Novel Silicon Devices for Radiation Therapy Monitoring
Modern radiotherapy techniques pose specific constraints in radiation-monitoring and dosimetry due to the occurrence of small radiation fields with high dose gradients, variation in space and time of the dose rate, variation in space and time of the beam energy spectrum. Novel devices coping with th...
Ausführliche Beschreibung
Gespeichert in:
| Autor*in: |
Bruzzi, Mara [verfasserIn] |
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| Format: |
E-Artikel |
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| Sprache: |
Englisch |
| Erschienen: |
2016transfer abstract |
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| Schlagwörter: |
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| Umfang: |
8 |
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| Übergeordnetes Werk: |
Enthalten in: The efficacy of EEG-biofeedback for acute pain management, a randomized sham-controlled study of a tailored protocol - Ide, C.V. ELSEVIER, 2017, a journal on accelerators, instrumentation and techniques applied to research in nuclear and atomic physics, materials science and related fields in physics, Amsterdam |
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| Übergeordnetes Werk: |
volume:809 ; year:2016 ; day:11 ; month:02 ; pages:105-112 ; extent:8 |
| Links: |
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| DOI / URN: |
10.1016/j.nima.2015.10.072 |
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ELV013927604 |
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| 520 | |a Modern radiotherapy techniques pose specific constraints in radiation-monitoring and dosimetry due to the occurrence of small radiation fields with high dose gradients, variation in space and time of the dose rate, variation in space and time of the beam energy spectrum. Novel devices coping with these strict conditions are needed. This paper reviews the most advanced technologies developed with silicon-based materials for clinical radiotherapy. Novel Si diodes as Pt-doped Si, epitaxial Si as well as thin devices have optimized performance, their response being independent of the accumulated dose, thus ensuring radiation tolerance and no need of recalibration. Monolithic devices based on segmented Si detectors can be easily tailored to optimize spatial resolution in the large active areas required in clinical radiotherapy. In particular, a monolithic device based on epitaxial p-type silicon, characterized by high spatial resolution and ability to directly measure temporal variations in dose modulation proved to be best viable solution for pre-treatment verifications in IMRT fields. | ||
| 520 | |a Modern radiotherapy techniques pose specific constraints in radiation-monitoring and dosimetry due to the occurrence of small radiation fields with high dose gradients, variation in space and time of the dose rate, variation in space and time of the beam energy spectrum. Novel devices coping with these strict conditions are needed. This paper reviews the most advanced technologies developed with silicon-based materials for clinical radiotherapy. Novel Si diodes as Pt-doped Si, epitaxial Si as well as thin devices have optimized performance, their response being independent of the accumulated dose, thus ensuring radiation tolerance and no need of recalibration. Monolithic devices based on segmented Si detectors can be easily tailored to optimize spatial resolution in the large active areas required in clinical radiotherapy. In particular, a monolithic device based on epitaxial p-type silicon, characterized by high spatial resolution and ability to directly measure temporal variations in dose modulation proved to be best viable solution for pre-treatment verifications in IMRT fields. | ||
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10.1016/j.nima.2015.10.072 doi GBVA2016006000029.pica (DE-627)ELV013927604 (ELSEVIER)S0168-9002(15)01284-X DE-627 ger DE-627 rakwb eng 530 530 DE-600 610 VZ 44.90 bkl Bruzzi, Mara verfasserin aut Novel Silicon Devices for Radiation Therapy Monitoring 2016transfer abstract 8 nicht spezifiziert zzz rdacontent nicht spezifiziert z rdamedia nicht spezifiziert zu rdacarrier Modern radiotherapy techniques pose specific constraints in radiation-monitoring and dosimetry due to the occurrence of small radiation fields with high dose gradients, variation in space and time of the dose rate, variation in space and time of the beam energy spectrum. Novel devices coping with these strict conditions are needed. This paper reviews the most advanced technologies developed with silicon-based materials for clinical radiotherapy. Novel Si diodes as Pt-doped Si, epitaxial Si as well as thin devices have optimized performance, their response being independent of the accumulated dose, thus ensuring radiation tolerance and no need of recalibration. Monolithic devices based on segmented Si detectors can be easily tailored to optimize spatial resolution in the large active areas required in clinical radiotherapy. In particular, a monolithic device based on epitaxial p-type silicon, characterized by high spatial resolution and ability to directly measure temporal variations in dose modulation proved to be best viable solution for pre-treatment verifications in IMRT fields. Modern radiotherapy techniques pose specific