US2014054453A1PendingUtilityA1

Radiation beam analyzer and method

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Assignee: NAVARRO DANIELPriority: Dec 3, 2008Filed: Nov 4, 2013Published: Feb 27, 2014
Est. expiryDec 3, 2028(~2.4 yrs left)· nominal 20-yr term from priority
Inventors:Daniel Navarro
G01T 1/02G01T 1/24A61N 5/1075G01T 1/185A61B 6/022G01T 1/169A61N 5/1084A61N 2005/1076
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Claims

Abstract

A radiation beam analyzer for measuring the distribution and intensity of radiation produced by a Cyberknife®. The analyzer employs a relative small tank of water into which a sensor is placed to maintain a constant SAD (source to axis distance). A first method maintains a fixed position of detector, and raises or lowers the small tank of water. A second method moves the detector up, down or rotationally synchronously in opposite directions with respect to the small tank of water to keep the SAD constant. These methods position the detector relative to the radiation source to simulate the location of a malady within a patient's body. An embodiment of the present invention enables measurements of substantially larger fields. This is accomplished by rotating a tank of water 90 degrees from a first position to a second position.

Claims

exact text as granted — not AI-modified
What is claimed is: 
     
         1 . A radiation beam analyzer for detecting radiation dosimetry of a beam emitted along an axis from a radiotherapy treatment device comprising:
 a phantom body formed of a material having a density proximate that of a human body;   a tank containing said phantom body;   at least one dosimetry probe constructed and arranged to sense photons and electrons, said at least one dosimetry probe positioned within said dynamic phantom body;   a plurality of rails secured to said tank and said dynamic phantom body;   a rotary table, said tank and said plurality of rails and said second plurality of rails being positioned on said rotary table; and   a plurality of mechanisms incrementally moving said tank and said dynamic phantom body in a substantially vertical, radial, transverse or diagonal direction relative to a radiation source;   the distance between said radiation source and the axis of a beam emitted from said radiation source relative to said at least one dosimetry probe being constant;   whereby movement of said tank and said phantom body through a series of locations is carried out so as to provide sufficient data to determine the proper dose of radiation required for radiotherapeutics.   
     
     
         2 . The radiation beam analyzer of  claim 1  wherein said dosimetry probe is an ion chamber. 
     
     
         3 . The radiation beam analyzer of  claim 1  wherein said radiation beam analyzer directly measures radiation from isocentric beams in a field of approximately 0.4 cm to 40 cm. 
     
     
         4 . The radiation beam analyzer of  claim 1  wherein said movement is isocentric. 
     
     
         5 . The radiation beam analyzer of  claim 1  wherein said radiotherapy treatment device is a linear accelerator. 
     
     
         6 . The radiation beam analyzer of  claim 1  wherein said dosimetry probe is at least one diode. 
     
     
         7 . The radiation beam analyzer of  claim 1  wherein said rotary table includes a motor and a gear train, said motor and said gear train constructed and arranged to provide rotation about an axis upon operation of said motor. 
     
     
         8 . The radiation beam analyzer of  claim 7  wherein said rotary table is a treatment table. 
     
     
         9 . A radiation beam analyzer for detecting radiation dosimetry of a beam emitted along an axis from a radiotherapy treatment device comprising:
 a phantom body formed of a material having a density proximate that of a human body;   a tank containing said phantom body;   at least one dosimetry probe constructed and arranged to sense photons and electrons, said at least one dosimentry probe positioned within said dynamic phantom body;   a plurality of rails secured to said tank and said dynamic phantom body;   a rotary table, said tank, and said plurality of rails being positioned on said rotary table;   a plurality of mechanisms incrementally moving said tank and said phantom body in a substantially vertical, radial, transverse or diagonal direction relative to a radiation source; and   a controller connected to and operating said plurality of mechanisms to move both said tank and said at least one dosimetry probe to maintain the distance between said radiation source and the axis of a beam emitted from said radiation source relative to said at least one dosimetry probe constant;   whereby movement of said phantom body and said at least one dosimetry probe through a series of locations is carried out so as to provide sufficient data to determine the proper dose of radiation required for radiotherapy treatment.   
     
     
         10 . The radiation beam analyzer of  claim 9  wherein said dosimetry probe is an ion chamber. 
     
     
         11 . The radiation beam analyzer of  claim 9  wherein said radiation beam analyzer directly measures radiation from isocentric beams in a field of approximately 0.4 cm to 40 cm. 
     
     
         12 . The radiation beam analyzer of  claim 9  wherein said movement is isocentric. 
     
     
         13 . The radiation beam analyzer of  claim 9  wherein said radiotherapy treatment device is a linear accelerator. 
     
     
         14 . The radiation beam analyzer of  claim 9  wherein said dosimetry probe is at least one diode. 
     
     
         15 . The radiation beam analyzer of  claim 9  wherein said rotary table includes a motor and a gear train, said motor and said gear train constructed and arranged to provide rotation about an axis upon operation of said motor. 
     
     
         16 . The radiation beam analyzer of  claim 15  wherein said rotary table is a treatment table. 
     
     
         17 . A method of calibrating a radiotherapy treatment device comprising:
 providing a source of radiation along an axis;   providing a phantom body formed of a material having a density proximate that of a human body;   providing a tank containing said phantom body;   providing at least one dosimetry probe constructed and arranged to sense photons and electrons;   positioning said at least one dosimetry probe within said phantom body;   providing a plurality of rails secured to said tank and said phantom body;   providing a rotary table;   positioning said tank and said plurality of rails on said rotary table;   incrementally moving said tank and said phantom body in a substantially vertical, radial, transverse or diagonal direction relative to a radiation source; and   employing a controller to simultaneously move both said tank and said at least one dosimetry probe relative to each other while maintaining the distance between a radiation source and the axis of a beam emitted from the radiation source relative to said at least one dosimetry probe substantially constant;   whereby movement of said phantom body through a series of locations is carried out so as to provide sufficient data to determine the proper dose of radiation required for radiotherapy treatment.   
     
     
         18 . The method of calibrating a radiotherapy treatment device of  claim 17  wherein one of said plurality of rails is a Z-axis guideway constructed and arranged to traverse said dosemetry probe. 
     
     
         19 . The method of calibrating a radiotherapy treatment device of  claim 17  wherein one of said plurality of rails is a Y-axis guideway constructed and arranged to traverse said tank. 
     
     
         20 . The method of calibrating a radiotherapy treatment device of  claim 17  wherein one of said plurality of rails is a X-axis guideway constructed and arranged to traverse said dosemetry probe.

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