BACKGROUND: 3-dimensional intra-cone beam computed tomography (intra-CBCT) could be a potentially powerful tool for use with arc irradiation such as volumetric modulated arc therapy.
The aim of the study was to evaluate the image quality of intra-cone beam computed tomography (intra-CBCT) for arc irradiation with various imaging condition.
MATERIALS AND METHODS: Two types of intra-CBCT imaging techniques were evaluated — intra-fractional CBCT with flattening filtered (FF) beam (intra-FF CBCT) and that with flattening filter free (FFF) beam (intra-FFF CBCT). For the intra-MV beams, four different field sizes (2 cm x 2 cm, 5 cm x 5 cm, 10 cm x 10 cm, and 20 cm x 20 cm) were used with dose rates of 500 MU/min and 1600 MU/min, for 6 MV FF and 6 MV FFF, respectively. For all image acquisitions, two rotation angles (full-arc and half-arc) were investigated. Thereafter, the linearity, contrast-to-noise ratio (CNR), and uniformity index (UI) of intra-CBCT image were compared with those of conventional CBCT image.
RESULTS: All acquisition conditions had good linearity of the CT value (R2 &gt; 0.99). For CNR, the change rates from conventional CBCT ranged from 0.6–33.7% for a 2 cm x 2 cm beam, whereas that for a 20 cm x 20 cm beam ranged from 62.7–82.3%. Similarly, the UI increased from 1.5% to 7.0% as the field size increased.
CONCLUSION: Quality of intra-CBCT image was affected by the field size and acquisition angle. Image quality of intra-CBCT was worse than that of conventional CBCT, but it was better under a smaller field and wider correction angle and would be acceptable for clinical use.


