Measurement of modulation transfer function in Z-axis for multi-slice spiral CT using the micro-disk method: comparison with the bead method and examination of geometric influence

• Published in: Nippon Hōshasen Gijutsu Gakkai zasshi Vol. 59; no. 11; p. 1391
• Main Authors: Hara, Takanori, Tsuzaka, Masatoshi, Sakurai, Naoyuki
• Format: Journal Article
• Language: Japanese
• Published: Japan 01.11.2003
• Subjects: Phantoms, Imaging; Sensitivity and Specificity; Tomography, Spiral Computed - methods
• ISSN: 0369-4305
• DOI: 10.6009/jjrt.KJ00003174070

Many methods of measuring the section-sensitive profile (SSP) of computed tomography (CT) by the input of a delta function have been reported. In Japan, the bead method is used as a common measurement because of the high flexibility of the multi-purpose method. However, the intensity of the response of the bead method tends to decline, creating a relatively large error in the base of section-sensitive profiles. A problem is considered to be the accuracy of measurement in evaluating spatial resolution along the z-axis in multi-slice spiral/helical CT (MSCT). We therefore evaluated the modulation transfer function (MTF) by conducting research with the micro-disk method (100 micro m thickness and 1.0 mmphi diameter) and the bead method (1.0 mmphi diameter) for the same input width. Moreover, in the micro-disk method, we also examined alignment, circular region of interest (ROI), and the energy characteristic. Our comparison of MTFs obtained by the micro-disk method and the bead method showed that the former resulted in a higher value and lower standard deviation. The difference was significant at p<0.01. Measurement using the micro-disk method did not show significant differences in terms of alignment and ROIs. Moreover, the energy characteristic was not indicated. This research demonstrated that the accuracy of MTF measurement with the micro-disk method was greater than that with the bead method, and it was found that there was no influence on the actual measurement level of the geometric structure with the micro-disk method.