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Radiation dose reduction and image quality in pediatric abdominal CT with kVp and mAs modulation and an iterative reconstruction technique
Radiation dose reduction and image quality in pediatric abdominal CT with kVp and mAs modulation and an iterative reconstruction technique Jun-Hwee Kim, Myung-Joon Kim, Ha Yan Kim, Mi-Jung Lee PII: DOI: Reference:
S0899-7071(14)00143-0 doi: 10.1016/j.clinimag.2014.05.008 JCT 7630
To appear in:
Journal of Clinical Imaging
Received date: Revised date: Accepted date:
16 January 2014 15 May 2014 19 May 2014
Please cite this article as: Kim Jun-Hwee, Kim Myung-Joon, Kim Ha Yan, Lee Mi-Jung, Radiation dose reduction and image quality in pediatric abdominal CT with kVp and mAs modulation and an iterative reconstruction technique, Journal of Clinical Imaging (2014), doi: 10.1016/j.clinimag.2014.05.008
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ACCEPTED MANUSCRIPT Radiation dose reduction and image quality in pediatric abdominal CT with kVp and
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mAs modulation and an iterative reconstruction technique
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Jun-Hwee Kim, M.D.1, Myung-Joon Kim, M.D., Ph.D.1, Ha Yan Kim, M.S.2, Mi-Jung Lee, M.D., Ph.D.1
of Radiology and Research Institute of Radiological Science, Severance
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1Department
Children's Hospital, Yonsei University College of Medicine, Seoul, Korea Collaboration Unit, Yonsei University, Severance Hospital
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2Biostatistics
Abbreviated title: SAFIRE in pediatric abdominal CT Corresponding author: Mi-Jung Lee, M.D., Ph.D.
Department of Radiology and Research Institute of Radiological Science Severance Children’s Hospital, Yonsei University College of Medicine
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50-1, Yonsei-ro, Seodaemun-gu, 120-752 Seoul, Korea
FAX: 82-2-393-3035
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TEL: 82-2- 2228-7400
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E-mail: [email protected]
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ACCEPTED MANUSCRIPT Abstract Objective: The objective of this study was to compare the radiation dose and image quality of
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pediatric abdominal CT using a protocol reconstructed with filtered back projection (FBP)
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and a protocol with both kVp and mAs modulation and sinogram–affirmed iterative reconstruction (SAFIRE).
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Materials and methods: We retrospectively reviewed pediatric abdominal CT examinations
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performed with both kVp and mAs modulation. These raw data were reconstructed with SAFIRE at different strengths from 2 to 4 (SAFIRE group 2-4). Another set of age/sexmatched pediatric abdominal CT examinations were also reviewed, which were performed during the same period with only mAs modulation and FBP (control group). The radiation
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dose and image quality were compared between groups. The image quality was objectively evaluated as the noise measured in the liver, aorta, and spleen at the level of the main portal
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vein and the image quality was subjectively reviewed by two radiologists for diagnostic
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acceptability using a four-point scale (0: unacceptable; 1: worse than the control group, but acceptable; 2: comparable with the control group; and 3: better than the control group). An
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independent t-test was used in order to compare the radiation dose. An independent t-test with Bonferroni correction and generalized estimating equations were used for the comparison of the objective and subjective image quality, respectively. Results: Twenty-nine patients (M:F = 19:10, mean age 10.0) were enrolled in each group. The SAFIRE group, using the size-specific dose estimates calculation method showed a 64.2% radiation dose reduction (from 8.1 to 2.9 mGy, p<0.05), compared with the results of the control group. The objective image noise of the SAFIRE groups 2 and 3 was comparable to that of the control group. The subjective image quality was the best in SAFIRE group 3 (odds ratio [OR] 3.015, p<0.001 when comparing to SAFIRE group 0; and OR 1.513, p<0.001 2
ACCEPTED MANUSCRIPT when comparing to SAFIRE group 2). Conclusions: Image acquisition with both kVp and mAs modulation and iterative
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reconstruction using SAFIRE with strength 3 can preserve the objective and subjective image
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quality of pediatric abdominal CT scans with less than half the radiation dose.
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Index Terms: Pediatric, Computed tomography, Radiation dose, Iterative reconstruction
Introduction
There are increased concerns about radiation exposure from computed tomography (CT)
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especially in pediatric patients [1, 2]. It is well known that children are more susceptible to
of malignancy [3].
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radiation than adults, because of their rapid cellular proliferation and increased lifetime risk
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One of the best methods for reducing radiation exposure is avoiding unnecessary CT evaluation and minimizing multi-phase scanning. However, CT is still a useful diagnostic tool
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in children when considering its non-invasiveness and accuracy with short acquisition time. In addition, recent advances in CT technology have suggested several methods for reducing radiation exposure. The automated modulation of tube voltage and current according to a patient’s body size has been suggested as one of the radiation dose reduction methods [4, 5]. However, lowering the tube voltage and current may increase the image noise, thus lowering the image quality and diagnostic accuracy [2]. Recently, several iterative reconstruction techniques have been suggested as post image acquisition processing methods to decrease the image noise in low-dose CT scans [6, 7]. These techniques can enhance the image quality by decreasing the image noise by the 3
ACCEPTED MANUSCRIPT introduction of multiple correction loops into the reconstruction process. One of these techniques is sinogram-affirmed iterative reconstruction (SAFIRE). This technique utilizes
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both projection space data and image space data with two different correction loops. The
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corrected image is compared to the original with a number of iterations in each space dependent on the needs of a specific scan. Thanks to advanced hardware and software, these
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complicated imaging processes can be handled faster and easier nowadays and we can use
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these clinically.
There have been many recent studies using variable iterative reconstruction techniques. However, a majority of these studies have been performed in adults and little is known about these techniques in children even though radiation dose reduction has greater clinical
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importance in children. In this study, we retrospectively compared the radiation dose and image quality in pediatric abdominal CT scans using a protocol with only mAs modulation
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and reconstruction with filtered back projection (FBP) and a protocol with both kVp and mAs
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modulation and reconstruction with SAFIRE.
