research article Dosimetric evaluation of a 320 detector row CT scanner unit Mario de Denaro and Paola Bregant S.C. di Fisica Sanitaria, A.O.U. "Ospedali Riuniti" di Trieste, Trieste, Italy Received 22 May 2010 Accepted 2 September 2010 Correspondence to: Dr. Mario de Denaro, Struttura Complessa di Fisica Sanitaria, Azienda Ospedaliero Universitaria "Ospedali Riuniti" di Trieste, Ospedale Maggiore, Centro Tumori, Via Pietá 19, 34100 Trieste, Italy. Phone: +39 040 399 2341; Fax: +39 040 399 2367; E-mail: mario.dedenaro@aots.sanita.fvg.it Disclosure: No potential conflicts of interest were disclosed. Background. The technologic improvements in Multislice scanners include the increment in the X-ray beam width. Some new CT scanners are equipped with a 320 detector row which allows a longitudinal coverage of 160 mm and a total of 640 slices for a single rotation. When such parameters are used the length of the traditional pencil chamber (10 cm) is no more appropriate to measure the standard weighted computed tomography dose index (CTDIw) value. Materials and methods. Dosimetric measurements were performed on a 640 slices Toshiba Aquilion One CT scanner using common instrumentation available in Medical Physics Departments. Results. For the measurements in air, two different ionization chambers were completely exposed to the beam. Dosimeters showed an acceptable agreement in the measurements. To evaluate the actual shape of the dose profile strips of Gafchromic XRQA film were used. Films were previously calibrated on site. From the graphic response of the scanned film it is possible to evaluate the full width at half maximum (FWHM) of the dose profile which represent the actual beam width. Conclusions. Computed Tomography Dose Index (CTDI) and Dose Length Product (DLP) need to be changed when the beam width of the CT scanner is over 100 mm. To perform dose evaluation with the conventional instrumentation, two parameters should be considered: the average absorbed dose and the actual beam width. To measure the average absorbed dose, the conventional ionization chamber can be used. For the measurement of the width of the dose profile, Gafchromic XRQA film seemed to be suitable. Key words: multislice CT; pencil chamber; computed tomography dose index; dose profile; Gafchromic film Introduction The advent of multislice scanners technology1 leads to a continuous increment of the X-ray beam width along the cranio-caudal direction. The new CT scanner from Toshiba, Aquilion One, is equipped with the 320 detector rows each one 0.5 mm wide. This new technology allows a longitudinal coverage of 160 mm at rotation time of 0.35 seconds. The important change in dosimetric evaluation is needed to adapt the CT dosimetry metrics to the new standard.2-5 With a 160 mm beam width as an operating condition, the length of the traditional pencil chamber (10 cm) is no more appropriate to evaluate the standard computed tomography dose index (CTDI).6 Despite this problem the CTDI and the dose length product (DLP) values are still dis- played on the scanner console. The problem for medical physicists, who must carry out quality assurance and dose optimization on the new CT equipment, is that suitable instrumentation is usually not available. In the present work we suggest some dosimetric measurements that can be carried out on a 320 row CT scanner unit, by means of conventional dosimetric instrumentation. Material and methods Some measurements on a 640 slices Toshiba Aquilion One CT scanner were carried out by means of common instrumentation typically employed at Medical Physics Departments. CT scanners providing 160 mm beam width allows to completely expose the 6cc ionization chamber of a Radcal Dosimeter, model 9015, commonly employed in the conventional radiodiagnostic measurement. To evaluate the average absorbed dose due to the primary beam, we compared the measurement carried out in air at the isocenter of the gantry, during a single rotation, exposing together the Radcal Dosimeter and the standard 10 cm long CT pencil chamber (WDCT 10, Wellhofer, Germany), connected to PMX-III electrometer. The average absorbed dose alone does not give information regarding the profile of the dose along the cranio-caudal direction (Z axis); it is a parameter to be considered to evaluate the shape and the actual width of the beam. To measure the dose profile free in air Gafchromic XRQA film was exposed to the primary beam during a single axial rotation. The film was previously calibrated exposing small pieces of Gafchromic (2 x 