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Objective:To evaluate the influence of different detector widths and signal acquisition positions of wide-detector CT in different scanning modes on CT number and noise, and to provide a basis for reasonable selection of scanning modes and related parameters in clinical practice.Methods:The body dose phantom was scanned by GE Revolution CT. The scan was performed with detector widths of 40, 80 and 160 mm in sequential scanning mode and with detector width/pitch combinations of 40 mm/0.516, 40 mm/0.984, 80 mm/0.508 and 80 mm/0.992 in spiral scanning mode. The phantom was placed at the central and peripheral of the selected detector widths, and the adjacent positions between two axial scans. The images of the phantom were evaluated subjectively and the CT numbers and SDs were measured. The differences between the measured values at different imaging parameters were compared. The multi-group Friedman test was used to compare CT numbers and SD under different scanning parameters in sequential scanning mode, and the Wilcoxon test was used to compare CT numbers and SD in spiral scanning mode.Results:There was no statistically significant difference in the geometric shapes of the phantom images obtained at any combination of parameters. In sequential scanning mode, the differences at different detector widths were statistically significant (χ 2=14.00, P=0.001) with CT numbers at 40 mm and 160 mm greater than CT numbers at 80 mm ( P<0.05). The differences at different signal acquisition positions were statistically significant (χ 2=12.04, P=0.002) with CT numbers at peripheral and adjacent greater than CT numbers at central ( P<0.05). In spiral scanning mode CT numbers at detector width at 80 mm were greater than CT numbers at 40 mm ( Z=-2.10, P=0.036). For SD, the differences at different detector widths were statistically significant in sequential scanning modes (χ 2=8.17, P=0.017) with SD at 160 mm greater than SD at 80 mm ( P<0.05). The differences at different signal acquisition positions were statistically significant (χ 2=13.50, P=0.001) with SD at peripheral greater than SD at central ( P<0.05). In spiral scanning mode SDs at pitches 0.984 and 0.992 were greater than SDs at 0.516 and 0.508 ( Z=-2.66, P=0.008). There were no significant differences among other groups. Conclusion:The selection of scanning mode, detector width and signal acquisition position of wide-detector CT will affect the image CT numbers and SDs.
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Objective To explore the distribution characteristics on z-axis of scattered radiation from a wide-detector CT with different scan modes and detector widths.Methods The CT standard-dose phantom was scanned using a 16 cm wide detector Revolution CT.Thermoluminescent dosimeters (TLDs)were placed on the central axis (z-axis) of the scan hole at given intervals.As scan modes,both axial scan mode (using detector with width in 4,8 or 16 cm) and the helical scan mode (using detector with width in 4 and 8 cm) are used.The scan parameters were as follows:tube voltage 120 kV;effective tube current 200 mAs;scan length 16 cm;pitch (for helical scan):0.984 ∶ 1 and 0.516 ∶ 1,and all scans were repeated for 4 times.All TLDs were measured,after exposure,and divided by four for further analysis.Results The scattered radiation on z-axis was higher at the direction of human head than at the direction of human foot (Z=-2.366,-2.197,-2.366,-2.371,-2.028,-2.236,-2.028,P<0.05).Under the axial scan,the difference in distribution of scattered radiation with different detector widths was statistically significant.The maximum increase for detector width of 4 cm and 16 cm was 67.5 μ Gy(x2=28.000,P<0.05).Under the helical scan,the difference in distribution of scattered radiation with different detector widths was statistically significant (Z =-3.233,-2.982,P<0.05).The largest distribution of scattered radiation was found when the detector width was 8 cm and the smallest at the detector width is 4 cm.The maximum increase for detector width of 8 and 4 cm was 97.67 μGy at a pitch of 0.516 ∶ 1.Furthermore,when the detector width and effective mAs were the same,the scattered radiation at a pitch of 0.516∶1 was greater than that at a pitch of 0.984 ∶ 1,with the statistically significant difference(Z =-3.296,-3.296,P<0.05).The maximum increase was 49.95 μGy when the detector width was 8 cm.Conclusions In a 16 cm wide-detector CT,the selection of different detector widths can significantly influence the distribution of radiation field and related radiation values.Suitable detector width and relevant parameters shall be chosen according to the specific clinical requirements so as to reduce the radiation doses to workers,patients and carers.