Materials and Methods Patient selection This single-center retrospective study was approved by our hospital institutional review board and informed consent was waived. We retrospectively reviewed abdominal CT images performed in pediatric patients with a protocol using both tube current and voltage modulation and iterative reconstruction using SAFIRE (SAFIRE group) in our hospital from January to February 2012. Other age/sex-matched pediatric abdominal CT examinations were also reviewed which were performed during the same time period with a protocol using only 4
ACCEPTED MANUSCRIPT tube current modulation and FBP reconstruction (control group) in the emergency room. Only
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Scanning technique and radiation dose measurements
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single phase (portal venous phase) examinations were included in this study.
Our hospital has a 64 channel CT scanner (Sensation 64; Siemens Healthcare, Forchheim,
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Germany) with only the tube current modulation program (CARE Dose4D) and no iterative
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reconstruction in the emergency room. This tube current modulation program automatically adapts radiation dose to the size and shape of the patient based on the topogram, defined reference setting, and real-time angular dose modulation. For the reference setting, this technique uses the term of a quality reference mAs as a defined value that we would use for a
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standard sized adult patient weighing 75 kg. We used a quality reference mAs of 100mAs for abdominal CT in children. We scanned pediatric abdominal CTs with 80 kVp for children less
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than 10 kg, 100 kVp for children between 10-40 kg, and 120 kVp for children more than 40
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kg according to body weight. The acquisition parameters were 64 x 0.6-mm detector collimation, 1.4 pitch factor, and 0.33-sec gantry rotation. The slice thickness and increment
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were 2 mm each.
Our hospital also has a dual source CT scanner (Somatom Definition Flash; Siemens Healthcare), which has automated tube voltage and current modulation program (CARE kV and CARE Dose4D; Siemens Healthcare), and the iterative reconstruction program named SAFIRE (Siemens Healthcare). The tube voltage modulation program uses information gathered by the topogram and automatically recommends the optimally low tube voltage for the entire length of the scan while keeping the contrast-to-noise ratio. A single tube voltage (kV) is selected for each exam. It also uses a reference value as a quality reference kV set for a standard patient of 75 kg. We have used an abdominal CT protocol with a quality reference 5
ACCEPTED MANUSCRIPT kV of 100 kVp and a quality reference mAs of 100mAs for children since January 2012. The acquisition parameters were 64 x 0.6-mm detector collimation, 1.4 pitch factor, and 0.28-sec
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standard soft tissue kernel (B30f) for image reconstruction.
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gantry rotation. The slice thickness and increment were 2 mm each. Both CT scanners used
The protocols of the contrast media injection and patient preparation were the same when
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performing these two CT examinations. The abdominal CT scans were performed with
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300mg iodine/ml concentration intravenous contrast iobitridol (Xenetix, Laboratories Guerbet, Roissy, France). For contrast enhancement, 2 ml/kg of contrast was injected through an upper extremity peripheral intravenous line followed by a saline chaser of 0.5 ml/kg. The scanning was performed 40 seconds after enhancement in the abdominal aorta reached 100
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Hounsfield units (HU) for the portal venous phase only.
The volume CT dose indices (CTDIvol) and dose length product (DLP) values were recorded
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on the dose page for each of the studies. We multiplied the CTDIvol values by the conversion
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factors for size-specific dose estimates (SSDE) for the pediatric patients according to the
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American Association of Physicists in Medicine Report 204 [8].
Iterative reconstruction The SAFIRE iteration strength can be changed according to the strength of the noise reduction. The iteration strength can be ordered with an integral scale of 1 to 5, with 1 being the weakest and 5 being the strongest iteration strength. Two pediatric radiologists (M.J.K. and M.J.L.) with more than 30 and 10 years of experience with pediatric abdominal CT preliminarily reviewed several images with all 1 to 5 SAFIRE strengths and subjectively determined that images with SAFIRE strengths of 1 and 5 are too noisy or too smooth, respectively. Therefore, we selected only SAFIRE strengths 2, 3, and 4 for the analyses 6
ACCEPTED MANUSCRIPT (SAFIRE groups 2-4).
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Objective and subjective image quality analysis
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We reviewed each study of the control group and the SAFIRE groups 2-4 using the picture archiving and communication systems of our institution (Centricity Radiology RA1000, GE
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Medical Systems, Milwaukee, WI). For quantitative image quality analysis, we obtained
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noise measurements for each study. A single circular region of interest (ROI) that measured at least 3cm2 was drawn in the homogenous regions of the right hepatic lobe, abdominal aorta, and spleen at the level of the main portal vein. We measured the noise using standard deviations (SDs) of the attenuation value of the ROI [9].
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For subjective image quality analysis, two radiologists (M.J.L. and J.H.K.) with 10 and 4 years of experience with pediatric abdominal CT reviewed all images in the study of each
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patient directly and randomly without technical or personal medical information. We used the
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standard soft tissue window settings (400HU of window width and 40HU of window level) and carefully checked the anatomic structures of the abdominal organs and vessels as
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previously suggested [10]. Each radiologist independently graded each study of the raw data from the dose modulation protocol without SAFIRE (SAFIRE group 0) and with SAFIRE strengths 2, 3, and 4 (SAFIRE groups 2-4) for diagnostic acceptability using a four-point scale in comparison with the age/sex-matched control group. Grade 0 was unacceptable; grade 1 was worse than the control group, but acceptable; grade 2 was comparable with the control group; and grade 3 was better than the control group. We reviewed the images of each SAFIRE group from one patient together in one monitor compared with the images of the control group.
