Systems, devices and methods related to calibration of a proton computed tomography scanner
First Claim
1. A computed tomography system comprising:
- a particle detection system comprising one or more detectors, the particle detection system configured to generate a signal in response to interaction between an ion and at least one of the one or more detectors;
a calibration device comprising a plurality of degrader plates configured to be introduced into a beam of ions along a beam axis, the plurality of degrader plates in combination having a known water-equivalent thickness (WET) value;
a processor configured to determine, for each of a plurality of ions that interact with the particle detection system;
an initial energy corresponding to an energy prior to interaction with the calibration device and a final energy corresponding to an energy after interaction with the calibration device; and
a relationship between a difference between the initial energy and the final energy and a water-equivalent path length (WEPL), the WEPL based on the known WET values,wherein the plurality of degrader plates has a first known WET value for a first path through the plurality of degrader plates and a second known WET value for a second path through the plurality of degrader plates, the first path and the second path being parallel to one another and offset from one another in a direction perpendicular to the beam axis.
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Accused Products
Abstract
Disclosed are systems, devices and methodologies related to calibration of an ion based imaging apparatus such as a proton computed tomography scanner. In some implementations, energy degrader plates having known water-equivalent thickness (WET) values can be introduced to an ion beam to introduce different energy degradation settings. Energy detector responses to individual ions subject to such energy degradation settings can be obtained. Such responses can be normalized and correlated to water-equivalent path lengths (WEPL) of the ions based on the known WET values. Such calibration utilizing degrader plates can be performed relatively quickly and can yield accurate WEPL values that facilitate estimation of, for example, a CT image based on relative stopping power of an object.
266 Citations
20 Claims
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1. A computed tomography system comprising:
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a particle detection system comprising one or more detectors, the particle detection system configured to generate a signal in response to interaction between an ion and at least one of the one or more detectors; a calibration device comprising a plurality of degrader plates configured to be introduced into a beam of ions along a beam axis, the plurality of degrader plates in combination having a known water-equivalent thickness (WET) value; a processor configured to determine, for each of a plurality of ions that interact with the particle detection system; an initial energy corresponding to an energy prior to interaction with the calibration device and a final energy corresponding to an energy after interaction with the calibration device; and a relationship between a difference between the initial energy and the final energy and a water-equivalent path length (WEPL), the WEPL based on the known WET values, wherein the plurality of degrader plates has a first known WET value for a first path through the plurality of degrader plates and a second known WET value for a second path through the plurality of degrader plates, the first path and the second path being parallel to one another and offset from one another in a direction perpendicular to the beam axis. - View Dependent Claims (2, 3, 4, 5)
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6. A proton computed tomography system comprising:
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a calibration device comprising a plurality of degrader plates configured to be introduced into a beam of protons along a beam axis, each of the plurality of degrader plates having a known water-equivalent thickness (WET) value; a particle detection system configured to generate signals in response to interaction between a proton and the particle detection system comprising; a front tracker detector positioned so that the beam axis intersects the front tracker detector prior to the calibration device; a rear tracker detector positioned so that the beam axis intersects the rear tracker detector after the calibration device; and an energy detector positioned so that the beam axis intersects the energy detector after the calibration device; a processor configured to determine, for each of a plurality of protons that interact with the particle detection system; a path through the calibration device, the path determined by analyzing signals generated by the front tracker detector and the rear tracker detector; an energy measurement determined by analyzing signals generated by the energy detector; and a calibration factor relating the energy measurement to a water-equivalent path length (WEPL), the WEPL based on the known WET values and the path through the calibration device. - View Dependent Claims (7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20)
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Specification