Publication

Image quality and radiation dose of dual-energy CT of the head and neck compared with a standard 120-kVp acquisition

Journal Paper/Review - Sep 8, 2011

Units
PubMed
Doi

Citation
Tawfik A, Kerl J, Razek A, Bauer R, Nour-Eldin N, Vogl T, Mack M. Image quality and radiation dose of dual-energy CT of the head and neck compared with a standard 120-kVp acquisition. AJNR Am J Neuroradiol 2011; 32:1994-9.
Type
Journal Paper/Review (English)
Journal
AJNR Am J Neuroradiol 2011; 32
Publication Date
Sep 8, 2011
Issn Electronic
1936-959X
Pages
1994-9
Brief description/objective

BACKGROUND AND PURPOSE
DECT offers additional image datasets with potential benefits, but its use for H&N imaging is not justified unless image quality is preserved without increased radiation dose. The aim of this work was to compare image quality and radiation dose between a DE-derived WA image dataset and a standard SECT acquisition of the H&N.

MATERIALS AND METHODS
Thirty-two patients underwent DECT of the H&N (tube voltages 80 and Sn140 kVp) and were compared with the last 32 patients who underwent standard SECT (120 kVp) on the same dual-source scanner. WA images from the 2 DE tubes were compared with images obtained with an SE mode. Radiation doses and attenuation measurements of the internal jugular vein, submandibular gland, and sternomastoid and tongue muscles were compared. Objective image noise was compared at 5 anatomic levels. Two blinded readers compared subjective image quality by using 5-point grading scales.

RESULTS
CTDI(vol) was 12% lower with DE than with SECT, a difference of 1.5 mGy, (P < .0001). Objective noise was not significantly different between DE and SECT at any of the anatomic levels (P > .05). No significant differences in attenuation measurements were observed between DE and SECT (P > .05). No significant differences in subjective image quality scores were observed between DE and SECT at any of the 5 anatomic levels (P > .05).

CONCLUSIONS
DE-derived WA images of the H&N are equivalent to standard SE acquisitions and thus can be used for routine diagnostic purposes. Multiple additional image datasets can be obtained with no radiation dose penalty.