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ACCEPTED MANUSCRIPT Statistical analysis The data were analyzed using the Statistical Analysis System (version 9.2, SAS Institute Inc.,
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Cary, NC, USA). The patients’ height, weight, body mass index (BMI), and radiation dose
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were compared using an independent t-test. The objective image noise was compared using an independent t-test with Bonferroni correction. For subjective image quality analysis, the
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generalized estimating equation was used in order to compare SAFIRE groups 2-4 with
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SAFIRE group 0 and SAFIRE group 2 with SAFIRE group 3. The p-value was adjusted for age, sex, and reviewer with the Bonferroni correction. A p-value of less than 0.05 was
Results
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Patients and radiation dose
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considered statistically significant.
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There were 29 pediatric patients enrolled in the SAFIRE group. In addition, another 29 age/sex-matched patients who underwent single-phase abdominal CT scans in the emergency
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room in 2011 were enrolled in the control group. Therefore, a total of 58 pediatric patients were enrolled in this study. There were 19 boys and 10 girls in each group. The mean age of each group was 10.0 years (range: 0-16 years). The indications for an abdominal CT scan in the SAFIRE group were the evaluation of abdominal pain and/or fever in 17 patients, an abdominal mass in seven patients, postoperative evaluation in three patients, and the preoperative evaluation of congenital anomalies in two patients. In the control group, 28 patients received an abdominal CT scan for evaluation of abdominal pain and one patient received a scan due to minor injury after a traffic accident. Table 1 demonstrates the results of the demographics and radiation dose in the SAFIRE group 8
ACCEPTED MANUSCRIPT and the control group. Height, weight, and BMI did not differ between the two groups. The radiation dose was significantly lower in the SAFIRE group in comparison with the control
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group (p<0.001). The average tube voltage of the SAFIRE group was 100 kVp compared to
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111.7 kVp in the control group, showing a 10.5% reduction by using CARE kV. The average SSDE of the SAFIRE group was 2.9 mGy compared to 8.1 mGy in the control group,
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resulting in a 64.2% dose reduction. The average DLP of the SAFIRE group was 137.8 mGy
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x cm compared to 389.0 mGy x cm in the control group, showing a 64.6% reduction in the SAFIRE group.
Objective image quality
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The image noise was higher in the SAFIRE group 0 compared to that in the control group (Table 2). And the noise showed a tendency to decrease according to the increased SAFIRE
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strength. When compared with the control group, SAFIRE groups 2 and 3 showed
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comparable image noise in almost all of the areas except in the spleen in SAFIRE group 3.
group.
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There was less image noise in the spleen in SAFIRE group 3 compared with the control
Subjective image quality The results of the subjective image quality assessments are summarized in Table 3. When compared to the SAFIRE group 0, SAFIRE groups 2 (Odds ratio [OR] 1.993, p<0.001) and 3 (OR 3.015, p<0.001) showed better image quality in diagnostic acceptability. However, SAFIRE group 4 showed no significant improvement in the image quality in comparison with SAFIRE group 0 (OR 1.109, p=0.082) (Figure 1). When comparing between SAFIRE group 2 and 3, SAFIRE group 3 was better in subjective image quality (OR 1.513, p<0.001). 9
ACCEPTED MANUSCRIPT Discussion Making the image quality acceptable while reducing the radiation exposure is one of the most
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important issues in regards to CT examinations. Recent iterative reconstruction technologies,
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including SAFIRE, can lead to novel post-processing techniques in order to reduce radiation dose and improve image quality. However, there are limited studies of the use of these
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techniques in children. In addition, there is no definite guideline of the optimal iterative
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reconstruction strength for the best image quality. Our study showed that this technique is also useful in pediatric patients with the effect of a radiation dose reduction of more than 60%. We also found that iterative reconstruction strength 3 can be the best for both the objective and subjective image quality for pediatric abdominal CTs.
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Among the variable methods to reduce radiation dose, automatic kVp and mAs modulation can both be options. The use of mAs modulation automatically adapts the tube current in both
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the angular and longitudinal directions according to the patient’s size and thickness in order
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to maintain predefined image noise or image quality characteristics, and it is an important technique for reducing radiation dose [11, 12]. In addition, the use of the optimal tube
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potential can be another important technique, even though there have only been a few studies on the effects of kVp modulation on radiation dose reduction [13, 14]. While the use of kVp modulation resulted in a 10.5% reduction of the mean tube voltage, its overall effect on radiation dose cannot be determined due to the simultaneous use of mAs modulation. Further studies to clarify the effect of automatic kVp modulation technique on dose reduction and the evaluation for the possibility of additional dose reduction and dose protocol optimization using this technique are needed. Iterative reconstruction techniques can be another method used to reduce the radiation dose. There have been several studies using these techniques even in pediatric CT scans. A majority 10
ACCEPTED MANUSCRIPT of these studies were performed using Adaptive Statistical Iterative Reconstruction (ASIR, GE healthcare). Vorona et al. [15] reported a 33% dose reduction in pediatric abdominal CTs
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and Singh et al. [16] reported 46% and 38% dose reductions in pediatric chest and abdominal
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CT scans, respectively, using this technique. However, only a few studies have been performed using SAFIRE in children for cardiac CTs [17, 18].
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There have been several recent studies focusing on the use of SAFIRE in adults. However,
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these studies were primarily performed for coronary CTs [19, 20] and only a few studies were performed for abdominal CTs [21-23]. Kalra et al. [21] and Fletcher et al. [22, 23] demonstrated that SAFIRE can reduce the radiation dose by approximately 50% for abdominal CT or CT colonography in adult patients without a significant loss of image
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quality. In addition, there is no consensus about the optimal iteration strength using this technique. Fletcher et al. [22] mentioned that the diagnostic confidence and image quality
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scores can depend on the reader and they did not evaluate the optimal iteration strength. Kalra
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et al. [21] also found that there was a minor blocky, pixelated appearance in the reconstructed images with SAFIRE strengths 3 and 4 without suggesting the optimal reconstruction
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strength. In our study, there was also a minor blocky, pixelated appearance in the SAFIRE group 3 images. However, the reviewers determined that SAFIRE group 3 was better in subjective image quality compared with SAFIRE group 0 and group 2. To the best of our knowledge, this study represents the first clinical evaluation of SAFIRE with the suggestion of the optimal reconstruction strength in pediatric abdominal CT. We evaluated both the objective and subjective image quality in order to determine the optimal SAFIRE strength in pediatric abdominal CT and concluded that SAFIRE strength 3 is the most optimal. In the objective image quality analyses, the image noise decreased according to the increased SAFIRE strength. And the noise of the images with SAFIRE strengths 2 and 3 11
ACCEPTED MANUSCRIPT was comparable with that of the control group. In the subjective image quality analyses, we found that SAFIRE strength 3 can also provide the most acceptable images. However,
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diagnostic acceptability is not the same as diagnostic accuracy. There can be criticisms of
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iterative reconstruction which include the decrease of image sharpness and the limited detection of fine anatomical detail. These can affect not only image quality but also
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diagnostic accuracy. Therefore, further study about the effects of the iteration strength on
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diagnostic accuracy is needed.
