Mini Endoscopic Combined Intra-Renal Surgery (MiniECIRS) with endoview puncture in A 12 month boy. A safe but challenging procedure.

INTRODUCTION: Associating minipercutaneous nephrolithotomy and retrograde flexible ureteroscopy (fURS) is called Mini Endoscopic Combined Intra-Renal Surgery (miniECIRS). It's a safe and efficient technique, also in children. MATERIAL AND METHODS: The video describes miniECIRS in a 12 month-old boy with an infectious pelvic left stone (16 mm) and multiple caliceal stones. The UAS used was a 10FR and the percutaneous access was a 14Fr with Clear-Petra® sheath. RESULTS: The operative time was 180 min and blood losses were virtually absent. There were no intra- or post-operative complications and the patient was discharged at the 5th day. After 1 month, double J was removed having a stone free status. CONCLUSIONS: MiniECIRS with endoview puncture is a safe and efficient technique when performed by experienced hands. Therefore, it is an alternative to consider for the treatment of complex lithiasis in the pediatric population.

If you can make it, you can share it - Perspectives on the first DIY-fair at the European congress of medical physics (ECMP, DUBLIN 2022).

The medical physics and engineering community is known for being active in conjuring do-it-yourself (DIY) -solutions to support their clinical and research work. To facilitate the exchange of solutions and ideas, a DIY-fair was held for the first time at the European Congress of Medical Physics (ECMP) in August 2022 in Dublin, Ireland. Altogether 32 contributions were presented, consisting of software, scripts, 3D-printed customized solutions, devices, gadgets and phantoms. All contributions were published in video format on a dedicated YouTube channel, and most were also presented in person at the conference. The fair demonstrated that there is an unmet need for sharing and distributing information on self-created solutions in the medical physics community. The authors propose the creation of a dedicated platform for sharing such content within our community, as well as a continuity of DIY-fairs at future ECMP meetings.

Automated quantification of the pulmonary vasculature in pulmonary embolism and chronic thromboembolic pulmonary hypertension.

The shape and distribution of vascular lesions in pulmonary embolism (PE) and chronic thromboembolic pulmonary hypertension (CTEPH) are different. We investigated whether automated quantification of pulmonary vascular morphology and densitometry in arteries and veins imaged by computed tomographic pulmonary angiography (CTPA) could distinguish PE from CTEPH. We analyzed CTPA images from a cohort of 16 PE patients, 6 CTEPH patients, and 15 controls. Pulmonary vessels were extracted with a graph-cut method, and separated into arteries and veins using deep-learning classification. Vascular morphology was quantified by the slope (α) and intercept (ß) of the vessel radii distribution. To quantify lung perfusion defects, the median pulmonary vascular density was calculated. By combining these measurements with densities measured in parenchymal areas, pulmonary trunk, and descending aorta, a static perfusion curve was constructed. All separate quantifications were compared between the three groups. No vascular morphology differences were detected in contrast to vascular density values. The median vascular density (interquartile range) was -567 (113), -452 (95), and -470 (323) HU, for the control, PE, and CTEPH group. The static perfusion curves showed different patterns between groups, with a statistically significant difference in aorta-pulmonary trunk gradient between the PE and CTEPH groups (p = 0.008). In this proof of concept study, not vasculature morphology but densities differentiated between patients of three groups. Further technical improvements are needed to allow for accurate differentiation between PE and CTEPH, which in this study was only possible statistically by measuring the density gradient between aorta and pulmonary trunk.

New Generation Pulse Modulation in Holmium:YAG Lasers: A Systematic Review of the Literature and Meta-Analysis.

(1) Background: New pulse modulation (PM) technologies in Holmium:YAG lasers are available for urinary stone treatment, but little is known about them. We aim to systematically evaluate the published evidence in terms of their lithotripsy performance. (2) Methods: A systematic electronic search was performed (MEDLINE, Scopus, and Cochrane databases). We included all relevant publications, including randomized controlled trials, non-randomized comparative and non-comparative studies, and in-vitro studies investigating Holmium:YAG lithotripsy performance employing any new PM. (3) Results: Initial search yielded 203 studies; 24 studies were included after selection: 15 in-vitro, 9 in-vivo. 10 In-vitro compared Moses with regular PM, 1 compared Quanta's, 1 Dornier MedTech's, 2 Moses with super Thulium Fiber Laser, and 1 compared Moses with Quanta PMs. Six out of seven comparative studies found a statistically significant difference in favor of new-generation PM technologies in terms of operative time and five out of six in fragmentation time; two studies evaluated retropulsion, both in favor of new-generation PM. There were no statistically significant differences regarding stone-free rate, lasing and operative time, and complications between Moses and regular PM when data were meta-analyzed. (4) Conclusions: Moses PM seems to have better lithotripsy performance than regular modes in in-vitro studies, but there are still some doubts about its in-vivo results. Little is known about the other PMs. Although some results favor Quanta PMs, further studies are needed.