constraints in radiation-monitoring and dosimetry due to the occurrence of small radiation fields with high dose gradients, variation in space and time of the dose rate, variation in space and time of the beam energy spectrum. Novel devices coping with these strict conditions are needed. This paper reviews the most advanced technologies developed with silicon-based materials for clinical radiotherapy. Novel Si diodes as Pt-doped Si, epitaxial Si as well as thin devices have optimized performance, their response being independent of the accumulated dose, thus ensuring radiation tolerance and no need of recalibration. Monolithic devices based on segmented Si detectors can be easily tailored to optimize spatial resolution in the large active areas required in clinical radiotherapy. In particular, a monolithic device based on epitaxial p-type silicon, characterized by high spatial resolution and ability to directly measure temporal variations in dose modulation proved to be best viable solution for pre-treatment verifications in IMRT fields. Dosimeters Elsevier IMRT Elsevier Silicon Elsevier Enthalten in North-Holland Publ. Co Ide, C.V. ELSEVIER The efficacy of EEG-biofeedback for acute pain management, a randomized sham-controlled study of a tailored protocol 2017 a journal on accelerators, instrumentation and techniques applied to research in nuclear and atomic physics, materials science and related fields in physics Amsterdam (DE-627)ELV000874671 volume:809 year:2016 day:11 month:02 pages:105-112 extent:8 https://doi.org/10.1016/j.nima.2015.10.072 Volltext GBV_USEFLAG_U GBV_ELV SYSFLAG_U SSG-OLC-PHA 44.90 Neurologie VZ AR 809 2016 11 0211 105-112 8 045F 530 |
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10.1016/j.nima.2015.10.072 doi GBVA2016006000029.pica (DE-627)ELV013927604 (ELSEVIER)S0168-9002(15)01284-X DE-627 ger DE-627 rakwb eng 530 530 DE-600 610 VZ 44.90 bkl Bruzzi, Mara verfasserin aut Novel Silicon Devices for Radiation Therapy Monitoring 2016transfer abstract 8 nicht spezifiziert zzz rdacontent nicht spezifiziert z rdamedia nicht spezifiziert zu rdacarrier Modern radiotherapy techniques pose specific constraints in radiation-monitoring and dosimetry due to the occurrence of small radiation fields with high dose gradients, variation in space and time of the dose rate, variation in space and time of the beam energy spectrum. Novel devices coping with these strict conditions are needed. This paper reviews the most advanced technologies developed with silicon-based materials for clinical radiotherapy. Novel Si diodes as Pt-doped Si, epitaxial Si as well as thin devices have optimized performance, their response being independent of the accumulated dose, thus ensuring radiation tolerance and no need of recalibration. Monolithic devices based on segmented Si detectors can be easily tailored to optimize spatial resolution in the large active areas required in clinical radiotherapy. In particular, a monolithic device based on epitaxial p-type silicon, characterized by high spatial resolution and ability to directly measure temporal variations in dose modulation proved to be best viable solution for pre-treatment verifications in IMRT fields. Modern radiotherapy techniques pose specific constraints in radiation-monitoring and dosimetry due to the occurrence of small radiation fields with high dose gradients, variation in space and time of the dose rate, variation in space and time of the beam energy spectrum. Novel devices coping with these strict conditions are needed. This paper reviews the most advanced technologies developed with silicon-based materials for clinical radiotherapy. Novel Si diodes as Pt-doped Si, epitaxial Si as well as thin devices have optimized performance, their response being independent of the accumulated dose, thus ensuring radiation tolerance and no need of recalibration. Monolithic devices based on segmented Si detectors can be easily tailored to optimize spatial resolution in the large active areas required in clinical radiotherapy. In particular, a monolithic device based on epitaxial p-type silicon, characterized by high spatial resolution and ability to directly measure temporal variations in dose modulation proved to be best viable solution for pre-treatment verifications in IMRT fields. Dosimeters Elsevier IMRT Elsevier Silicon Elsevier Enthalten in North-Holland Publ. Co Ide, C.V. ELSEVIER The efficacy of EEG-biofeedback for acute pain management, a randomized sham-controlled study of a tailored protocol 2017 a journal on accelerators, instrumentation and techniques applied to research in nuclear and atomic physics, materials science and related fields in physics Amsterdam (DE-627)ELV000874671 volume:809 year:2016 day:11 month:02 pages:105-112 extent:8 https://doi.org/10.1016/j.nima.2015.10.072 Volltext GBV_USEFLAG_U GBV_ELV SYSFLAG_U SSG-OLC-PHA 44.90 Neurologie VZ AR 809 2016 11 0211 105-112 8 045F 530 |