There were several limitations in our study. First, we retrospectively reviewed the CT studies between two different groups with a small number of subjects and using two different CT scanners. Although the patients’ height, weight, and BMI between the two groups were not
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significantly different, this small difference could have affected the inter-individual variability. Moreover, we compared the images of each SAFIRE group from one patient together in one
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monitor which can cause bias. The indications were also different between the two groups.
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Almost all patients underwent abdominal CT due to abdominal pain in the control group when there were variable indications in the SAFIRE group. It is because we selected the
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control CT examinations performed in the emergency room. These different indications also can affect image quality. However, doing repeated CT scans in the same child for only academic purposes is not ethically appropriate. Therefore, our study design was quite acceptable and necessary for the safety of the pediatric patients. The second limitation was the relatively simple scoring system of the subjective image quality analysis. We only used four grades to evaluate the diagnostic acceptability. We did not evaluate the lesion detectability or diagnostic performance. This was due to the variable purposes of the CT scans in our patients. Additional studies with a large number of patients are needed in order to evaluate the diagnostic performance and accuracy. The third limitation of this study was that 12
ACCEPTED MANUSCRIPT we only examined the portal venous phase images of the contrast-enhanced CTs. This is the routine protocol of pediatric abdominal CT scans in our hospital in order to avoid
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unnecessary multiphase scans. However, the image noise and quality can vary in the pre-
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contrast images or in different phases of post-contrast images. Further studies are also needed
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in order to evaluate the effects of iterative reconstruction according to scan phase.
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In conclusion, both kVp and mAs modulation protocols can significantly reduce the radiation dose and iterative reconstruction using SAFIRE can preserve image quality in pediatric abdominal CT scans. The most optimal SAFIRE strength was 3 for both the objective and
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subjective image quality.
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ACCEPTED MANUSCRIPT Table 1. Demographics and radiation dose of the control group and the SAFIRE group. Control group
*p-value
Height (cm)
138.3 ± 24.6
137.7 ± 23.8
0.925
Weight (kg)
35.6 ± 14.3
38.3 ± 17.7
17.7 ± 2.1
19.5 ± 7.3
0.207
100.0± 7.6
mass
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Body
index
0.522
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(kg/m2)
<0.001
2.9 ± 0.8
8.1 ± 4.6
<0.001
137.8 ± 54.5
389.0 ± 259.2
<0.001
111.7± 10.0
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Tube voltage (kVp) SSDE(mGy) DLP (mGy x cm)
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SAFIRE group
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Note: data are shown in mean ± standard deviation
SAFIRE: sinogram–affirmed iterative reconstruction
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SSDE: size-specific dose estimates
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DLP: dose length products
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*from an independent t-test
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Table 2. Comparison of the image noise between the control group and each SAFIRE group. Data represents mean value (± standard
Noise
SAFIRE 2
SAFIRE 3
CR I
Noise
SAFIRE 0 *p-value
Noise
*p-value
Noise
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Control
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deviation) of the image noise measured as the standard deviation of the CT attenuationin each area. SAFIRE 4
*p-value
Noise
*p-value
12.3 (±2.5) 17.4 (±3.2)
<0.001
13.7 (±2.5)
0.152
11.9 (±2.5)
>0.999
10.2 (±2.3)
0.008
Aorta
15.7 (±3.7) 19.6 (±4.1)
0.001
16.3 (±4.1)
>0.999
13.9 (±3.8)
0.309
12.2 (±3.5)
0.002
Spleen 12.8 (±2.6) 15.6 (±2.7)
0.001
12.9 (±2.3)
>0.999
0.027
9.6 (±1.8)
<0.001
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Liver
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11.2 (±2.0)
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SAFIRE 0: CT group using both automatic kVpand mAsmodulation without SAFIRE
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SAFIRE 2, 3, and 4: CT group using both automatic kVp and mAs modulation and reconstructed with SAFIRE strengths 2, 3, and 4
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*from an independent t-test with Bonferroni correction
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ACCEPTED MANUSCRIPT Table 3. Subjective image quality analysis between the SAFIRE groups *p-value
SAFIRE 2 vs. SAFIRE 0
1.993 (1.769-2.245)
<0.001
SAFIRE 3 vs. SAFIRE 0
3.015 (2.750-3.304)
SAFIRE 4 vs. SAFIRE 0
1.109 (1.012-1.216)
SAFIRE 3 vs. SAFIRE 2
1.513 (1.333-1.717)
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Odds ratio (95% Confidence interval)
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Comparison of quality grades
<0.001 0.127 <0.001
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ACCEPTED MANUSCRIPT Figure legends Figure 1. Abdominal CT images at the level of the main portal vein of two 11-year-old boys
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SAFIRE strength 2 (C), 3 (D), and 4 (E).
