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Background：Contrast dose and radiation dose reduction in computerized tomography （CT） scan for adult has been explored successfully,but there have been few studies on the application of low-concentration contrast in pediatric abdominal CT examinations.This was a feasibility study on the use of dual-energy spectral imaging and adaptive statistical iterative reconstruction （ASiR） for the reduction of radiation dose and iodine contrast dose in pediatric abdominal CT patients with solid tumors.Methods：Forty-five patients with solid tumors who had initial CT （Group B） and follow-up CT （Group A） after chemotherapy were enrolled.The initial diagnostic CT scan （Group B） was performed using the standard two-phase enhanced CT with 320 mgI/ml concentration contrast,and the follow-up scan （Group A） was performed using a single-phase enhanced CT at 45 s after the beginning of the 270 mgI/ml contrast injection using spectral mode.Forty percent ASiR was used for the images in Group B and monochromatic images with energy levels ≥60 keV in Group A.In addition,filtered back-projection （FBP） reconstruction was used for monochromatic images 〈60 keV in Group A.The total radiation dose,total iodine load,contrast injection speed,and maximum injection pressure were compared between the two groups.The 40 keV and 60 keV spectral CT images of Group A were compared with the images of Group B to evaluate overall image quality.Results：The total radiation dose,total iodine load,injection speed,and maximum injection pressure for Group A were decreased by 19%,15%,34.4%,and 18.3%,respectively.The optimal energy level in spectral CT for displaying the abdominal vessels was 40 keV.At this level,the CT values in the abdominal aorta and its three branches,the portal vein and its two branches,and the inferior vena cava were all greater than 340 hounsfield unit （HU）.The abdominal organs of Groups A and B had similar degrees of absolute and relative enhancement （t =0.36 and-1.716 for liver,0.153 and-1.546 for pancreas,and 2.427 and 0.866 for renal cortex,all P 〉 0.05）.Signal-to-noise ratio of the abdominal organs was significantly lower in Group A than in Group B （t =-8.11 for liver,-7.83 for pancreas,and-5.38 for renal cortex,all P 〈 0.05）.However,the subjective scores for the 40 keV （FBP） and 60 keV （40% ASiR） spectral CT images determined by two radiologists were all 〉3,indicating clinically acceptable image quality.Conclusions：Single-phase,dual-energy spectral CT used for children with solid abdominal tumors can reduce contrast dose and radiation dose and can also maintain clinically acceptable image quality.

The dose of bendamustine used to treat previously untreated follicular lymphoma (FL) is sometimes reduced based on various clinical considerations, but the impact of such dose reductions on outcomes is unclear. We retrospectively analyzed 92 untreated FL patients treated with bendamustine at seven institutions in Japan. Dose reduction was defined as receiving less than 90% of the planned total dose of 1080 mg/m2 over six cycles. Patients with disease progression observed at ≤ 180 days of treatment initiation were defined as primary bendamustine‐refractory (PBR). The 3‐year overall survival (OS) and progression‐free survival (PFS) were 87.1% and 71.8%, respectively. Seven patients were classified as PBR, six of whom received bendamustine at full dose without dose reduction, and they had significantly worse OS with 3‐year OS of 38.1%. We excluded the PBR cases from subsequent analyses of the dose intensity's prognostic significance. The dose‐reduction group had a significantly lower CR rate (93.0% vs. 74.4%, p = 0.032). Similarly, the 3‐year PFS was significantly worse in the dose‐reduction group (86.8% vs. 68.1%, p = 0.005). In univariate and multivariate analyses, dose reduction was associated with inferior PFS. In an analysis limited to patients who completed all six courses, the CR rate was comparable between the two groups, but 3‐year PFS was significantly worse in the dose‐reduction group (86.8% vs. 68.7%, p = 0.041). Furthermore, even among patients who achieved CR, the 3‐year PFS tended to be poorer in the dose‐reduction group (85.7% vs. 72.7%, p = 0.062). These findings suggest that PBR cases are resistant to bendamustine itself regardless of the dose intensity. In contrast, among responders including those who achieved CR, dose reduction was associated with poorer PFS, indicating that maintaining treatment intensity is important for improving prognosis in the treatment of bendamustine‐responsive FL patients.