Design and evaluation of a modular multimodality imaging phantom to simulate heterogeneous uptake and enhancement patterns for radiomic quantification in hybrid imaging: A feasibility study.

BACKGROUND: Accuracy and precision assessment in radiomic features is important for the determination of their potential to characterize cancer lesions. In this regard, simulation of different imaging conditions using specialized phantoms is increasingly being investigated. In this study, the design and evaluation of a modular multimodality imaging phantom to simulate heterogeneous uptake and enhancement patterns for radiomics quantification in hybrid imaging is presented. METHODS: A modular multimodality imaging phantom was constructed that could simulate different patterns of heterogeneous uptake and enhancement patterns in positron emission tomography (PET), single-photon emission computed tomography (SPECT), computed tomography (CT), and magnetic resonance (MR) imaging. The phantom was designed to be used as an insert in the standard NEMA-NU2 IEC body phantom casing. The entire phantom insert is composed of three segments, each containing three separately fillable compartments. The fillable compartments between segments had different sizes in order to simulate heterogeneous patterns at different spatial scales. The compartments were separately filled with different ratios of 99m Tc-pertechnetate, 18 F-fluorodeoxyglucose ([18 F]FDG), iodine- and gadolinium-based contrast agents for SPECT, PET, CT, and T1 -weighted MR imaging respectively. Image acquisition was performed using standard oncological protocols on all modalities and repeated five times for repeatability assessment. A total of 93 radiomic features were calculated. Variability was assessed by determining the coefficient of quartile variation (CQV) of the features. Comparison of feature repeatability at different modalities and spatial scales was performed using Kruskal-Wallis-, Mann-Whitney U-, one-way ANOVA- and independent t-tests. RESULTS: Heterogeneous uptake and enhancement could be simulated on all four imaging modalities. Radiomic features in SPECT were significantly less stable than in all other modalities. Features in PET were significantly less stable than in MR and CT. A total of 20 features, particularly in the gray-level co-occurrence matrix (GLCM) and gray-level run-length matrix (GLRLM) class, were found to be relatively stable in all four modalities for all three spatial scales of heterogeneous patterns (with CQV < 10%). CONCLUSION: The phantom was suitable for simulating heterogeneous uptake and enhancement patterns in [18 F]FDG-PET, 99m Tc-SPECT, CT, and T1 -weighted MR images. The results of this work indicate that the phantom might be useful for the further development and optimization of imaging protocols for radiomic quantification in hybrid imaging modalities.

[Confocal laser endomicroscopy for the treatment of upper urinary tract transitional cellcarcinoma.] / Endomicroscopía láser confocal en el tratamiento del tumor urotelial del tracto urinario superior.

OBJECTIVES: Confocal lasser endomicroscopy (CLE) is an optical technique that enables in vivo cytological characterization of a tissue. Previous studies have shown it useful in the evaluation of urinary and respiratory tracts for a better characterization of mucosal lesions, showing a high concordance between in vivo and final histopathological results. Recently, the use of CLE has been proposed for the study of transitional cell carcinoma of the upper urinary tract (UUT) during ureteroscopy, because it enables real time information about tumor grade and supplements the information of ureteroscopic biopsies, which may understimate the grade and stage of the lesion up to 43% of the cases due to its limitiations. METHODS: We performed a systematic review of the literature in the Pubmed/Medline database following the PRISMA standard. We selected 20 articles that complied with the inclusion criteria for evidence synthesis. RESULTS: Equipment miniaturization has enabled CLE as part of the diagnostic options in upper urinary tract tumors. This technique performs in vivo cytological characterization of the evaluated tissue, accomplishing differentiation between tumor and normal tissue, as well as tumor grade identification. Its communicated sensitivity and specificity reach 79%/78% respectively for low grade tumors and 67%/79% for high grade, with a substantial inter observer concordance (surgeon/pathologist; k = 0.64). No complications have been communicated in the literature with the use of fluorescein or confocal laser microscopy probes in patients undergoing this technique. CONCLUSIONS: CLE represents a useful and safe tool, capable of providing cytological real time information of UUT tumors that enables tumor grade identification with substantial concordance between in vivo tumor typifying and the final histopathological analysis. For this, CLE is currently considered a tool for conservative management of UUT transitional cell carcinoma in the European Association of Urology (EAU) guidelines.