Aoki, Shinichi

Komiyama, Takafumi

Maehata, Yoshiyasu

Marino, Kan

Onishi, Hiroshi

Saito, Masahide

Sano, Naoki

Shibata, Yuki

Suzuki, Hidekazu

Ueda, Koji

Via Medica Journals

495https://journals.viamedica.pl/rportechnical noteReports of Practical oncology and Radiotherapy 2021, Volume 26, number 3, pages: 495–501 Doi: 10.5603/RPoR.a2021.0066Submitted: 04.08.2020accepted: 25.02.2021Address for correspondence: Masahide Saito, Ph.D., Department of Radiology, University of Yamanashi, 1110 Shimokato, Chuo-city, Yamanashi, 409-3898, Japan, tel: +81-55-273-1111, fax: +81-55-273-6744; e-mail: masahides@yamanashi.ac.jpQuantification of image quality of intra-fractional  cone-beam computed tomography for arc irradiation  with various imaging condition Masahide Saito, Yuki Shibata, Koji Ueda, Hidekazu Suzuki, Takafumi Komiyama, Kan Marino,  Shinichi Aoki, Yoshiyasu Maehata, Naoki Sano, Hiroshi OnishiDepartment of Radiology, University of Yamanashi, Yamanashi, Japanthis article is available in open access under creative common attribution-non-commercial-no Derivatives 4.0 international (cc BY-nc-nD 4.0) license, allowing to download articles and share them with others as long as they credit the authors and the publisher, but without permission to change them in any way or use them commercially© 2021 Greater Poland cancer centre.  Published by Via Medica.  all rights reserved.e-iSSn 2083–4640iSSn 1507–1367REPORTS OF PRACTICALONCOLOGY ANDRADIOTHERAPYISSN: 1507–1367introductionIn high conformal radiotherapy for a tumor with respiratory motion, monitoring the in-tra-fractional tumor motion is important to con-firm the accuracy of irradiation and reduce inter-nal margin. Institutes globally have used multiple techniques to monitor tumor motion during ir-radiation. One of the techniques involves the use of an electronic portal imaging device (EPID), which enables to monitor the target localization using the treatment beam on cine mode EPID image [1]. Another technique is a 4-dimension-al (4-D) kV-cone-beam computed tomography AbstrActbackground: 3-dimensional intra-cone beam computed tomography (intra-cBct) could be a potentially powerful tool for use with arc irradiation such as volumetric modulated arc therapy. the aim of the study was to evaluate the image quality of intra-cone beam computed tomography (intra-cBct) for arc irradiation with various imaging condition.Materials and methods: two types of intra-cBct imaging techniques were evaluated — intra-fractional cBct with flattening filtered (FF) beam (intra-FF cBct) and that with flattening filter free (FFF) beam (intra-FFF cBct). For the intra-MV beams, four different field sizes (2 cm × 2 cm, 5 cm × 5 cm, 10 cm × 10 cm, and 20 cm × 20 cm) were used with dose rates of 500 MU/min and 1600 MU/min, for 6 MV FF and 6 MV FFF, respectively. For all image acquisitions, two rotation angles (full-arc and half-arc) were investigated. thereafter, the linearity, contrast-to-noise ratio (cnR), and uniformity index (Ui) of intra-cBct image were compared with those of conventional cBct image.results: all acquisition conditions had good linearity of the ct value (R2 > 0.99). For cnR, the change rates from conventional cBct ranged from 0.6–33.7% for a 2 cm × 2 cm beam, whereas that for a 20 cm × 20 cm beam ranged from 62.7–82.3%. Simi-larly, the Ui increased from 1.5% to 7.0% as the field size increased. conclusion: Quality of intra-cBct image was affected by the field size and acquisition angle. image quality of intra-cBct was worse than that of conventional cBct, but it was better under a smaller field and wider correction angle and would be acceptable for clinical use. Key words: cone-beam computed tomography; volumetric modulated arc therapy; MV simultaneous exposure; image qualityRep Pract Oncol Radiother 2021;26(3):495–501Reports of Practical Oncology and Radiotherapy 2021, vol. 26, no. 3https://journals.viamedica.pl/rpor496(CBCT). This technique enables to verify the tumor position and other anatomical positions during treatment to generate the respiratory cor-related CBCT by projection phase sorting [2]. Some studies have investigated the effectiveness and improvement of 4D-kV CBCT to assess the respiratory motion of tumor during high confor-mal treatments, such as volumetric modulated arc therapy (VMAT) [3–6].In this study, we investigated the effectiveness of intra-fractional CBCT, called intra-CBCT, a poten-tially powerful tool for use with arc irradiation such as volumetric modulated arc therapy. Although the quality of intra-CBCT images is worse due to the ray scattering derived from MV beam irradiation and the acquisition of them gives an extra