PET for radiotherapy planning

Publikation: Bidrag til bog/antologi/rapportBidrag til bog/antologiForskningfagfællebedømt

Standard

PET for radiotherapy planning. / Dejanovic, Danijela; Specht, Lena; Munk, Ole Lajord; Christensen, Charlotte Birk; Berthelsen, Anne Kiil; Law, Ian; Loft, Annika.

Nuclear Medicine and Molecular Imaging: Volume 1-4. Bind 3 Elsevier, 2022. s. 774-792.

Publikation: Bidrag til bog/antologi/rapportBidrag til bog/antologiForskningfagfællebedømt

Harvard

Dejanovic, D, Specht, L, Munk, OL, Christensen, CB, Berthelsen, AK, Law, I & Loft, A 2022, PET for radiotherapy planning. i Nuclear Medicine and Molecular Imaging: Volume 1-4. bind 3, Elsevier, s. 774-792. https://doi.org/10.1016/B978-0-12-822960-6.00128-9

APA

Dejanovic, D., Specht, L., Munk, O. L., Christensen, C. B., Berthelsen, A. K., Law, I., & Loft, A. (2022). PET for radiotherapy planning. I Nuclear Medicine and Molecular Imaging: Volume 1-4 (Bind 3, s. 774-792). Elsevier. https://doi.org/10.1016/B978-0-12-822960-6.00128-9

Vancouver

Dejanovic D, Specht L, Munk OL, Christensen CB, Berthelsen AK, Law I o.a. PET for radiotherapy planning. I Nuclear Medicine and Molecular Imaging: Volume 1-4. Bind 3. Elsevier. 2022. s. 774-792 https://doi.org/10.1016/B978-0-12-822960-6.00128-9

Author

Dejanovic, Danijela ; Specht, Lena ; Munk, Ole Lajord ; Christensen, Charlotte Birk ; Berthelsen, Anne Kiil ; Law, Ian ; Loft, Annika. / PET for radiotherapy planning. Nuclear Medicine and Molecular Imaging: Volume 1-4. Bind 3 Elsevier, 2022. s. 774-792

Bibtex

@inbook{e48bf85963814959b999daaf9dc9ca66,
title = "PET for radiotherapy planning",
abstract = "To benefit from modern radiation therapy characterized by highly conformal dose distribution and steep dose gradients, high quality imaging is required for precise tumor delineation. The standard imaging for radiation therapy planning (RTP) remains the acquisition of a dedicated planning computed tomography (CT). Recent advances in combined functional and structural imaging, e.g. hybrid positron emission tomography and CT (PET/CT) have led to progress in management of cancer patients. As PET/CT has become widely available it is increasingly being incorporated into routine RTP. PET/CT in RTP is a multidisciplinary task involving the expertise in radiation oncology, radiology, nuclear medicine and medical physics. Imaging protocols and tumor delineation methods for PET/CT in RT planning should be well-defined and rigorously applied to guarantee reproducibility. The most often used radiotracer for PET/CT in RTP is the glucose analog [18F]FDG, depicting cell metabolism with high sensitivity but low specificity as it is not a specific tumor tracer. PET-based RTP can improve local tumor control by reducing target volume and using dose escalation, with fewer side effects by restricting RT to [18F]FDG avid volumes. Applications of functional imaging are continuously evolving with development of novel PET tracers aimed at specific biological processes. As personalized medicine has become a true force in modern medicine, the individualization of treatment strategies in RTP will require functional imaging in the tailoring of RT for each patient. Novel approaches in radiation therapy delivery, such as dose painting using PET/CT, have been suggested as methods to reduce risk of local recurrence. Equally important, is minimizing radiation toxicity to normal tissue by using PET/CT with breath hold techniques. Furthermore, PET/CT is increasingly used to predict and evaluate response to RT to optimize treatment strategy.",
keywords = "DIBH, Dose painting, FDG, GTV, Image reconstruction, IMRT, PET/CT, Radiation therapy, Tumor delineation",
author = "Danijela Dejanovic and Lena Specht and Munk, {Ole Lajord} and Christensen, {Charlotte Birk} and Berthelsen, {Anne Kiil} and Ian Law and Annika Loft",
note = "Publisher Copyright: {\textcopyright} 2022 Elsevier Inc. All rights reserved.",
year = "2022",
doi = "10.1016/B978-0-12-822960-6.00128-9",
language = "English",
isbn = "9780128229606",
volume = "3",
pages = "774--792",
booktitle = "Nuclear Medicine and Molecular Imaging",
publisher = "Elsevier",
address = "Netherlands",

}

RIS

TY - CHAP

T1 - PET for radiotherapy planning

AU - Dejanovic, Danijela

AU - Specht, Lena

AU - Munk, Ole Lajord

AU - Christensen, Charlotte Birk

AU - Berthelsen, Anne Kiil

AU - Law, Ian

AU - Loft, Annika

N1 - Publisher Copyright: © 2022 Elsevier Inc. All rights reserved.