OBJETIVOS: La endomicroscopía láser confocal (CLE) es una técnica óptica que permite la caracterización citológica en vivo de un tejido. Estudios previos en lesiones del tracto digestivo y respiratorio han mostrado una alta concordancia entre el resultado en vivo y el resultado histopatológico. Recientemente, se ha propuesto el uso de la CLE en el estudio del tracto urinario superior (TUS) durante la ureteroscopia, ya que permite obtener información a tiempo real del grado tumoral y complementa la información de las biopsias ureteroscópicas, que dadas sus limitaciones, pueden infraestimar el grado y el estadío de la lesión hasta en un 43% de los casos.MÉTODOS: Se llevó a cabo una revisión de la literatura en la base de datos Pubmed/Medline siguiendo las normas PRISMA. Se utilizaron 21 artículos que cumplieron los criterios de inclusión para la síntesis de la evidencia. RESULTADOS: La sensibilidad y especificidad descrita, alcanza el 79%/78% y 67%/79% para tumores de bajo y alto grado respectivamente, con una concordancia sustancial entre observadores (cirujano/anatomopatólogo; K = 0,64). No se han reportado complicaciones asociadas a la utilización de la fluoresceína ni sondas de CLE. CONCLUSIONES: La CLE representa una herramienta útil y segura, capaz de proporcionar información citológica de tumores del TUS en tiempo real que permite la identificación del grado tumoral con sustancial grado de acuerdo entre la tipificación en vivo y su análisis histopatológico final. Por este motivo, actualmente, la CLE es considerada como una herramienta en el manejo conservador del carcinoma del TUS en las guidelines de la European Association of Urology (EAU).

Endomicroscopía láser confocal en el tratamiento del tumor urotelial del tracto urinario superior / Confocal laser endomicroscopy for the treatment of upper urinary tract transitional cellcarcinoma

Objetivos: La endomicroscopía láser confocal (CLE) es una técnica óptica que permite la caracterización citológica en vivo de un tejido. Estudios previos en lesiones del tracto digestivo y respiratorio han mostrado una alta concordancia entre el resultado en vivo y el resultado histopatológico. Recientemente, se ha propuesto el uso de la CLE en el estudio del tracto urinario superior (TUS) durante la ureteroscopia, ya que permite obtener información a tiempo real del grado tumoral y complementa la información de las biopsias ureteroscópicas, que dadas sus limitaciones, pueden infraestimar el grado y el estadío de la lesión hasta en un 43% de los casos. Métodos: Se llevó a cabo una revisión de la literatura en la base de datos Pubmed/Medline siguiendo las normas Prisma. Se utilizaron 21 artículos que cumplieron los criterios de inclusión para la síntesis de la evidencia. Resultados: La sensibilidad y especificidad descrita, alcanza el 79%/78% y 67%/79% para tumores de bajo y alto grado respectivamente, con una concordancia sustancial entre observadores cirujano/anatomopatólogo; K=0,64). No se han reportado complicaciones asociadas a la utilización de la fluoresceína ni sondas de CLE. Conclusiones: La CLE representa una herramienta útil y segura, capaz de proporcionar información citológica de tumores del TUS en tiempo real que permitela identificación del grado tumoral con sustancial grado de acuerdo entre la tipificación en vivo y su análisis histopatológico final. Por este motivo, actualmente, la CLE es considerada como una herramienta en el manejo conservador del carcinoma del TUS en las guidelines de la European Association of Urology (EAU)