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10.1016/j.nima.2015.10.072 doi GBVA2016006000029.pica (DE-627)ELV013927604 (ELSEVIER)S0168-9002(15)01284-X DE-627 ger DE-627 rakwb eng 530 530 DE-600 610 VZ 44.90 bkl Bruzzi, Mara verfasserin aut Novel Silicon Devices for Radiation Therapy Monitoring 2016transfer abstract 8 nicht spezifiziert zzz rdacontent nicht spezifiziert z rdamedia nicht spezifiziert zu rdacarrier Modern radiotherapy techniques pose specific constraints in radiation-monitoring and dosimetry due to the occurrence of small radiation fields with high dose gradients, variation in space and time of the dose rate, variation in space and time of the beam energy spectrum. Novel devices coping with these strict conditions are needed. This paper reviews the most advanced technologies developed with silicon-based materials for clinical radiotherapy. Novel Si diodes as Pt-doped Si, epitaxial Si as well as thin devices have optimized performance, their response being independent of the accumulated dose, thus ensuring radiation tolerance and no need of recalibration. Monolithic devices based on segmented Si detectors can be easily tailored to optimize spatial resolution in the large active areas required in clinical radiotherapy. In particular, a monolithic device based on epitaxial p-type silicon, characterized by high spatial resolution and ability to directly measure temporal variations in dose modulation proved to be best viable solution for pre-treatment verifications in IMRT fields. Modern radiotherapy techniques pose specific constraints in radiation-monitoring and dosimetry due to the occurrence of small radiation fields with high dose gradients, variation in space and time of the dose rate, variation in space and time of the beam energy spectrum. Novel devices coping with these strict conditions are needed. This paper reviews the most advanced technologies developed with silicon-based materials for clinical radiotherapy. Novel Si diodes as Pt-doped Si, epitaxial Si as well as thin devices have optimized performance, their response being independent of the accumulated dose, thus ensuring radiation tolerance and no need of recalibration. Monolithic devices based on segmented Si detectors can be easily tailored to optimize spatial resolution in the large active areas required in clinical radiotherapy. In particular, a monolithic device based on epitaxial p-type silicon, characterized by high spatial resolution and ability to directly measure temporal variations in dose modulation proved to be best viable solution for pre-treatment verifications in IMRT fields. Dosimeters Elsevier IMRT Elsevier Silicon Elsevier Enthalten in North-Holland Publ. Co Ide, C.V. ELSEVIER The efficacy of EEG-biofeedback for acute pain management, a randomized sham-controlled study of a tailored protocol 2017 a journal on accelerators, instrumentation and techniques applied to research in nuclear and atomic physics, materials science and related fields in physics Amsterdam (DE-627)ELV000874671 volume:809 year:2016 day:11 month:02 pages:105-112 extent:8 https://doi.org/10.1016/j.nima.2015.10.072 Volltext GBV_USEFLAG_U GBV_ELV SYSFLAG_U SSG-OLC-PHA 44.90 Neurologie VZ AR 809 2016 11 0211 105-112 8 045F 530 |
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10.1016/j.nima.2015.10.072 doi GBVA2016006000029.pica (DE-627)ELV013927604 (ELSEVIER)S0168-9002(15)01284-X DE-627 ger DE-627 rakwb eng 530 530 DE-600 610 VZ 44.90 bkl Bruzzi, Mara verfasserin aut Novel Silicon Devices for Radiation Therapy Monitoring 2016transfer abstract 8 nicht spezifiziert zzz rdacontent nicht spezifiziert z rdamedia nicht spezifiziert zu rdacarrier Modern radiotherapy techniques pose specific constraints in radiation-monitoring and dosimetry due to the occurrence of small radiation fields with high dose gradients, variation in space and time of the dose rate, variation in space and time of the beam energy spectrum. Novel devices coping with these strict conditions are needed. This paper reviews the most advanced technologies developed with silicon-based materials for clinical radiotherapy. Novel Si diodes as Pt-doped Si, epitaxial Si as well as thin devices have optimized performance, their response being independent of the accumulated dose, thus ensuring radiation tolerance and no need of recalibration. Monolithic devices based on segmented Si detectors can be easily tailored to optimize spatial resolution in the large active areas required in clinical radiotherapy. In particular, a monolithic device based on epitaxial p-type silicon, characterized by high spatial resolution and ability to directly measure temporal variations in dose modulation proved to be best viable solution for pre-treatment verifications in IMRT fields. Modern radiotherapy techniques pose specific constraints in radiation-monitoring and dosimetry due to the occurrence of small radiation fields with high dose gradients, variation in space and time of the dose rate, variation in space and time of the beam energy spectrum. Novel devices coping with these strict conditions are needed. This paper reviews the most advanced technologies developed with silicon-based materials for clinical radiotherapy. Novel Si diodes as Pt-doped Si, epitaxial Si as well as thin devices have optimized performance, their response being independent of the accumulated dose, thus ensuring radiation tolerance and no need of recalibration. Monolithic devices based on segmented Si detectors can be easily tailored to optimize spatial resolution in the large active areas required in clinical radiotherapy. In particular, a monolithic device based on epitaxial p-type silicon, characterized by high spatial resolution and ability to directly measure temporal variations in dose modulation proved to be best viable solution for pre-treatment verifications in IMRT fields. Dosimeters Elsevier IMRT Elsevier Silicon Elsevier Enthalten in North-Holland Publ. Co Ide, C.V. ELSEVIER The efficacy of EEG-biofeedback for acute pain management, a randomized sham-controlled study of a tailored protocol 2017 a journal on accelerators, instrumentation and techniques applied to research in nuclear and atomic physics, materials science and related fields in physics Amsterdam (DE-627)ELV000874671 volume:809 year:2016 day:11 month:02 pages:105-112 extent:8 https://doi.org/10.1016/j.nima.2015.10.072 Volltext GBV_USEFLAG_U GBV_ELV SYSFLAG_U SSG-OLC-PHA 44.90 Neurologie VZ AR 809 2016 11 0211 105-112 8 045F 530 |