In this study, we evaluated the improvement of image quality in digital breast tomosynthesis under low-radiation dose conditions of pre-reconstruction processing using conditional generative adversarial networks [cGAN (pix2pix)]. Pix2pix pre-reconstruction processing with filtered back projection (FBP) was compared with and without multiscale bilateral filtering (MSBF) during pre-reconstruction processing. Noise reduction and preserve contrast rates were compared using full width at half-maximum (FWHM), contrast-to-noise ratio (CNR), peak signal-to-noise ratio (PSNR), and structural similarity (SSIM) in the in-focus plane using a BR3D phantom at various radiation doses [reference-dose (automatic exposure control reference dose: AECrd), 50% and 75% reduction of AECrd] and phantom thicknesses (40 mm, 50 mm, and 60 mm). The overall performance of pix2pix pre-reconstruction processing was effective in terms of FWHM, PSNR, and SSIM. At ~50% radiation-dose reduction, FWHM yielded good results independently of the microcalcification size used in the BR3D phantom, and good noise reduction and preserved contrast. PSNR results showed that pix2pix pre-reconstruction processing represented the minimum in the error with reference FBP images at an approximately 50% reduction in radiation-dose. SSIM analysis indicated that pix2pix pre-reconstruction processing yielded superior similarity when compared with and without MSBF pre-reconstruction processing at ~50% radiation-dose reduction, with features most similar to the reference FBP images. Thus, pix2pix pre-reconstruction processing is promising for reducing noise with preserve contrast and radiation-dose reduction in clinical practice.

The use of diagnostic radiology in pediatric patients has increased, and various positive effects have been reported, including methods to reduce radiation doses in children. Research has been conducted to preserve image quality while reducing exposure and doses in pediatric patients. This study aimed to measure four different filters to identify an optimized filter for pediatric patients. The experiment was conducted using four types of filters, including aluminum, copper, molybdenum, and tungsten. The optimal filter thickness was verified using a histogram to visually evaluate the spectrum by filter thickness, effective dose on a pediatric phantom, entrance skin dose, organ absorbed dose using the PC-based Monte Carlo (PCXMC) program version 2.0 simulation, figure of merit (FOM), and image quality. As a result of measuring the spectrum according to the tube voltage and the four types of filters, dose reduction and contrast improvement effects were obtained with a 0.05 mm tungsten filter. Additionally, effective entrance skin and organ absorbed dose decreased with the said filter. The aluminum, copper, and molybdenum filters demonstrated that the effective dose scarcely decreased even when the thickness was increased; meanwhile, the effective dose decreased when the tungsten filter was 0.05 mm. The FOM with a 0.05 mm tungsten increased by 91% in the lung field and 39% in the mediastinal field. The entrance skin and organ absorbed dose in pediatric patients can be reduced by removing low-energy photons that fail in image formation using a tungsten filter.

The aim of this study was to investigate the potential of jaw tracking with the volumetric-modulated arc therapy (VMAT) to reduce the normal tissue dose. Plans of nasopharynx, lung, and prostate cancers (10 plans for each) were used to perform VMAT with and without jaw tracking. The dose reduction was evaluated in terms of organ doses and integral doses. Organ-dose reduction with jaw tracking was statistically significant in the volume receiving a dose of 5 Gy (V5) of bladder, rectum, and lung, the volume receiving a dose of 10 Gy (V10) of bladder, rectum, and lung, and the mean dose of lung (P < 0.05). Integral-dose reduction with jaw tracking was statistically significant in almost all the treatment plans (P < 0.05). For organ-dose reduction, jaw tracking in VMAT plan was effective in reducing V5and V10. For integral-dose reduction, jaw tracking in VMAT plan is an efficient method for decreasing V5.

A method for minimizing organ dose during computed tomography examinations is the use of shielding to protect superficial organs. There are some scientific reports that usage of shielding technique reduces the surface dose to patients with no appreciable loss in diagnostic quality. Therefore, in this Monte Carlo study based on the phantom of a 11-year-old Iranian boy, the effect of using an optimized shield on dose reduction to body organs was quantified. Based on the impact of shield on image quality, lead shields with thicknesses of 0.2 and 0.4 mm were considered for organs exposed directly and indirectly in the scan range, respectively. The results showed that there is 50%-62% reduction in amounts of dose for organs located fully or partly in the scan range at different tube voltages and modeling the true location of all organs in human anatomy, especially the ones located at the border of the scan, range affects the results up to 49%.

[This corrects the article DOI: 10.3389/fphar.2024.1369805.].