Objectives: Confocal lasser endomicroscopy (CLE) is an optical technique that enables in vivo cytological characterization of a tissue. Previous studies have shown it useful in the evaluation of urinary and respiratory tracts for a better characterization of mucosal lesions, showing a high concordance between in vivo and final histopathological results. Recently, the use of CLE has been proposed for the study of transitional cell carcinoma of the upper urinary tract (UUT) during ureteroscopy, because it enables real time information about tumor grade and supplements the information of ureteroscopic biopsies, which may understimate the grade and stage of the lesion up to 43% of the cases due to its limitiations. Methods: We performed a systematic review of the literature in the Pubmed/Medline database following the PRISMA standard. We selected 20 articles that complied with the inclusion criteria for evidence synthesis. Results: Equipment miniaturization has enabled CLE as part of the diagnostic options in upper urinary tract tumors. This technique performs in vivo cytological characterization of the evaluated tissue, accomplishing differentiation between tumor and normal tissue, as well as tumor grade identification. Its communicated sensitivity and specificity reach 79%/78% respectively for low grade tumors and 67%/79% for high grade, with a substantial inter observer concordance (surgeon/pathologist;k=0.64). No complications have been communicated in the literature with the use of fluorescein or confocal laser microscopy probes in patients undergoing this technique. CONCLUSIONS: CLE represents a useful and safe tool, capable of providing cytological real time information of UUT tumors that enables tumor grade identification with substantial concordance between in vivo tumor typifying and the final histopathological analysis. For this, CLE is currently considered a tool for conservative management of UUT transitional cell carcinoma in the European Association of Urology (EAU) guidelines

Automatic quantitative analysis of pulmonary vascular morphology in CT images.

PURPOSE: Vascular remodeling is a significant pathological feature of various pulmonary diseases, which may be assessed by quantitative computed tomography (CT) imaging. The purpose of this study was therefore to develop and validate an automatic method for quantifying pulmonary vascular morphology in CT images. METHODS: The proposed method consists of pulmonary vessel extraction and quantification. For extracting pulmonary vessels, a graph-cuts-based method is proposed which considers appearance (CT intensity) and shape (vesselness from a Hessian-based filter) features, and incorporates distance to the airways into the cost function to prevent false detection of airway walls. For quantifying the extracted pulmonary vessels, a radius histogram is generated by counting the occurrence of vessel radii, calculated from a distance transform-based method. Subsequently, two biomarkers, slope α and intercept ß, are calculated by linear regression on the radius histogram. A public data set from the VESSEL12 challenge was used to independently evaluate the vessel extraction. The quantitative analysis method was validated using images of a three-dimensional (3D) printed vessel phantom, scanned by a clinical CT scanner and a micro-CT scanner (to obtain a gold standard). To confirm the association between imaging biomarkers and pulmonary function, 77 scleroderma patients were investigated with the proposed method. RESULTS: In the independent evaluation with the public data set, our vessel segmentation method obtained an area under the receiver operating characteristic (ROC) curve of 0.976. The median radius difference between clinical and micro-CT scans of a 3D printed vessel phantom was 0.062 ± 0.020 mm, with interquartile range of 0.199 ± 0.050 mm. In the studied patient group, a significant correlation between diffusion capacity for carbon monoxide and the biomarkers, α (R = -0.27, P = 0.018) and ß (R = 0.321, P = 0.004), was obtained. CONCLUSION: In conclusion, the proposed method was validated independently using a public data set resulting in an area under the ROC curve of 0.976 and using a 3D printed vessel phantom data set, showing a vessel sizing error of 0.062 mm (0.16 in-plane pixel units). The correlation between imaging biomarkers and diffusion capacity in a clinical data set confirmed an association between lung structure and function. This quantification of pulmonary vascular morphology may be helpful in understanding the pathophysiology of pulmonary vascular diseases.

Added Value of Ultra-low-dose Computed Tomography, Dose Equivalent to Chest X-Ray Radiography, for Diagnosing Chest Pathology.

