaneous beams' additive high dose rate radiation therapy, imaging and detection of concealed elements in a person or in a container with inverse Compton scattering x-rays. 13. A system for generating multiple simultaneous tunable monochromatic x-rays as in claim 1, where spent electron beam of inverse Compton interaction with electron and laser switched into two beams and steered through two octagonal beam lines and to multiple treatment heads and their beams converging at the isocenter simultaneously with isocentric additive high dose rate ranging from 1,000 to 4,000 cGy per minute for high dose rate radiation therapy with lesser toxicity to normal tissue. 14. A system for generating multiple simultaneous tunable photon beams by reusing the spent electron beam of inverse Compton scattering electron-laser interaction as in claim 13, further consisting of imaging and tumor specific intensity modulated radiation therapy with varying beam intensities of each converging beams at the isocenter. 15. A system for isocentric high additive dose rate radiation therapy as in claim 13, further consisting of lesser normal tissue toxic radiation therapy combined with hyperthermia and chemotherapy to treat cancerous tumors including radioresistant and multiple times recurrent tumors that are otherwise untreatable with conventional radiation therapy. 16. A system for generating multiple simultaneous tunable monochromatic x-rays as in claim 1, where simultaneous X-ray beam generated in multiple treatment heads arranged in a circle to treat a patient with multiple simultaneous beams and for imaging combined with pixel analysis with their attenuated beam passing through image processing detectors. 17. An image processing system as in claim 16, where attenuated photon exposing the parallel opposed collimated detectors placed proximally to treatment heads. 18. A system for generating multiple simultaneous tunable photon and electron beams as in claim 1, where radiation therapy is administered with high energy multiple simultaneous electron beams with their additive high dose and dose rate at the isocenter. 19. A system for generating multiple simultaneous tunable photon and electron beams as in claim 18, further consisting of radiation therapy with electron beam segments and imaging with its tail end photon beam exiting at its opposite side and reaching the opposing stationary detectors placed proximal to treatment heads in a circle and exposing said collimated detectors with said exiting photon beams for image processing.
Carroll, Frank E.; Traeger, Robert H.; Mendenhall, Marcus H.; Waters, James W.; Edwards, Glenn; Brau, Charles A., System and method for producing pulsed monochromatic X-rays.
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Suh, K. Stephen; Sarojini, Sreeja; Tuna, Mehmet; Barbiere, Joseph; Ndlovu, Alois M.; Pecora, Andrew L.; Ingenito, Anthony, Method for treating skin cancer using radiation therapy.
Bharadwaj, Vinod; Dolgashev, Valery A.; Fahrig, Rebecca; Loo, Billy Wiseman; Maxim, Peter G.; Tantawi, Sami; Limborg, Cecile; Nicolas, Ludovic, Methods and systems for beam intensity-modulation to facilitate rapid radiation therapies.
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