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S0899-7071(14)00143-0 doi: 10.1016/j.clinimag.2014.05.008 JCT 7630
To appear in:
Journal of Clinical Imaging
Received date: Revised date: Accepted date:
16 January 2014 15 May 2014 19 May 2014
Please cite this article as: Kim Jun-Hwee, Kim Myung-Joon, Kim Ha Yan, Lee Mi-Jung, Radiation dose reduction and image quality in pediatric abdominal CT with kVp and mAs modulation and an iterative reconstruction technique, Journal of Clinical Imaging (2014), doi: 10.1016/j.clinimag.2014.05.008
This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
ACCEPTED MANUSCRIPT Radiation dose reduction and image quality in pediatric abdominal CT with kVp and
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mAs modulation and an iterative reconstruction technique
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Jun-Hwee Kim, M.D.1, Myung-Joon Kim, M.D., Ph.D.1, Ha Yan Kim, M.S.2, Mi-Jung Lee, M.D., Ph.D.1
of Radiology and Research Institute of Radiological Science, Severance
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1Department
Children's Hospital, Yonsei University College of Medicine, Seoul, Korea Collaboration Unit, Yonsei University, Severance Hospital
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2Biostatistics
Abbreviated title: SAFIRE in pediatric abdominal CT Corresponding author: Mi-Jung Lee, M.D., Ph.D.
Department of Radiology and Research Institute of Radiological Science Severance Children’s Hospital, Yonsei University College of Medicine
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50-1, Yonsei-ro, Seodaemun-gu, 120-752 Seoul, Korea
FAX: 82-2-393-3035
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TEL: 82-2- 2228-7400
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E-mail: [email protected]
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ACCEPTED MANUSCRIPT Abstract Objective: The objective of this study was to compare the radiation dose and image quality of
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pediatric abdominal CT using a protocol reconstructed with filtered back projection (FBP)
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and a protocol with both kVp and mAs modulation and sinogram–affirmed iterative reconstruction (SAFIRE).
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Materials and methods: We retrospectively reviewed pediatric abdominal CT examinations
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performed with both kVp and mAs modulation. These raw data were reconstructed with SAFIRE at different strengths from 2 to 4 (SAFIRE group 2-4). Another set of age/sexmatched pediatric abdominal CT examinations were also reviewed, which were performed during the same period with only mAs modulation and FBP (control group). The radiation
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dose and image quality were compared between groups. The image quality was objectively evaluated as the noise measured in the liver, aorta, and spleen at the level of the main portal
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vein and the image quality was subjectively reviewed by two radiologists for diagnostic
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acceptability using a four-point scale (0: unacceptable; 1: worse than the control group, but acceptable; 2: comparable with the control group; and 3: better than the control group). An
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independent t-test was used in order to compare the radiation dose. An independent t-test with Bonferroni correction and generalized estimating equations were used for the comparison of the objective and subjective image quality, respectively. Results: Twenty-nine patients (M:F = 19:10, mean age 10.0) were enrolled in each group. The SAFIRE group, using the size-specific dose estimates calculation method showed a 64.2% radiation dose reduction (from 8.1 to 2.9 mGy, p<0.05), compared with the results of the control group. The objective image noise of the SAFIRE groups 2 and 3 was comparable to that of the control group. The subjective image quality was the best in SAFIRE group 3 (odds ratio [OR] 3.015, p<0.001 when comparing to SAFIRE group 0; and OR 1.513, p<0.001 2
ACCEPTED MANUSCRIPT when comparing to SAFIRE group 2). Conclusions: Image acquisition with both kVp and mAs modulation and iterative
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reconstruction using SAFIRE with strength 3 can preserve the objective and subjective image
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quality of pediatric abdominal CT scans with less than half the radiation dose.
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Index Terms: Pediatric, Computed tomography, Radiation dose, Iterative reconstruction
Introduction
There are increased concerns about radiation exposure from computed tomography (CT)
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especially in pediatric patients [1, 2]. It is well known that children are more susceptible to
of malignancy [3].
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radiation than adults, because of their rapid cellular proliferation and increased lifetime risk
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One of the best methods for reducing radiation exposure is avoiding unnecessary CT evaluation and minimizing multi-phase scanning. However, CT is still a useful diagnostic tool
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in children when considering its non-invasiveness and accuracy with short acquisition time. In addition, recent advances in CT technology have suggested several methods for reducing radiation exposure. The automated modulation of tube voltage and current according to a patient’s body size has been suggested as one of the radiation dose reduction methods [4, 5]. However, lowering the tube voltage and current may increase the image noise, thus lowering the image quality and diagnostic accuracy [2]. Recently, several iterative reconstruction techniques have been suggested as post image acquisition processing methods to decrease the image noise in low-dose CT scans [6, 7]. These techniques can enhance the image quality by decreasing the image noise by the 3
ACCEPTED MANUSCRIPT introduction of multiple correction loops into the reconstruction process. One of these techniques is sinogram-affirmed iterative reconstruction (SAFIRE). This technique utilizes
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both projection space data and image space data with two different correction loops. The
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corrected image is compared to the original with a number of iterations in each space dependent on the needs of a specific scan. Thanks to advanced hardware and software, these
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complicated imaging processes can be handled faster and easier nowadays and we can use
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these clinically.
There have been many recent studies using variable iterative reconstruction techniques. However, a majority of these studies have been performed in adults and little is known about these techniques in children even though radiation dose reduction has greater clinical
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importance in children. In this study, we retrospectively compared the radiation dose and image quality in pediatric abdominal CT scans using a protocol with only mAs modulation
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and reconstruction with filtered back projection (FBP) and a protocol with both kVp and mAs
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modulation and reconstruction with SAFIRE.
Materials and Methods Patient selection This single-center retrospective study was approved by our hospital institutional review board and informed consent was waived. We retrospectively reviewed abdominal CT images performed in pediatric patients with a protocol using both tube current and voltage modulation and iterative reconstruction using SAFIRE (SAFIRE group) in our hospital from January to February 2012. Other age/sex-matched pediatric abdominal CT examinations were also reviewed which were performed during the same time period with a protocol using only 4
ACCEPTED MANUSCRIPT tube current modulation and FBP reconstruction (control group) in the emergency room. Only
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Scanning technique and radiation dose measurements
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single phase (portal venous phase) examinations were included in this study.