dose, no study has evaluated the details of image quality dur-ing arc irradiation. Materials and methodsequipment for intra-cBctX-ray volume imaging (XVI®) system ver. 5.0 (Elekta AB, Crawley, UK) attached to the Elekta Synergy was used in this study. It utilizes an amorphous silicon/cesium iodide flat-panel detector with a 1024 × 1024 array of 0.4-mm elements. The X-ray source is mounted on a re-tractable arm with a fixed source to an isocenter distance of 100 cm and offers several different in-terchangeable collimators and kV filter combina-tions based on the desired scanning volume. For acquiring intra-CBCT images, the 3D Volume ViewTM mode was used, which are reconstructed automatically after the acquisition of projection images. For reconstruction of intra-CBCT im-ages, beam delivery has to be accompanied by a rotational treatment, such as conformal arc ra-diotherapy and VMAT.In this study, three types of CBCT images were compared, namely: 1) conventional CBCT image, 2) intra-CBCT image acquired using a 6 MV flat-tening filter (FF) beam (intra-FF CBCT), and 3) intra-CBCT image acquired using a 6 MV with flattening filter free (FFF) beam (intra-FFF CBCT). Two collection angles (full-arc: CW, −180°to 180°and half-arc: CW, −180°to 20°) were investi-gated for image acquisition. All images were ac-quired with a 120-kV, 20-mA with the following imaging parameters: S10 collimator (27 cm of ax-ial field-of-view (FOV), 12 cm of nominal axial length); image size, 540 × 540 pixels; pixel size, 0.5 mm; and slice thickness, 0.5 mm. For the intra-MV beams, the monitor unit (MU) was set as 1000, and four different field sizes (2 cm × 2 cm, 5 cm × 5 cm, 10 cm × 10 cm, and 20 cm × 20 cm) were used with dose rates of 500 MU/min and 1600 MU/min, for 6 MV FF and 6 MV FFF, respectively.evaluation of image qualityThe Catphan® 503 (The Phantom Laboratory, Sa-lem, NY, US) phantom with a 20-cm diameter was used for the evaluation of intra-CBCT image qual-ity. It has the following different inserts for evaluat-ing the geometric accuracy with defined distances in the axial and longitudinal directions: 1) a section with uniform material and a density equivalent to that of water for determining spatial uniformity; 2) a section featuring a cylindrically arranged resolu-tion pattern in an axial plane (1 through 21 line pairs per centimeter) and two point markers (tung-sten-carbide bead; diameter, 0.28 mm) embed-ded into a uniform material; and 3) a section with inserts of different densities such as polystyrene, polymethylpentene (PMP), low-density polyethyl-ene (LDPE), acrylic, air, Delrin, and Teflon imple-mented for conversion testing of electron density to the CT number. The phantom was set in the treat-ment couch top and the laser was aligned as shown in Figure 1A.Image quality evaluation was performed us-ing the following three indexes: 1) linearity be-tween nominal and measured CT values; 2) con-trast-to-noise ratio (CNR); and 3) uniformity in-dex (UI). For the linearity, the average CT value was measured with nine regions of interest (ROIs), where each material existed (two materials had wa-ter). For the CNR, the value was calculated by fol-lowing equation (1):𝐶𝐶𝐶𝐶𝐶𝐶 𝐶 𝑆𝑆��� − 𝑆𝑆�� �𝜎𝜎�� �   𝑈𝑈𝑈𝑈 𝐶 𝑈𝑈𝑈 𝑈 𝐻𝐻𝑈𝑈����������� − 𝐻𝐻𝑈𝑈����������𝐻𝐻𝑈𝑈���������� + 𝑈𝑈𝑈𝑈      (1)where, Smat is the mean pixel value of each material; SB.G. is the mean pixel value of the back-ground (water), and σB.G. is the standard deviation of the background (water). Figure 1B shows the image slice used for evaluation of the linearity and CNR.Masahide Saito et al. Quantification of intra-cBct497https://journals.viamedica.pl/rporTo assess the UI, the average CT value was mea-sured with five ROIs at regions with uniformity. Then, the UI was calculated with the following equation (2):𝐶𝐶𝐶𝐶𝐶𝐶 𝐶 𝑆𝑆��� − 𝑆𝑆�� �𝜎𝜎�� �   𝑈𝑈𝑈𝑈 𝐶 𝑈𝑈𝑈 𝑈 𝐻𝐻𝑈𝑈����������� − 𝐻𝐻𝑈𝑈����������𝐻𝐻𝑈𝑈���������� + 𝑈𝑈𝑈𝑈      (2)where, HUmaximum is the mean HU that is the larg-est value among the peripheral four ROIs; HUcenter is the mean HU of the center of the ROI. Figure 1C shows the image slice used for the evaluation of UI. All analyses were performed using MATLAB R2016a (Mathworks Inc., Natick, MA).ResultsFigure 2 shows the comparison among three CBCT images (conventional, intra-FF, and in-tra-FFF CBCT images with a field size of 10 cm × 10 cm). The slice which has a 1 through 21-line pair per centimeter high-resolution test gauge is shown for each image. On comparison between conven-tional and intra-CBCT images, the latter contained more noise than the former because of MV beam scattering during the imaging of the phantom. Es-pecially, intra-FFF CBCT contained more noise