PURPOSE: The purpose of this study was to assess the clinical value of ultra-low-dose computed tomography (ULDCT) compared with chest x-ray radiography (CXR) for diagnosing chest pathology. MATERIALS AND METHODS: A total of 200 patients referred for CXR by outpatient clinics or general practitioners were enrolled prospectively. They underwent CXR (posteroanterior and lateral) and ULDCT (120 kV, 3 mAs) on the same day. In-room time and effective dose were recorded for each examination. Studies were categorized whether they were diagnostic or not, relevant radiologic diagnostic findings were reported, and confidence for diagnosis was recorded by a Likert scale. Differences in diagnostic confidence and effect on management decision were compared. RESULTS: In-room time was <2 minutes for CXR and <3 minutes for ULDCT. Effective dose was 0.040 mSv for CXR and 0.071 mSv for ULDCT. CXR was considered diagnostic in 98% and ULDCT in 100%. The mean perceived confidence for diagnosis was 88±12% with CXR and 98±2% with ULDCT (P<0.0001), whereas discrepant findings between CXR and ULDCT were found in 101 of 200 patients. As compared with CXR, ULDCT had added value for management decisions in 40 of 200 patients. CONCLUSIONS: ULDCT provided added value to the radiologist by improved perceived confidence with a reduction in false-positive and false-negative CXR investigations that had management implications in 20% of patients. The effective dose of ULDCT will not be a limiting factor for introducing ULDCT of the chest on a broad scale in clinical practice.

Development of a 3D printed anthropomorphic lung phantom for image quality assessment in CT.

PURPOSE: To design a 3D printed anthropomorphic lung vessel phantom for CT image quality assessment and to evaluate the phantom image and dose characteristics. METHODS: An in-house algorithm generated a vessel tree model, based on human lungs anatomy, which was 3D printed using a multi jet modeling printer (0.25 mm ≤ vessel diameters ≤ 8.25 mm) and inserted in an elliptical holder (thorax surrogate). The phantom was scanned (Toshiba Aquilion Genesis CT) and compared in terms of attenuation (Hounsfield units, HU) and dose characteristics with studies of five patients (normal BMI) and a commercial torso phantom, performed with the same thorax protocol. The pixel value distribution in the lung area was assessed with histograms. To investigate the adjustment of tube current modulation, tube load and CTDI were compared. RESULTS: The histogram peaks for respectively vessels and surrounding tissue were at 105 HU and -985 HU (3D printed phantom), at -25 HU and -1000 HU (torso phantom) and at 25 HU and -875 HU (average patient). The contrast between vessels and surrounding was -1090 HU (3D printed), -975 HU (torso phantom), and -900 HU (average patient). The measured HU values (soft tissue and vertebra) were (32 ±â€¯15) HU and (210 ±â€¯71) HU (average patient); (4 ±â€¯4) HU, (390 ±â€¯39) HU (torso phantom) and (119 ±â€¯5) HU, (951 ±â€¯31) HU (3D printed phantom and holder). CTDIvol was (1.9 ±â€¯4.7 mGy) for patients, 1.9 mGy for the torso phantom and 2.1 mGy for the 3D printed lung phantom. CONCLUSIONS: An anthropomorphic 3D printed lung phantom was developed and its CT image and dose characteristics evaluated. The phantom has the potential to provide clinically relevant and reproducible measures of CT image quality.

Inter-laboratory comparison of channelized hotelling observer computation.

PURPOSE: The task-based assessment of image quality using model observers is increasingly used for the assessment of different imaging modalities. However, the performance computation of model observers needs standardization as well as a well-established trust in its implementation methodology and uncertainty estimation. The purpose of this work was to determine the degree of equivalence of the channelized Hotelling observer performance and uncertainty estimation using an intercomparison exercise. MATERIALS AND METHODS: Image samples to estimate model observer performance for detection tasks were generated from two-dimensional CT image slices of a uniform water phantom. A common set of images was sent to participating laboratories to perform and document the following tasks: (a) estimate the detectability index of a well-defined CHO and its uncertainty in three conditions involving different sized targets all at the same dose, and (b) apply this CHO to an image set where ground truth was unknown to participants (lower image dose). In addition, and on an optional basis, we asked the participating laboratories to (c) estimate the performance of real human observers from a psychophysical experiment of their choice. Each of the 13 participating laboratories was confidentially assigned a participant number and image sets could be downloaded through a secure server. Results were distributed with each participant recognizable by its number and then each laboratory was able to modify their results with justification as model observer calculation are not yet a routine and potentially error prone. RESULTS: Detectability index increased with signal size for all participants and was very consistent for 6 mm sized target while showing higher variability for 8 and 10 mm sized target. There was one order of magnitude between the lowest and the largest uncertainty estimation. CONCLUSIONS: This intercomparison helped define the state of the art of model observer performance computation and with thirteen participants, reflects openness and trust within the medical imaging community. The performance of a CHO with explicitly defined channels and a relatively large number of test images was consistently estimated by all participants. In contrast, the paper demonstrates that there is no agreement on estimating the variance of detectability in the training and testing setting.

