Peripheral dose from megavoltage cone‐beam CT imaging for nasopharyngeal carcinoma image‐guided radiation therapy

Jia, Ming X.; Li, Na; Wang, En Y.; Liu, Da W.; Cai, Wei

doi:10.1120/jacmp.v13i5.3869

Cited by 2 publications

(2 citation statements)

References 31 publications

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“…In addition, both studies utilized the pelvic (high dose) imaging hence the peripheral dose could be substantially less if a low dose setting is used. In another study, Jia et al [85] measured the peripheral dose from a MV CBCT system and concluded that the magnitude of its peripheral dose is similar to that of kV CBCT imaging, and that it increases with use of higher dose imaging.…”

Section: Peripheral Dose From Cbct Imagingmentioning

confidence: 95%

Imaging dose from cone beam computed tomography in radiation therapy

2015

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Imaging dose in radiation therapy has traditionally been ignored due to its low magnitude and frequency in comparison to therapeutic dose used to treat patients. The advent of modern, volumetric, imaging modalities, often as an integral part of linear accelerators, has facilitated the implementation of image-guided radiation therapy (IGRT), which is often accomplished by daily imaging of patients. Daily imaging results in additional dose delivered to patient that warrants new attention be given to imaging dose. This review summarizes the imaging dose delivered to patients as the result of cone beam computed tomography (CBCT) imaging performed in radiation therapy using current methods and equipment. This review also summarizes methods to calculate the imaging dose, including the use of Monte Carlo (MC) and treatment planning systems (TPS). Peripheral dose from CBCT imaging, dose reduction methods, the use of effective dose in describing imaging dose, and the measurement of CT dose index (CTDI) in CBCT systems are also reviewed.

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Section: Peripheral Dose From Cbct Imagingmentioning

confidence: 95%

Imaging dose from cone beam computed tomography in radiation therapy

2015

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“…Incorporating MV imaging dose into the treatment plan and avoiding daily MVCBCT imaging is advised to reduce excess dose [124]. Other dose limiting recommendations include: use of a posterior CBCT acquisition angle (90-290 degrees) to reduce eye dose [125], utilising topogram feature to move field of view caudally [126] and using the lowest numbers of monitor units possible to acquire MV images [124].…”

Section: Imaging Dosementioning

confidence: 99%

A review of Image Guided Radiation Therapy in head and neck cancer from 2009–2019 – Best Practice Recommendations for RTTs in the Clinic

Kearney

Coffey

Leong

2020

Technical Innovations & Patient Support in Radiation Oncolo

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Radiation therapy (RT) is beneficial in Head and Neck Cancer (HNC) in both the definitive and adjuvant setting. Highly complex and conformal planning techniques are becoming standard practice in delivering increased doses in HNC. A sharp falloff in dose outside the high dose area is characteristic of highly complex techniques and geometric uncertainties must be minimised to prevent under dosage of the target volume and possible over dosage of surrounding critical structures. CTV-PTV margins are employed to account for geometric uncertainties such as set up errors and both interfraction and intrafraction motion. Robust immobilisation and Image Guided Radiation Therapy (IGRT) is also essential in this group of patients to minimise discrepancies in patient position during the treatment course. IGRT has evolved with increased 2-Dimensional (2D) and 3-Dimensional (3D) IGRT modalities available for geometric verification. 2D and 3D IGRT modalities are both beneficial in geometric verification while 3D imaging is a valuable tool in assessing volumetric changes that may have dosimetric consequences for this group of patients. IGRT if executed effectively and efficiently provides clinicians with confidence to reduce CTV-PTV margins thus limiting treatment related toxicities in patients. Accumulated exposure dose from IGRT vary considerably and may be incorporated into the treatment plan to avoid excess dose. However, there are considerable variations in the application of IGRT in RT practice. This paper aims to summarise the advances in IGRT in HNC treatment and provide clinics with recommendations for an IGRT strategy for HNC in the clinic.

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Peripheral dose from megavoltage cone‐beam CT imaging for nasopharyngeal carcinoma image‐guided radiation therapy

Cited by 2 publications

References 31 publications

Imaging dose from cone beam computed tomography in radiation therapy

Imaging dose from cone beam computed tomography in radiation therapy

A review of Image Guided Radiation Therapy in head and neck cancer from 2009–2019 – Best Practice Recommendations for RTTs in the Clinic

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