Estimating the Patient-specific Dose to the Thyroid and Breasts and                    Overall Risk in Chest CT When Using Organ-based Tube Current                    Modulation

Franck, Caro; Smeets, Peter; Lapeire, Lore; Achten, Eric; Bacher, Klaus

doi:10.1148/radiol.2018170757

Cited by 21 publications

(25 citation statements)

References 25 publications

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“…Finally Wang et al found a dose reduction of 34–39% for the risk organ–based tube current modulation using a semianthropomorphic phantom [ 21 ]. Our results are in line with those studies, but there has been a recent study by Franck et al that showed there is only a 9% dose reduction in the female breast, in contrast to our results [ 22 ]. This difference can be explained in that, in their study, not all breast tissue was within the reduced tube current zone, and therefore the effect was not as big as if the breast tissue was within the reduced tube current zone.…”

Section: Discussionsupporting

confidence: 93%

Influence of risk-organ–based tube current modulation on CT-induced DNA double-strand breaks in a biological phantom model

Brand

Wuest

May

et al. 2018

Journal of Radiation Research

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Techniques for dose reduction in computed tomography (CT) are receiving increasing attention. Lowering the tube current in front of the patient, known as risk-organ–based tube current modulation (RTM), represents a new approach. Physical dose parameters can determine the exposure but are not able to assess the biological–X-ray interactions. The purpose of this study was to establish a biological phantom model to evaluate the effect of RTM on X-ray–induced DNA double-strand breaks (DSBs). In breast phantoms and in the location of the spine in an Alderson phantom, isolated human blood lymphocytes were irradiated using a 128-slice CT scanner. A standard thoracic CT protocol (120 kV, 110 ref. mAs, anatomy-based tube current modulation, pitch 0.6, scan length 30 cm) with and without RTM was used. X-ray–induced DSBs were quantified in isolated blood lymphocytes using immunofluorescence microscopy after staining for the phosphorylated histone variant γ-H2AX. Using RTM, the resulting DNA damage reduction was 41% in superficial breast locations (P = 0.0001), 28% in middle breast locations (P = 0.0003) and 29% in lower breast locations (P = 0.0001), but we found a DNA damage increase of 36% in superficial spine locations (P = 0.0001) and of 26% in deep spine locations (P = 0.0001). In summary, we established a biological phantom model that is suitable for detecting DNA damage in distinct organs. In addition, we were able to show that, using RTM, X-ray–induced DNA damage in the breast can be significantly reduced; however, there is a significant increase in DSBs in the location of the spine.

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Section: Discussionsupporting

confidence: 93%

Influence of risk-organ–based tube current modulation on CT-induced DNA double-strand breaks in a biological phantom model

Brand

Wuest

May

et al. 2018

Journal of Radiation Research

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“…Although this approach has been documented to reduce dose to superficial radiosensitive organs, it provokes a dose increase to centrally and posteriorly located organs. Franck et al [6] have shown that OTCM in thorax CT of females reduces the dose to thyroid and breast by 18% and 19%, respectively. However, the doses for lung, liver, and kidney were found 17%, 11%, and 26% higher.…”

Section: Discussionmentioning

confidence: 99%

“…However, this approach has been documented to deliver images of increased noise [10,11]. Previous studies performed in adult patients have shown that OTCM may substantially reduce radiation dose to superficial radiosensitive organs [6,8,12,13]. To our knowledge, there is scarce published data on the effect of OTCM on radiation dose to superficial radiosensitive organs and image quality in pediatric CT examinations [14,15].…”

Section: Introductionmentioning

confidence: 99%

“…Different CT vendors have adopted different approaches to implement OTCM. In one approach, implemented by Siemens Healthcare with X-CARE, mA is reduced when the x-ray tube rotates over the anterior quadrant of the body circumference, while it is increased over the lateral and posterior quadrants to preserve image quality [ 6 – 9 ]. However, an increase in dose absorbed by posterior located radiosensitive organs has been demonstrated [ 6 – 8 ].…”

Section: Introductionmentioning

confidence: 99%

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Evaluation of an organ-based tube current modulation tool in pediatric CT examinations

Papadakis¹,

Damilakis²

2020

Eur Radiol

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Objectives To investigate the effect of an organ-based tube current modulation (OTCM) technique on organ absorbed dose and assess image quality in pediatric CT examinations. Methods Four physical anthropomorphic phantoms that represent the average individual as neonate, 1-year-old, 5-year-old, and 10-year-old were used. Standard head and thorax acquisitions were performed with automatic tube current modulation (ATCM) and ATCM+OTCM. Dose calculations were performed by means of Monte Carlo simulations. Radiation dose was measured for superficial and centrally located radiosensitive organs. The angular range of the OTCM exposure window was determined for different tube rotation times (t) by means of a solid-state detector. Image noise was measured as the standard deviation of the Hounsfield unit value in regions of interest drawn at selected anatomical sites. Results ATCM+OTCM resulted in a reduction of radiation dose to all radiosensitive organs. In head, eye lens dose was reduced by up to 13% in ATCM+OTCM compared with ATCM. In thorax, the corresponding reduction for breast dose was up to 10%. The angular range of the OTCM exposure window decreased with t. For t = 0.4 s, the angular range was limited to 74° in head and 135° for thorax. Image noise was significantly increased in ATCM+OTCM acquisitions across most examined phantoms (p < 0.05). Conclusions OTCM reduces radiation dose to exposed radiosensitive organs with the eye lens and breast buds exhibiting the highest dose reduction. The OTCM exposure window is narrowed at short t. An increase in noise is inevitable in images located within the OTCM-activated imaged volume. Key Points • In pediatric CT, organ-based tube current modulation reduces radiation dose to all major primarily exposed radiosensitive organs. • Image noise increases within the organ-based tube current modulation enabled imaged volume. • The angular range of the organ-based tube current modulation low exposure window is reduced with tube rotation time.

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“…A number of studies evaluated the influence of medical radiation exposure on future occurrence of malignant tumors in women who were exposed to high radiation doses due to multiple radiation examinations or treatment by radiotherapy. [ 14 – 16 ] However, the advantages of lung CT examination in revealing small pulmonary lesions has gradually become an important tool in physical examinations. In the conventional chest CT scanning procedure, the direct exposure of the breast to radiation is not avoidable, and the breast is not the target organ in lung CT screening; therefore, it is self-evident that the biological effect of frequent examinations or large doses of radiation might be a potential cancer risk.…”

Section: Discussionmentioning

confidence: 99%

Image quality and clinical usefulness of automatic tube current modulation technology in female chest computed tomography screening

Cheng

Zhang

et al. 2020

Medicine

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Estimating the Patient-specific Dose to the Thyroid and Breasts and Overall Risk in Chest CT When Using Organ-based Tube Current Modulation

Cited by 21 publications

References 25 publications

Influence of risk-organ–based tube current modulation on CT-induced DNA double-strand breaks in a biological phantom model

Influence of risk-organ–based tube current modulation on CT-induced DNA double-strand breaks in a biological phantom model

Evaluation of an organ-based tube current modulation tool in pediatric CT examinations

Image quality and clinical usefulness of automatic tube current modulation technology in female chest computed tomography screening

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