than intra-FF CBCT. Furthermore, on focusing on the collection angles, full-arc showed better image recognition than those acquired with half-arc. Fig-ure 3 also shows the lateral profiles of each CBCT image with the same condition of Figure 2, indicat-ing that intra-CBCT images contain noise from MV beam scattering. Figure 4 shows the comparison among four field sizes (intra-CBCT with the field size of 2 cm × 2 cm, 5 cm × 5 cm, 10 cm × 10 cm, and 20 cm × 20 cm) for two collection angles. The image quality was worse as the field size increased. Thereafter, all CBCT images were quantitatively analyzed. Table 1 shows the linearity between the nominal and measured CT values. Good linear-ity was observed for both conventional CBCT and intra-CBCT (FF and FFF) images (R2 > 0.99 for all acquisition conditions). Figure 5 shows the change in CNR values depending on each field size for sev-en materials. CNR values decreased as the field size increased for all conditions. Table 2 shows the aver-age value of the CNR change rate (%) for all materi-als assessed using conventional CBCT images for each condition. The change rates from conventional CBCT ranged from 0.6–33.7% for a 2 cm × 2 cm beam, whereas that ranged from 62.7–82.3% for a 20 cm × 20 cm beam. With regard to the col-lection angles, full-arc showed better CNR than the half-arc. Similarly, for beam quality, intra-FF CBCT images showed better CNR than intra-FFF CBCT images. Figure 6 shows the changes in UI depending on each field size for the intra-FF and intra-FFF CBCT images with two collection angles. For all conditions, the UI increased as the field sizes increased (approximately, from −1.5 to 7.0).DiscussionQuality assurance of the kV-CBCT system is one of the important topics in radiotherapy and new research, such as image quality of dual en-Figure 1. Setup of the catphan®503 phantom in the head of treatment couch (A), and the region of interest (Roi) for each image analysis (b, c); b — the image slice used for evaluating the linearity and contrast-to-noise ratio (cnR), which has nine Rois with each material; c — the slice for the evaluation of the uniformity index (Ui) which has five homogeneity Roisa B cReports of Practical Oncology and Radiotherapy 2021, vol. 26, no. 3https://journals.viamedica.pl/rpor498ergy CT, has been carried out [7]. However, in our knowledge, there has been no reports to investi-gate the image quality of intra-CBCT with various imaging conditions in detail. In our results, image Figure 3. lateral profiles of three cBct images (black line, conventional cBct images; red line, intra-FF cBct images; and blue line, intra-FFF cBct images). two collection angles (upper, full-arc; bottom, half-arc) are shown. the selected profile line is shown in right figure (red line)Full-arcCBCTIntra-FF-CBCTIntra-FFF-CBCTHalf-arc≠ Profile lineCT value (HU)CT value (HU)8004000–400–800–12008004000–400–800–1200Lateral pixel numberLateral pixel numberCBCTFull-arcHalf-arcIntra-FF-CBCT Intra-FFF-CBCTFigure 2. comparison of three cBct images [(A) and (D), conventional cBct images; (b) and (E), intra-FF cBct images; and (c) and (F), intra-FFF cBct images] at the slice which has a 1 through 21-line pair per centimeter high-resolution test gauge. two collection angles (upper, full-arc; bottom, half-arc) are shown. the image size is 540 × 540 pixels, and the pixel size was 0.5 mm for all dimensions. Window width of 1,000 hU and window level of 10 hU are showna B cD e FMasahide Saito et al. Quantification of intra-cBct499https://journals.viamedica.pl/rporquality depended on the field size and acquisition angle. With regard to field size, the scattered dose from the subject increased when the field size was large, which resulted in deteriorating image qual-ity. With regard to the acquisition angle, full-arc imaging provided better image quality than half-arc because the former usually generates more projec-tion images during treatment. Therefore, our study suggested that treatment with small fields, such as stereotactic body radiotherapy, might be preferred to use intra-CBCT. However, this study did not per-form the evaluation with actual patient images and, therefore, additional study is required.Our study had some limitations. First, we in-vestigated the image quality by only one vender (Elekta XVI). Our results might differ from those on other vendor machines. Second, our study only investigated images acquired with the following condition: 120 kV and 20 mA with S collimator. Therefore, different future studies should investi-gate image acquisition with different irradiation conditions. Third, in this study, we only evaluated the following