PY - 2022

Y1 - 2022

N2 - To benefit from modern radiation therapy characterized by highly conformal dose distribution and steep dose gradients, high quality imaging is required for precise tumor delineation. The standard imaging for radiation therapy planning (RTP) remains the acquisition of a dedicated planning computed tomography (CT). Recent advances in combined functional and structural imaging, e.g. hybrid positron emission tomography and CT (PET/CT) have led to progress in management of cancer patients. As PET/CT has become widely available it is increasingly being incorporated into routine RTP. PET/CT in RTP is a multidisciplinary task involving the expertise in radiation oncology, radiology, nuclear medicine and medical physics. Imaging protocols and tumor delineation methods for PET/CT in RT planning should be well-defined and rigorously applied to guarantee reproducibility. The most often used radiotracer for PET/CT in RTP is the glucose analog [18F]FDG, depicting cell metabolism with high sensitivity but low specificity as it is not a specific tumor tracer. PET-based RTP can improve local tumor control by reducing target volume and using dose escalation, with fewer side effects by restricting RT to [18F]FDG avid volumes. Applications of functional imaging are continuously evolving with development of novel PET tracers aimed at specific biological processes. As personalized medicine has become a true force in modern medicine, the individualization of treatment strategies in RTP will require functional imaging in the tailoring of RT for each patient. Novel approaches in radiation therapy delivery, such as dose painting using PET/CT, have been suggested as methods to reduce risk of local recurrence. Equally important, is minimizing radiation toxicity to normal tissue by using PET/CT with breath hold techniques. Furthermore, PET/CT is increasingly used to predict and evaluate response to RT to optimize treatment strategy.

AB - To benefit from modern radiation therapy characterized by highly conformal dose distribution and steep dose gradients, high quality imaging is required for precise tumor delineation. The standard imaging for radiation therapy planning (RTP) remains the acquisition of a dedicated planning computed tomography (CT). Recent advances in combined functional and structural imaging, e.g. hybrid positron emission tomography and CT (PET/CT) have led to progress in management of cancer patients. As PET/CT has become widely available it is increasingly being incorporated into routine RTP. PET/CT in RTP is a multidisciplinary task involving the expertise in radiation oncology, radiology, nuclear medicine and medical physics. Imaging protocols and tumor delineation methods for PET/CT in RT planning should be well-defined and rigorously applied to guarantee reproducibility. The most often used radiotracer for PET/CT in RTP is the glucose analog [18F]FDG, depicting cell metabolism with high sensitivity but low specificity as it is not a specific tumor tracer. PET-based RTP can improve local tumor control by reducing target volume and using dose escalation, with fewer side effects by restricting RT to [18F]FDG avid volumes. Applications of functional imaging are continuously evolving with development of novel PET tracers aimed at specific biological processes. As personalized medicine has become a true force in modern medicine, the individualization of treatment strategies in RTP will require functional imaging in the tailoring of RT for each patient. Novel approaches in radiation therapy delivery, such as dose painting using PET/CT, have been suggested as methods to reduce risk of local recurrence. Equally important, is minimizing radiation toxicity to normal tissue by using PET/CT with breath hold techniques. Furthermore, PET/CT is increasingly used to predict and evaluate response to RT to optimize treatment strategy.

KW - DIBH

KW - Dose painting

KW - FDG

KW - GTV

KW - Image reconstruction

KW - IMRT

KW - PET/CT

KW - Radiation therapy

KW - Tumor delineation

U2 - 10.1016/B978-0-12-822960-6.00128-9

DO - 10.1016/B978-0-12-822960-6.00128-9

M3 - Book chapter

AN - SCOPUS:85151225166

SN - 9780128229606

VL - 3

SP - 774

EP - 792

BT - Nuclear Medicine and Molecular Imaging

PB - Elsevier

ER -

ID: 345055290