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The efficacy of EEG-biofeedback for acute pain management, a randomized sham-controlled study of a tailored protocol |
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The efficacy of EEG-biofeedback for acute pain management, a randomized sham-controlled study of a tailored protocol |
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Novel Silicon Devices for Radiation Therapy Monitoring |
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The efficacy of EEG-biofeedback for acute pain management, a randomized sham-controlled study of a tailored protocol |
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The efficacy of EEG-biofeedback for acute pain management, a randomized sham-controlled study of a tailored protocol |
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novel silicon devices for radiation therapy monitoring |
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Novel Silicon Devices for Radiation Therapy Monitoring |
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Modern radiotherapy techniques pose specific constraints in radiation-monitoring and dosimetry due to the occurrence of small radiation fields with high dose gradients, variation in space and time of the dose rate, variation in space and time of the beam energy spectrum. Novel devices coping with these strict conditions are needed. This paper reviews the most advanced technologies developed with silicon-based materials for clinical radiotherapy. Novel Si diodes as Pt-doped Si, epitaxial Si as well as thin devices have optimized performance, their response being independent of the accumulated dose, thus ensuring radiation tolerance and no need of recalibration. Monolithic devices based on segmented Si detectors can be easily tailored to optimize spatial resolution in the large active areas required in clinical radiotherapy. In particular, a monolithic device based on epitaxial p-type silicon, characterized by high spatial resolution and ability to directly measure temporal variations in dose modulation proved to be best viable solution for pre-treatment verifications in IMRT fields. |
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Modern radiotherapy techniques pose specific constraints in radiation-monitoring and dosimetry due to the occurrence of small radiation fields with high dose gradients, variation in space and time of the dose rate, variation in space and time of the beam energy spectrum. Novel devices coping with these strict conditions are needed. This paper reviews the most advanced technologies developed with silicon-based materials for clinical radiotherapy. Novel Si diodes as Pt-doped Si, epitaxial Si as well as thin devices have optimized performance, their response being independent of the accumulated dose, thus ensuring radiation tolerance and no need of recalibration. Monolithic devices based on segmented Si detectors can be easily tailored to optimize spatial resolution in the large active areas required in clinical radiotherapy. In particular, a monolithic device based on epitaxial p-type silicon, characterized by high spatial resolution and ability to directly measure temporal variations in dose modulation proved to be best viable solution for pre-treatment verifications in IMRT fields. |
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Modern radiotherapy techniques pose specific constraints in radiation-monitoring and dosimetry due to the occurrence of small radiation fields with high dose gradients, variation in space and time of the dose rate, variation in space and time of the beam energy spectrum. Novel devices coping with these strict conditions are needed. This paper reviews the most advanced technologies developed with silicon-based materials for clinical radiotherapy. Novel Si diodes as Pt-doped Si, epitaxial Si as well as thin devices have optimized performance, their response being independent of the accumulated dose, thus ensuring radiation tolerance and no need of recalibration. Monolithic devices based on segmented Si detectors can be easily tailored to optimize spatial resolution in the large active areas required in clinical radiotherapy. In particular, a monolithic device based on epitaxial p-type silicon, characterized by high spatial resolution and ability to directly measure temporal variations in dose modulation proved to be best viable solution for pre-treatment verifications in IMRT fields. |
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Novel Silicon Devices for Radiation Therapy Monitoring |
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