two beam qualities: 6 MV FF and 6 MV FFF with the same MU. From our results, the quality of images acquired with FF seems better than acquired with FFF. However, the dose rate and gantry speed between them differed, indicat-ing that they cannot be compared with each other. Therefore, further studies are needed to compare different beam qualities.table 1. linearity (R2) between the nominal and measured ct valuesLinearity (R2)CBCT 2 cm × 2 cm 5 cm × 5 cm 10 cm × 10 cm 20 cm × 20 cmFFFull-arc 0.9999 0.9999 0.9999 0.9998 0.9996half-arc 0.9995 0.9996 0.9997 0.9993 0.9996FFFFull-arc 0.9999 0.9998 0.9999 0.9999 0.9991half-arc 0.9995 0.9994 0.9990 0.9995 0.9968Full-arcHalf-arc2 cm × 2 cm 5 cm × 5 cm 10 cm × 10 cm 20 cm × 20 cma B c De F G hFigure 4. comparison among four field sizes [(A) and (E), 2 cm × 2 cm; (b) and (F), 5 cm × 5 cm; (c) and (G), 10 cm × 10 cm; and (D) and (H), 20 cm × 20 cm] at the slice which has a 1 through 21-line pair per centimeter high-resolution test gauge. the intra FF-cBct images with two collection angles (upper, full-arc; bottom, half-arc) are shown. the image size is 540 × 540 pixels, and the pixel size was 0.5 mm for all dimensions. Window width of 1,000 hU and window level of 10 hU are shownReports of Practical Oncology and Radiotherapy 2021, vol. 26, no. 3https://journals.viamedica.pl/rpor500table 2. the average value of the change rate (%) of contrast-to-noise ratio for all materials as evaluated using conventional cBct images for each conditionCNR change rate (%)2 cm × 2 cm 5 cm × 5 cm 10 cm × 10 cm 20 cm × 20 cmFull-arcFF –23.9 ± 20.7 –36.9 ± 32.8 –62.1 ± 14.2 –72.3 ± 20.5FFF –27.1 ± 44.8 –38.6 ± 32.3 –66.3 ± 18.0 –74.6 ± 26.7half-arcFF –0.6 ± 39.5 –11.8 ± 25.7 –37.1 ± 16.4 –62.7 ± 10.3FFF –33.7 ± 18.6 –48.3 ± 39.4 –73.2 ± 19.1 –82.3 ± 17.0Figure 5. changes in contrast-to-noise ratio depending on the field size (2 cm × 2 cm, 5 cm × 5 cm, 10 cm × 10 cm, 20 cm × 20 cm) for seven materials. (A) and (c) show the results of intra-FF cBct images and (b) and (D) show the results of intra-FFF-cBct images. two collection angles (upper, full-arc; bottom, half-arc) are shownFull-arcIntra-FFF-CBCTHalf-arcIntra-FF-CBCT    CBCT        2 × 2         5 × 5      10 × 10    20 × 20Field size [cm]    CBCT        2 × 2         5 × 5      10 × 10    20 × 20Field size [cm]    CBCT        2 × 2         5 × 5      10 × 10    20 × 20Field size [cm]    CBCT        2 × 2         5 × 5      10 × 10    20 × 20Field size [cm]CNRCNRCNRCNR50403020100504030201005040302010050403020100MaterialAir1Air2TeflonDelrinTMActylicPolyatyreneLDPEPMPa Bc DFigure 6. Uniformity index changes depending on the field size (2 cm × 2 cm, 5 cm × 5 cm, 10 cm × 10 cm, 20 cm × 20 cm). the intra-FF cBct (black line) and intra-FF cBct (gray line) for two collection angles [full-arc (solid line) and half-arc (dash line)] are shownUI (%)8.06.04.02.00.0–2.0–4.0CBCT        2 × 2         5 × 5       10 × 10   20 × 20Field size [cm]FF, Full-arcFFF, Full-arcFF, Half-arcFFF, Half-arcMasahide Saito et al. Quantification of intra-cBct501https://journals.viamedica.pl/rporconclusionIn this study, we evaluated intra CBCT at the various imaging conditions using the Catphan® 503 phantom. Quality of intra-CBCT image was af-fected by the field size and acquisition angle. Image quality of intra-CBCT was worse than that of con-ventional CBCT, but it was better under a smaller field and wider correction angle and would be ac-ceptable for clinical use.conflicts of interestThere is no conflict of interest with regard to this manuscript.FundingNone declared.Reference1. 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First clinical cone-beam ct imaging during volumetric modulated arc ther-apy. Radiother oncol. 2009; 90(3): 422–423, doi: 10.1016/j.radonc.2008.11.009, indexed in Pubmed: 19062117.6. Kida S, Masutani Y, Yamashita h, et al. in-treatment 4D cone-beam ct with image-based respiratory phase recognition. Radiol Phys technol. 2012; 5(2): 138–147, doi: 10.1007/s12194-012-0146-5, indexed in Pubmed: 22367851.7. Pawałowski B, Szweda h, Dudkowiak a, et al. Quality evaluation of monoenergetic images generated by dual-energy computed tomography for radiotherapy: a phan-tom study. Phys Med. 2019; 63: 48–55, doi: 10.1016/j.ejmp.2019.05.019, indexed in Pubmed: 31221408.

Quantification of image quality of intra-fractional cone-beam computed tomography for arc irradiation with various imaging condition

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Quantification of image quality of intra-fractional cone-beam computed tomography for arc irradiation with various imaging condition

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