Quality control in cone-beam computed tomography (CBCT) EFOMP-ESTRO-IAEA protocol (summary report).

The aim of the guideline presented in this article is to unify the test parameters for image quality evaluation and radiation output in all types of cone-beam computed tomography (CBCT) systems. The applications of CBCT spread over dental and interventional radiology, guided surgery and radiotherapy. The chosen tests provide the means to objectively evaluate the performance and monitor the constancy of the imaging chain. Experience from all involved associations has been collected to achieve a consensus that is rigorous and helpful for the practice. The guideline recommends to assess image quality in terms of uniformity, geometrical precision, voxel density values (or Hounsfield units where available), noise, low contrast resolution and spatial resolution measurements. These tests usually require the use of a phantom and evaluation software. Radiation output can be determined with a kerma-area product meter attached to the tube case. Alternatively, a solid state dosimeter attached to the flat panel and a simple geometric relationship can be used to calculate the dose to the isocentre. Summary tables including action levels and recommended frequencies for each test, as well as relevant references, are provided. If the radiation output or image quality deviates from expected values, or exceeds documented action levels for a given system, a more in depth system analysis (using conventional tests) and corrective maintenance work may be required.

A Monte Carlo simulation for the estimation of patient dose in rest and stress cardiac computed tomography with a 320-detector row CT scanner.

PURPOSE: To estimate organ dose and effective dose for patients for cardiac CT as applied in an international multicenter study (CORE320) with a 320-Detector row CT scanner using Monte Carlo (MC) simulations and voxelized phantoms. The effect of positioning of the arms, off-centering the patient and heart rate on patient dose was analyzed. METHODS: A MC code was tailored to simulate the geometry and characteristics of the CT scanner. The phantoms representing the adult reference male and female were implemented according to ICRP 110. Effective dose and organ doses were obtained for CT acquisition protocols for calcium scoring, coronary angiography and myocardial perfusion. RESULTS: For low heart rate, the normalized effective dose (E) for cardiac CT was higher for female (5.6 mSv/100 mAs) compared to male (2.2 mSv/100 mAs) due to the contribution of female breast tissue. Averaged E for female and male was 11.3 mSv for the comprehensive cardiac protocol consisting of calcium scoring (1.9 mSv); coronary angiography including rest cardiac perfusion (5.1 mSv) and stress cardiac perfusion (4.3 mSv). These values almost doubled at higher heart rates (20.1 mSv). Excluding the arms increased effective dose by 6-8%, centering the patient showed no significant effect. The k-factor (0.028 mSv/mGy.cm) derived from this study leads to effective doses up to 2-3 times higher than the values obtained using now outdated methodologies. CONCLUSION: MC modeling of cardiac CT examinations on realistic voxelized phantoms allowed us to assess patient doses accurately and we derived k-factors that are well above those published previously.

Adaptive iterative dose reduction 3D versus filtered back projection in CT: evaluation of image quality.

OBJECTIVE: The purpose of this study was to evaluate image quality with filtered back projection (FBP) and adaptive iterative dose reduction 3D (AIDR 3D). MATERIALS AND METHODS: Phantom acquisitions were performed at six dose levels to assess spatial resolution, noise, and low-contrast detectability (LCD). Spatial resolution was assessed with the modulation transfer function at high and low contrast levels. Noise power spectrum and SD of attenuation were assessed. LCD was calculated with a mathematic model observer applied to phantom CT images. The subjective image quality of clinical CT scans was assessed by five radiologists. RESULTS: Compared with FBP, AIDR 3D resulted in substantial noise reduction at all frequencies with a similar shape of the noise power spectrum. Spatial resolution was similar for AIDR 3D and FBP. LCD improved with AIDR 3D, which was associated with a potential average dose reduction of 36% (range, 9-86%). The observer study showed that overall image quality improved and artifacts decreased with AIDR 3D. CONCLUSION: AIDR 3D performs better than FBP with regard to noise and LCD, resulting in better image quality, and performs similarly with respect to spatial resolution. The evaluation of image quality of clinical CT scans was consistent with the objective assessment of image quality with a phantom. The amount of dose reduction should be investigated for each clinical indication in studies with larger numbers of patients.