Background Organ-specific dose reduction significantly reduces the radiation exposure of radiosensitive organs. Objective The purpose of this study was to assess the impact of a novel organ-specific dose reduction algorithm on image quality of pediatric chest CT. Materials and methods We included 28 children (mean age 10.9 ± 4.8 years, range 3–18 years) who had contrast-enhanced chest CT on a 128-row scanner. CT was performed at 100 kV using automated tube current modulation and a novel organ-specific dose-reduction algorithm (XCare™; Siemens, Forchheim, Germany). Seven children had a previous chest CT performed on a 64-row scanner at 100 kV without organ-specific dose reduction. Subjective image quality was assessed using a five-point scale (1-not diagnostic; 5-excellent). Contrast-to-noise ratio (CNR) and signal-to-noise ratio (SNR) were assessed in the descending aorta. Results Overall mean subjective image quality was 4.1 ± 0.6. In the subgroup of the seven children examined both with and without organ-specific dose reduction, subjective image quality was comparable (score 4.4 ± 0.5 with organ-specific dose reduction vs. 4.4 ± 0.7 without it; P  > 0.05). There was no significant difference in mean signal-to-noise ratio and contrast-to-noise ratio with organ-specific dose reduction (38.3 ± 10.1 and 28.5 ± 8.7, respectively) and without the reduction (35.5 ± 8.5 and 26.5 ± 7.8, respectively) ( P  > 0.05). Volume computed tomography dose index (CTDI vol ) and size-specific dose estimates did not differ significantly between acquisitions with the organ-specific dose reduction (1.7 ± 0.8 mGy) and without the reduction (1.7 ± 0.8 mGy) ( P  > 0.05). Conclusion Organ-specific dose reduction does not have an impact on image quality of pediatric chest CT and can therefore be used in clinical practice to reduce radiation dose of radiosensitive organs such as breast and thyroid gland.

Since the turn of the last millennium, the pediatric radiology community has blazed a patient-quality and safety trail in helping to effectively address the public and the news media’s concerns about the implications of ionizing radiation from CT scanners in children. As such, this article (1) reviews the potential deleterious effects of ionizing radiation, (2) discusses why limiting radiation exposure in children is so important, (3) tells the history of pediatric CT radiation exposure concerns, (4) explains the interventions that took place to address these concerns and (5) touches on the current school of thought on pediatric CT dose reduction.

Objectives Photon-counting computed tomography has lately found its way into clinical routine. The new technique could offer substantial improvements regarding general image quality, image noise, and radiation dose reduction. This study evaluated the first abdominal examinations in clinical routine and compared the results to conventional computed tomography. Methods In this single-center retrospective study, 66 patients underwent photon-counting and conventional abdominal CT. Four radiologists assessed general image quality, image noise, and image artifacts. Signal-to-noise ratio and dose properties of both techniques within the clinical application were compared. An ex vivo phantom study revealed the radiobiological impact by means of DNA double-strand break foci in peripheral blood cells by enumerating γ-H2AX+53BP1 foci. Results General image quality in accordance with the Likert scale was found superior for photon-counting CT (4.74 ± 0.46 vs. 4.25 ± 0.54; p < 0.001). Signal-to-noise ratio ( p < 0.001) and also dose exposure were higher for photon-counting CT (DLP: 419.2 ± 162.2 vs. 372.3 ± 236.6 mGy*cm; p = 0.0435). CT exposure resulted in significantly increased DNA damage in comparison to sham control ( p < 0.001). Investigation of the average foci per cell and radiation-induced foci numbers revealed significantly elevated numbers ( p = 0.004 and p < 0.0001, respectively) after photon-counting CT. Conclusion Photon-counting CT in abdominal examinations showed superior results regarding general image quality and signal-to-noise ratio in clinical routine. However, this seems to be traded for a significantly higher dose exposure and corresponding double-strand break frequency. Optimization of standard protocols in further clinical applications is required to find a compromise regarding picture quality and dose exposure. Key Points • Photon-counting computed tomography promises to enhance the diagnostic potential of medical imaging in clinical routine. • Retrospective single-center study showed superior general image quality accompanied by higher dose exposure in initial abdominal PCCT protocols compared to state-of-the-art conventional CT. • A simultaneous ex vivo phantom study revealed correspondingly increased frequencies of DNA double-strand breaks after PCCT.