Low-Tube-Voltage 80-kVp Neck CT: Evaluation of Diagnostic Accuracy and Interobserver Agreement

Patient Selection and Study Design

This retrospective study was approved by the ethics committee of our hospital, and written informed consent was waived. Of 404 clinically indicated neck DECT examinations performed between February 2010 and November 2010 at our institution, we included 170 consecutive examinations. During that timeframe, neck CT examinations were performed by using 2 different CT systems at our facility; only the patients scanned by using the dual-source system capable of DECT mode were included in this study. However, assignment to either scanner was completely random on the basis of available timeslots and was not influenced for research purposes.

Contraindications for DECT imaging were known allergies to iodinated contrast material, pregnancy, and impaired renal function (estimated glomerular filtration rate below 40 mL/min). Exclusion criteria for this study were age younger than 18 years (n = 15), noncontrast studies (n = 4), CT angiography examinations (n = 26), and severe motion (n = 21) or metal artifacts (n = 49) in case-relevant anatomic regions. Furthermore, to retain study group homogeneity, we excluded patients referred for evaluation of cervical metastasis from distal neoplasms (n = 6). In case a patient underwent multiple DECT examinations during this timeframe, we included only the first examination and excluded subsequent studies (n = 113).

To simulate routine clinical practice, we aggregated 3 main groups of indications for imaging: SCC-related (group 1, n = 107), lymphoma-related (group 2, n = 40), and benign conditions (group 3, n = 23). Groups 1 and 2 included CT examinations for the primary staging of known malignancy, detection of suspected malignancy, and follow-up CT to rule out recurrence. Patients with follow-up DECT were only included if the prior non-DECT scan did not show a recurrent SCC or pathologically enlarged lymph nodes in patients with known lymphoma to avoid miscategorizing patients with tumor remnants as having recurrent tumors. Group 3 consisted of patients referred for detection or evaluation of suspected benign conditions (eg, para-/retropharyngeal abscess, sialadenitis with possible sialolithiasis, Warthin tumor). A detailed list of indications for CT is summarized in Table 1.

The criterion standard in this study for comparison of observer results was based on the combination of the electronic medical records, results from histopathology, and the original CT imaging report, ranked in that order. However, because the original CT imaging reports of the evaluated scans may have resulted in false-positive or false-negative findings, especially in initial and follow-up examinations of patients with SCC, we ranked the final clinical diagnosis first because it also included clinical knowledge from physical examinations and biopsy; correlation with clinical diagnosis is especially important in SCC of the oral cavity, for example, which may be missed on neck CT. Thus, a final diagnosis of recurrent head-neck SCC based on histopathologic findings overruled a false-negative or uncertain finding in the original CT imaging report.

DECT Protocol

All CT examinations in this study were performed by using a second-generation 128-section dual-source CT in dual-energy mode (Somatom Definition Flash; Siemens, Erlangen, Germany). Both x-ray tubes were operated at a different tube potential. Examination parameters were as follows: tube A: 80 kVp, reference current-time product of 302 mAs per rotation; tube B: Sn140 kVp with a tin filter; 151 mAs per rotation; rotation time, 0.5 seconds; pitch, 0.9; collimation, 2 × 64 × 0.6 mm. Real-time automatic milliampere-second-modulation software (CareDose4D; Siemens) was used to regulate the tube current, depending on the patient's anatomy. Images were acquired in a craniocaudal direction in expiratory breath-hold with the patient in a supine position. The scan range extended from the upper orbital rim to the aortic arch. DECT imaging was initiated 70 seconds after the start of intravenous administration of 100 mL of nonionic iodinated contrast agent (iopamidol, Imeron 400; Bracco-Altana Pharma, Konstanz, Germany) through an antecubital vein at a flow rate of 2 mL/s.

On the basis of the DECT raw data, the scanner automatically reconstructed an image series with a standard linear blending setting (M_0.3), merging 30% of the 80-kVp and 70% of the 140-kVp data spectrum, representing a 120-kVp acquisition. All images were reconstructed with a dedicated dual-energy medium-soft convolution kernel (D30f) and a section thickness of 2.0 mm. Evaluation of image series was limited to axial images, and multiplanar reformations were not assessed. Quantitative DECT data were also not analyzed in this study.

Image Analysis

Initially only the 80-kVp image series was evaluated on a regular PACS workstation by 3 radiologists with 7, 3, and 2 years of experience in neck CT, respectively. All image series were assessed in random order. To avoid potential recall bias, readers were aware of the indication for CT imaging but were blinded to any other clinical information or auxiliary image series (ie, prior imaging studies). Readers were allowed to scroll through the whole stack of CT images. Window settings were automatically set to predetermined standard values for evaluation of soft tissue (width, 400 Hounsfield units; level, 80 Hounsfield units) but were freely adjustable. After a time interval of 12 weeks, all blended 120-kVp images from these cases were evaluated by the same readers in the same fashion and random order to allow an assessment of the diagnostic accuracy of a standard 120-kVp acquisition.

Radiation Dose Estimations

Examination protocols were evaluated, and the resulting volume CT dose index (CTDI_vol) and dose-length-product (DLP) were recorded for each scan. Currently, examination protocols provided by the second-generation dual-source CT scanner used in this study only display cumulative CTDI_vol and DLP values when scans are obtained in dual-energy mode and do not allow a further division of emitted radiation between both tubes with different voltage settings. However, to allow an intraindividual analysis of the estimated radiation dose without additional radiation exposure and to avoid potential bias among different study groups, we used dedicated software designed specifically for this study so that all DICOM datasets and CTDI_vol values of each of the 80-kVp series were extracted and averaged. CTDI_vol values are, in great part, also present in the patient protocols of each examination, which are usually used for analysis of the radiation dose. The given DLP of the cumulative DECT examination was divided by the cumulative CTDI_vol to calculate a conversion factor. The calculated mean CTDI_vol of the 80-kVp series based on the extracted data was then multiplied by this conversion factor to calculate the resulting estimated DLP for the low-tube-voltage acquisition.

Statistical Analysis

All statistical analyses were conducted by using dedicated software (SPSS, Version 21; IBM, Armonk, New York; and MedCalc for Windows, Version 13; MedCalc Software, Mariakerke, Belgium). Sensitivity, specificity, positive predictive value (PPV), and negative predictive value (NPV) were calculated for each observer and type of image series. The means and SDs of metric data were calculated. The paired t test was used to compare the CTDI_vol and DLP between the calculated values of the 80-kVp tube and the cumulative dual-energy CT examination. A P value < .05 indicated a statistically significant difference for all used tests.

Interobserver agreement among the 3 radiologists was evaluated by using intraclass correlation coefficient (ICC) statistics. Cumulative and subgroup-related ICC values were calculated. The ICC value was interpreted in the following way: ICC < 0.20, slight agreement; ICC = 0.21–0.40, fair agreement; ICC = 0.41–0.60, moderate agreement; ICC = 0.61–0.80, substantial agreement; ICC = 0.81–1.0, almost perfect agreement.