Our hospital has a 64 channel CT scanner (Sensation 64; Siemens Healthcare, Forchheim,
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Germany) with only the tube current modulation program (CARE Dose4D) and no iterative
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reconstruction in the emergency room. This tube current modulation program automatically adapts radiation dose to the size and shape of the patient based on the topogram, defined reference setting, and real-time angular dose modulation. For the reference setting, this technique uses the term of a quality reference mAs as a defined value that we would use for a
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standard sized adult patient weighing 75 kg. We used a quality reference mAs of 100mAs for abdominal CT in children. We scanned pediatric abdominal CTs with 80 kVp for children less
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than 10 kg, 100 kVp for children between 10-40 kg, and 120 kVp for children more than 40
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kg according to body weight. The acquisition parameters were 64 x 0.6-mm detector collimation, 1.4 pitch factor, and 0.33-sec gantry rotation. The slice thickness and increment
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were 2 mm each.
Our hospital also has a dual source CT scanner (Somatom Definition Flash; Siemens Healthcare), which has automated tube voltage and current modulation program (CARE kV and CARE Dose4D; Siemens Healthcare), and the iterative reconstruction program named SAFIRE (Siemens Healthcare). The tube voltage modulation program uses information gathered by the topogram and automatically recommends the optimally low tube voltage for the entire length of the scan while keeping the contrast-to-noise ratio. A single tube voltage (kV) is selected for each exam. It also uses a reference value as a quality reference kV set for a standard patient of 75 kg. We have used an abdominal CT protocol with a quality reference 5
ACCEPTED MANUSCRIPT kV of 100 kVp and a quality reference mAs of 100mAs for children since January 2012. The acquisition parameters were 64 x 0.6-mm detector collimation, 1.4 pitch factor, and 0.28-sec
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standard soft tissue kernel (B30f) for image reconstruction.
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gantry rotation. The slice thickness and increment were 2 mm each. Both CT scanners used
The protocols of the contrast media injection and patient preparation were the same when
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performing these two CT examinations. The abdominal CT scans were performed with
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300mg iodine/ml concentration intravenous contrast iobitridol (Xenetix, Laboratories Guerbet, Roissy, France). For contrast enhancement, 2 ml/kg of contrast was injected through an upper extremity peripheral intravenous line followed by a saline chaser of 0.5 ml/kg. The scanning was performed 40 seconds after enhancement in the abdominal aorta reached 100
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Hounsfield units (HU) for the portal venous phase only.
The volume CT dose indices (CTDIvol) and dose length product (DLP) values were recorded
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on the dose page for each of the studies. We multiplied the CTDIvol values by the conversion
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factors for size-specific dose estimates (SSDE) for the pediatric patients according to the
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American Association of Physicists in Medicine Report 204 [8].
Iterative reconstruction The SAFIRE iteration strength can be changed according to the strength of the noise reduction. The iteration strength can be ordered with an integral scale of 1 to 5, with 1 being the weakest and 5 being the strongest iteration strength. Two pediatric radiologists (M.J.K. and M.J.L.) with more than 30 and 10 years of experience with pediatric abdominal CT preliminarily reviewed several images with all 1 to 5 SAFIRE strengths and subjectively determined that images with SAFIRE strengths of 1 and 5 are too noisy or too smooth, respectively. Therefore, we selected only SAFIRE strengths 2, 3, and 4 for the analyses 6
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Objective and subjective image quality analysis
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We reviewed each study of the control group and the SAFIRE groups 2-4 using the picture archiving and communication systems of our institution (Centricity Radiology RA1000, GE
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Medical Systems, Milwaukee, WI). For quantitative image quality analysis, we obtained
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noise measurements for each study. A single circular region of interest (ROI) that measured at least 3cm2 was drawn in the homogenous regions of the right hepatic lobe, abdominal aorta, and spleen at the level of the main portal vein. We measured the noise using standard deviations (SDs) of the attenuation value of the ROI [9].
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For subjective image quality analysis, two radiologists (M.J.L. and J.H.K.) with 10 and 4 years of experience with pediatric abdominal CT reviewed all images in the study of each
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patient directly and randomly without technical or personal medical information. We used the
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standard soft tissue window settings (400HU of window width and 40HU of window level) and carefully checked the anatomic structures of the abdominal organs and vessels as
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previously suggested [10]. Each radiologist independently graded each study of the raw data from the dose modulation protocol without SAFIRE (SAFIRE group 0) and with SAFIRE strengths 2, 3, and 4 (SAFIRE groups 2-4) for diagnostic acceptability using a four-point scale in comparison with the age/sex-matched control group. Grade 0 was unacceptable; grade 1 was worse than the control group, but acceptable; grade 2 was comparable with the control group; and grade 3 was better than the control group. We reviewed the images of each SAFIRE group from one patient together in one monitor compared with the images of the control group.
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ACCEPTED MANUSCRIPT Statistical analysis The data were analyzed using the Statistical Analysis System (version 9.2, SAS Institute Inc.,
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Cary, NC, USA). The patients’ height, weight, body mass index (BMI), and radiation dose
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were compared using an independent t-test. The objective image noise was compared using an independent t-test with Bonferroni correction. For subjective image quality analysis, the
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generalized estimating equation was used in order to compare SAFIRE groups 2-4 with
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SAFIRE group 0 and SAFIRE group 2 with SAFIRE group 3. The p-value was adjusted for age, sex, and reviewer with the Bonferroni correction. A p-value of less than 0.05 was
Results
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Patients and radiation dose
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considered statistically significant.
