Optical Scintillation Detector Monitors Radiation Treatments
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By MedImaging International staff writers Posted on 15 Nov 2017 |
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Image: An optical system measures and validates radiation doses (Photo courtesy of RadiaDyne).
A new system provides diagnostic pinpoint accuracy measurement of the radiation treatment plan by verifying the dose delivered is consistent with the prescribed dose.
The RadiaDyne (Houston, TX, USA) OARtrac system is a real-time in vivo dosimetry device system that uses disposable scintillating detectors during stereotactic body radiotherapy (SBRT) and intensity-modulated radiation therapy (IMRT) for prostate cancer treatment or brachytherapy. The system is based on plastic scintillation detector (PSD) probes connected to a duplex fiber-optical cable that transmits the PSD signals to a charge coupled device (CCD) camera that measures the scintillator output signal.
The optical measurement is converted to an electrical signal and displayed on a digital readout located in the control room of the linear accelerator treatment machine. Based on the continuous review of the accumulative dose data provided by the system, radiation oncologists can adjust subsequent treatment if and when required, thus allowing for a true adaptive radiation therapy protocol. The PSD sensor cable can be used up to five times on the same patient.
“Radiation oncologists can now monitor multiple radiation delivery modalities within the same treatment center, as well as reduce overall treatment costs related to routine patient dose monitoring,” said John Isham, founder of RadiaDyne.
Organs at risk (OAR) are defined as normal tissues whose radiation sensitivity may significantly influence treatment planning and/or the prescribed radiation dose.
Related Links:
RadiaDyne
The RadiaDyne (Houston, TX, USA) OARtrac system is a real-time in vivo dosimetry device system that uses disposable scintillating detectors during stereotactic body radiotherapy (SBRT) and intensity-modulated radiation therapy (IMRT) for prostate cancer treatment or brachytherapy. The system is based on plastic scintillation detector (PSD) probes connected to a duplex fiber-optical cable that transmits the PSD signals to a charge coupled device (CCD) camera that measures the scintillator output signal.
The optical measurement is converted to an electrical signal and displayed on a digital readout located in the control room of the linear accelerator treatment machine. Based on the continuous review of the accumulative dose data provided by the system, radiation oncologists can adjust subsequent treatment if and when required, thus allowing for a true adaptive radiation therapy protocol. The PSD sensor cable can be used up to five times on the same patient.
“Radiation oncologists can now monitor multiple radiation delivery modalities within the same treatment center, as well as reduce overall treatment costs related to routine patient dose monitoring,” said John Isham, founder of RadiaDyne.
Organs at risk (OAR) are defined as normal tissues whose radiation sensitivity may significantly influence treatment planning and/or the prescribed radiation dose.
Related Links:
RadiaDyne
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