2 cm) to increasing doses; the Gafchromic films were put close to a reference ionization chamber. A calibration curve specific for the CT scanner beam quality was then obtained and it was used to convert the pixel values of the film into dose values (Figure 1).7 The exposed film was then scanned by a regular scanner (Epson 1680 pro) using red-green-blue (RGB) modality at 48 bits of depth and spatial resolution of 72 dots per inch. Only the red component of the image was considered. The dose profile was obtained correcting the pixel values by the calibration curve (Figure 2). From the graph the full width at half maximum (FWHM) of the dose profile can be evaluated. FWHM is a parameter which is related to the Z-axis geometric efficiency. CTDIair 300 (CTDI value using an integration interval of 300 mm) and CTDIair,100 (CTDI value using an integration interval of 100 mm) were evaluated and compared (Figure 3).2 Finally, we put a strip of Gafchromic film in the holes of a standard CT dosimetric PMMA phantom (Figure 4) to evaluate the average absorbed dose inside the phantom (Figure 5). Results FIGURE 1. Fitting curve for the calibration of Gafchromic XRQA film. FIGURE 2. Dose profile measured by Gafchromic XRQA film. ® 5 E Ï 6 10,«) 35,M JO,00 15.00 10.00 O.OO — qs.Da 40.00 35,00 30.00 35.00 20.00 15.00 10.00 5 00 0.00 jk u / ¿Îii 1 -J 50 100 .' : r'w'ij Assùî [mm) The measurement performed by the Radcal dosimeter showed an acceptable agreement with the values obtained by the Wellhofer pencil chamber (Table 1). The comparison was meaningful because the 6 cc chamber of the Radcal dosimeter is completely exposed by the beam width. To maintain the meaning of the CTDI, the integration interval for 160 mm beam width must be FIGURE 3. (A) Computed tomography dose index (CTDI)air,300. (B) CTDIair, 100. extended to a value of at least 300 mm.2 For the measurement of the weighted computed tomography dose index (CTDIw) a PMMA phantom is required, but at the moment it is very difficult to find and manage a PMMA phantom with a length TABLE 1. Absorbed dose evaluated with two different dosimeters Dosimeter Dose FOV Head (mGy/mAs) Dose FOV Body (mGy/mAs) Wellhofer pencil chamber (WDCT 10), with PMX-III Radcal model 9015with 6cc chamber 10X5-6 0.257 0.272 0.225 0.243 FOV, field-of-view; WDCT 10, Wellhofer CT pencil chamber 10 cm long FIGURE 4. Strip of Gafchromic film inserted inside the hole of a poliymethyl methacrylate (PMMA) phantom. mGy —*— Head ccntro — hkitit pfciifei Iii U\ - P i \ Ï £ 1 / i f i -80 -70 -ED -50 -40 -JO -20 -Id 10 Î0 30 40 50 60 70 Z-axis (mm} FIGURE 5. Average dose evaluation by Gafchromic film into the poliymethyl methacrylate (PMMA) phantom. of 300 mm. Moreover, also for the measurement of CTDI in air the length of the conventional pencil chamber (100 mm) is inappropriate. A way to perform dosimetric measurements using conventional instrumentation is to use the ionization chamber for the measurement of the average absorbed dose and Gafchromic film for the evaluation of the actual shape of the dose profile along z-axis. In Figure 1 the shape of the dose profile is plotted; an asymmetry appears evident in the profile due to the anode heel effect. Analysing the profile FWHM was calculated to be 171.8 mm pointing out an overbeam-ing of 11.8 mm. Z-axis geometric efficiency was also evaluated; it is defined by the International Electrotechnical Commission (IEC)8 as the ratio between the integral over the range subtended by detectors and total integral of the dose profile. The measured value of 95.4% showed for this parameter a low contribution of the penumbra effect. In Figure 3 two different intervals of integration to evaluate the CTDIair are presented; the value of CTDI ,„ was 36.7 mGy and the value of CTDI ,„„ air,300 J air,100 was 34.5 mGy. The result was as expected because the longer interval takes into account also the contribution due to the tails of the dose profile. To obtain an estimation of the absorbed dose inside the PMMA phantom, a strip of Gafchromic film was inserted in the phantom holes. The resulting value of 74.7 mGy was compared with the value of 81.4 mGy displayed at the CT console as CTDIvol. The comparison showed a significant underestimation of the measured value probably due to the length of the PMMA phantom (15 cm) which is not long enough to simulate completely the effect of the scattered radiation. Discussion Multislice CT scanners lead to a progressive increment in the X-ray beam width along z-axis. 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