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There were 29 pediatric patients enrolled in the SAFIRE group. In addition, another 29 age/sex-matched patients who underwent single-phase abdominal CT scans in the emergency
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room in 2011 were enrolled in the control group. Therefore, a total of 58 pediatric patients were enrolled in this study. There were 19 boys and 10 girls in each group. The mean age of each group was 10.0 years (range: 0-16 years). The indications for an abdominal CT scan in the SAFIRE group were the evaluation of abdominal pain and/or fever in 17 patients, an abdominal mass in seven patients, postoperative evaluation in three patients, and the preoperative evaluation of congenital anomalies in two patients. In the control group, 28 patients received an abdominal CT scan for evaluation of abdominal pain and one patient received a scan due to minor injury after a traffic accident. Table 1 demonstrates the results of the demographics and radiation dose in the SAFIRE group 8
ACCEPTED MANUSCRIPT and the control group. Height, weight, and BMI did not differ between the two groups. The radiation dose was significantly lower in the SAFIRE group in comparison with the control
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group (p<0.001). The average tube voltage of the SAFIRE group was 100 kVp compared to
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111.7 kVp in the control group, showing a 10.5% reduction by using CARE kV. The average SSDE of the SAFIRE group was 2.9 mGy compared to 8.1 mGy in the control group,
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resulting in a 64.2% dose reduction. The average DLP of the SAFIRE group was 137.8 mGy
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x cm compared to 389.0 mGy x cm in the control group, showing a 64.6% reduction in the SAFIRE group.
Objective image quality
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The image noise was higher in the SAFIRE group 0 compared to that in the control group (Table 2). And the noise showed a tendency to decrease according to the increased SAFIRE
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strength. When compared with the control group, SAFIRE groups 2 and 3 showed
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comparable image noise in almost all of the areas except in the spleen in SAFIRE group 3.
group.
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There was less image noise in the spleen in SAFIRE group 3 compared with the control
Subjective image quality The results of the subjective image quality assessments are summarized in Table 3. When compared to the SAFIRE group 0, SAFIRE groups 2 (Odds ratio [OR] 1.993, p<0.001) and 3 (OR 3.015, p<0.001) showed better image quality in diagnostic acceptability. However, SAFIRE group 4 showed no significant improvement in the image quality in comparison with SAFIRE group 0 (OR 1.109, p=0.082) (Figure 1). When comparing between SAFIRE group 2 and 3, SAFIRE group 3 was better in subjective image quality (OR 1.513, p<0.001). 9
ACCEPTED MANUSCRIPT Discussion Making the image quality acceptable while reducing the radiation exposure is one of the most
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important issues in regards to CT examinations. Recent iterative reconstruction technologies,
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including SAFIRE, can lead to novel post-processing techniques in order to reduce radiation dose and improve image quality. However, there are limited studies of the use of these
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techniques in children. In addition, there is no definite guideline of the optimal iterative
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reconstruction strength for the best image quality. Our study showed that this technique is also useful in pediatric patients with the effect of a radiation dose reduction of more than 60%. We also found that iterative reconstruction strength 3 can be the best for both the objective and subjective image quality for pediatric abdominal CTs.
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Among the variable methods to reduce radiation dose, automatic kVp and mAs modulation can both be options. The use of mAs modulation automatically adapts the tube current in both
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the angular and longitudinal directions according to the patient’s size and thickness in order
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to maintain predefined image noise or image quality characteristics, and it is an important technique for reducing radiation dose [11, 12]. In addition, the use of the optimal tube
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potential can be another important technique, even though there have only been a few studies on the effects of kVp modulation on radiation dose reduction [13, 14]. While the use of kVp modulation resulted in a 10.5% reduction of the mean tube voltage, its overall effect on radiation dose cannot be determined due to the simultaneous use of mAs modulation. Further studies to clarify the effect of automatic kVp modulation technique on dose reduction and the evaluation for the possibility of additional dose reduction and dose protocol optimization using this technique are needed. Iterative reconstruction techniques can be another method used to reduce the radiation dose. There have been several studies using these techniques even in pediatric CT scans. A majority 10
ACCEPTED MANUSCRIPT of these studies were performed using Adaptive Statistical Iterative Reconstruction (ASIR, GE healthcare). Vorona et al. [15] reported a 33% dose reduction in pediatric abdominal CTs
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and Singh et al. [16] reported 46% and 38% dose reductions in pediatric chest and abdominal
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CT scans, respectively, using this technique. However, only a few studies have been performed using SAFIRE in children for cardiac CTs [17, 18].
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There have been several recent studies focusing on the use of SAFIRE in adults. However,
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these studies were primarily performed for coronary CTs [19, 20] and only a few studies were performed for abdominal CTs [21-23]. Kalra et al. [21] and Fletcher et al. [22, 23] demonstrated that SAFIRE can reduce the radiation dose by approximately 50% for abdominal CT or CT colonography in adult patients without a significant loss of image
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quality. In addition, there is no consensus about the optimal iteration strength using this technique. Fletcher et al. [22] mentioned that the diagnostic confidence and image quality
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scores can depend on the reader and they did not evaluate the optimal iteration strength. Kalra
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et al. [21] also found that there was a minor blocky, pixelated appearance in the reconstructed images with SAFIRE strengths 3 and 4 without suggesting the optimal reconstruction
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strength. In our study, there was also a minor blocky, pixelated appearance in the SAFIRE group 3 images. However, the reviewers determined that SAFIRE group 3 was better in subjective image quality compared with SAFIRE group 0 and group 2. To the best of our knowledge, this study represents the first clinical evaluation of SAFIRE with the suggestion of the optimal reconstruction strength in pediatric abdominal CT. We evaluated both the objective and subjective image quality in order to determine the optimal SAFIRE strength in pediatric abdominal CT and concluded that SAFIRE strength 3 is the most optimal. In the objective image quality analyses, the image noise decreased according to the increased SAFIRE strength. And the noise of the images with SAFIRE strengths 2 and 3 11
ACCEPTED MANUSCRIPT was comparable with that of the control group. In the subjective image quality analyses, we found that SAFIRE strength 3 can also provide the most acceptable images. However,
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diagnostic acceptability is not the same as diagnostic accuracy. There can be criticisms of
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iterative reconstruction which include the decrease of image sharpness and the limited detection of fine anatomical detail. These can affect not only image quality but also
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diagnostic accuracy. Therefore, further study about the effects of the iteration strength on
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diagnostic accuracy is needed.
There were several limitations in our study. First, we retrospectively reviewed the CT studies between two different groups with a small number of subjects and using two different CT scanners. Although the patients’ height, weight, and BMI between the two groups were not
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significantly different, this small difference could have affected the inter-individual variability. Moreover, we compared the images of each SAFIRE group from one patient together in one
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monitor which can cause bias. The indications were also different between the two groups.
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Almost all patients underwent abdominal CT due to abdominal pain in the control group when there were variable indications in the SAFIRE group. It is because we selected the
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control CT examinations performed in the emergency room. These different indications also can affect image quality. However, doing repeated CT scans in the same child for only academic purposes is not ethically appropriate. Therefore, our study design was quite acceptable and necessary for the safety of the pediatric patients. The second limitation was the relatively simple scoring system of the subjective image quality analysis. We only used four grades to evaluate the diagnostic acceptability. We did not evaluate the lesion detectability or diagnostic performance. This was due to the variable purposes of the CT scans in our patients. Additional studies with a large number of patients are needed in order to evaluate the diagnostic performance and accuracy. The third limitation of this study was that 12
ACCEPTED MANUSCRIPT we only examined the portal venous phase images of the contrast-enhanced CTs. This is the routine protocol of pediatric abdominal CT scans in our hospital in order to avoid
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unnecessary multiphase scans. However, the image noise and quality can vary in the pre-
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contrast images or in different phases of post-contrast images. Further studies are also needed
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in order to evaluate the effects of iterative reconstruction according to scan phase.
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In conclusion, both kVp and mAs modulation protocols can significantly reduce the radiation dose and iterative reconstruction using SAFIRE can preserve image quality in pediatric abdominal CT scans. The most optimal SAFIRE strength was 3 for both the objective and
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subjective image quality.
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ACCEPTED MANUSCRIPT Table 1. Demographics and radiation dose of the control group and the SAFIRE group. Control group
*p-value
Height (cm)
138.3 ± 24.6
137.7 ± 23.8
0.925
Weight (kg)
35.6 ± 14.3
38.3 ± 17.7
17.7 ± 2.1
19.5 ± 7.3
0.207
100.0± 7.6
mass
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Body
index
0.522
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(kg/m2)
<0.001
2.9 ± 0.8
8.1 ± 4.6
<0.001
137.8 ± 54.5
389.0 ± 259.2
<0.001
111.7± 10.0
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Tube voltage (kVp) SSDE(mGy) DLP (mGy x cm)
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SAFIRE group
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Note: data are shown in mean ± standard deviation
SAFIRE: sinogram–affirmed iterative reconstruction
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SSDE: size-specific dose estimates
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DLP: dose length products
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*from an independent t-test
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Table 2. Comparison of the image noise between the control group and each SAFIRE group. Data represents mean value (± standard
Noise
SAFIRE 2
SAFIRE 3
CR I
Noise
SAFIRE 0 *p-value
Noise
*p-value
Noise
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Control
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deviation) of the image noise measured as the standard deviation of the CT attenuationin each area. SAFIRE 4
*p-value
Noise
*p-value
12.3 (±2.5) 17.4 (±3.2)
<0.001
13.7 (±2.5)
0.152
11.9 (±2.5)
>0.999
10.2 (±2.3)
0.008
Aorta
15.7 (±3.7) 19.6 (±4.1)
0.001
16.3 (±4.1)
>0.999
13.9 (±3.8)
0.309
12.2 (±3.5)
0.002
Spleen 12.8 (±2.6) 15.6 (±2.7)
0.001
12.9 (±2.3)
>0.999
0.027
9.6 (±1.8)
<0.001
MA
Liver
D
11.2 (±2.0)
TE
SAFIRE 0: CT group using both automatic kVpand mAsmodulation without SAFIRE
CE P
SAFIRE 2, 3, and 4: CT group using both automatic kVp and mAs modulation and reconstructed with SAFIRE strengths 2, 3, and 4
AC
*from an independent t-test with Bonferroni correction
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ACCEPTED MANUSCRIPT Table 3. Subjective image quality analysis between the SAFIRE groups *p-value
SAFIRE 2 vs. SAFIRE 0
1.993 (1.769-2.245)
<0.001
SAFIRE 3 vs. SAFIRE 0
3.015 (2.750-3.304)
SAFIRE 4 vs. SAFIRE 0
1.109 (1.012-1.216)
SAFIRE 3 vs. SAFIRE 2
1.513 (1.333-1.717)
T
Odds ratio (95% Confidence interval)
SC
RI P
Comparison of quality grades
<0.001 0.127 <0.001
MA NU
*from a Generalized Estimating Equation with adjusted for age, sex, and reviewer with
AC
CE
PT
ED
Bonferroni correction.
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ACCEPTED MANUSCRIPT Figure legends Figure 1. Abdominal CT images at the level of the main portal vein of two 11-year-old boys
T
for the evaluation of abdominal pain. A is a routine radiation dose image with filtered back
RI P
projection in the control group. B is an image using both automatic kVp and mAs modulation without SAFIRE reconstruction in the SAFIRE group. C-E are images reconstructed with
AC
CE
PT
ED
MA NU
SC
SAFIRE strength 2 (C), 3 (D), and 4 (E).
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ACCEPTED MANUSCRIPT
AC
CE
PT
ED
MA NU
SC
RI P
T
Figure 1A
22
ACCEPTED MANUSCRIPT
AC
CE
PT
ED
MA NU
SC
RI P
T
Figure 1B
23
ACCEPTED MANUSCRIPT
AC
CE
PT
ED
MA NU
SC
RI P
T
Figure 1C
24
ACCEPTED MANUSCRIPT
AC
CE
PT
ED
MA NU
SC
RI P
T
Figure 1D
25
ACCEPTED MANUSCRIPT
AC
CE
PT
ED
MA NU
SC
RI P
T
Figure 1E
26