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Abstract

Background

Low tube potential-high tube current computed tomography (CT) imaging allows reduction in iodine-based contrast dose and may extend the benefit of routine contrast-enhanced CT exams to patients at risk of nephrotoxicity.

Purpose

To determine the ability of an iodine contrast reduction algorithm to maintain diagnostic image quality for contrast-enhanced abdominal CT.

Material and Methods

CT exams with iodine contrast reduction were prescribed for patients at risk for renal dysfunction. The iodine contrast reduction algorithm combines weight-based contrast volume reduction with patient width-based low tube potential selection and bolus-tracking. Control exams with routine iodine dose were selected based on weight, width, and scan protocol. Three radiologists evaluated image quality and diagnostic confidence using a 4-point scale (<2 acceptable). Another radiologist assessed contrast reduction indications and measured portal vein and liver contrast-to-noise ratios.

Results

Forty-six contrast reduction algorithm and control exams were compared (mean creatinine 1.6 vs. 1.2 mg/dL, P ≤ 0.0001). Thirty-nine contrast reduction patients had an eGFR <60 mL/min/1.73m² and 15 had single or transplanted kidney. Mean iodine contrast dose was lower in the contrast reduction group (20.9 vs. 39.4 g/mL, P < 0.0001). Diagnostic confidence was rated as acceptable in 95% (131/138) of contrast reduction and 100% of control exams (1.18–1.28 vs. 1.02–1.13, respectively; P > 0.06). Liver attenuation and contrast-to-noise ratio (CNR) were similar (P = 0.08), but portal vein attenuation and CNR were lower with contrast-reduction (mean 176 vs. 198 HU, P = 0.02; 13 vs. 16, P = 0.0002).

Conclusion

This size-based contrast reduction algorithm using low kV and bolus tracking reduced iodine contrast dose by 50%, while achieving acceptable image quality in 95% of exams.

Keywords

Iodine renal insufficiency X-ray computed tomography

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References

Intravenous contrast: friend or foe? A review on contrast-induced nephropathy. Adv Chronic Kidney Dis 2017; 24:147–149.

Luk

Steinman

Newhouse

JH.

Intravenous contrast-induced nephropathy-the rise and fall of a threatening idea. Adv Chronic Kidney Dis 2017; 24:169–175.

McDonald

Carter

, et al. Intravenous contrast material exposure is not an independent risk factor for dialysis or mortality. Radiology 2014; 273:714–725.

Wilhelm-Leen

Montez-Rath

Chertow

Estimating the risk of radiocontrast-associated nephropathy. J Am Soc Nephrol 2017; 28:653–659.

Nash

Hafeez

Hou

Hospital-acquired renal insufficiency. Am J Kidney Dis 2002; 39:930–936.

ACR Manual on Contrast Media, Version 9. Available at: http://www.acr.org/quality-safety/resources/contrast-manual

Stacul

van der Molen

Reimer

, et al. Contrast induced nephropathy: updated ESUR Contrast Media Safety Committee guidelines. European Radiology 2011; 21:2527–2541.

Vasconcelos

Vrtiska

Foley

, et al. Reducing iodine contrast volume in CT angiography of the abdominal aorta using integrated tube potential selection and weight-based method without compromising image quality. AJR Am J Roentgenol 2017; 208:552–563.

Durmus

Rogalla

Lembcke

, et al. Low-dose triple-rule-out using 320-row-detector volume MDCT–less contrast medium and lower radiation exposure. Eur Radiol 2011; 21:1416–1423.

10.

Nijhof

Baltussen

Kant

, et al. Low-dose CT angiography of the abdominal aorta and reduced contrast medium volume: Assessment of image quality and radiation dose. Clin Radiol 2016; 71:64–73.

11.

Wichmann

Kerl

, et al. 70 kVp computed tomography pulmonary angiography potential for reduction of iodine load and radiation dose. Journal of Thoracic Imaging 2015; 30:69–76.

12.

Hough DM, Fletcher JG, Grant KL, et al. Lowering kilovoltage to reduce radiation dose in contrast-enhanced abdominal CT: initial assessment of a prototype automated kilovoltage selection tool. AJR Am J Roentgenol 2012;199:1070–1077.

13.

Shen

Zou

, et al. Did low tube voltage CT combined with low contrast media burden protocols accomplish the goal of “double low” for patients? An overview of applications in vessels and abdominal parenchymal organs over the past 5 years. Int J Clin Pract 2016; 70:B5–B15.

14.

Nakaura

Awai

Maruyama

, et al. Abdominal dynamic CT in patients with renal dysfunction: contrast agent dose reduction with low tube voltage and high tube current-time product settings at 256-detector row CT. Radiology 2011; 261:467–476.

15.

Aschoff

Catalano

Kirchin

, et al. Low radiation dose in computed tomography: the role of iodine. Br J Radiol 2017; 90:20170079.

16.

Hough DM, Yu L, Shiung MM, et al. Individualization of abdominopelvic CT protocols with lower tube voltage to reduce i.v. contrast dose or radiation dose. AJR Am J Roentgenol 2013;201:147–153.

17.

Hunsaker

Oliva

Cai

, et al. Contrast opacification using a reduced volume of iodinated contrast material and low peak kilovoltage in pulmonary CT angiography: Objective and subjective evaluation. AJR Am J Roentgenol 2010; 195:W118–124.

18.

Nakayama

Awai

Funama

, et al. Lower tube voltage reduces contrast material and radiation doses on 16-MDCT aortography. AJR Am J Roentgenol 2006; 187:W490–497.

19.

Utsunomiya

Oda

Funama

, et al. Comparison of standard- and low-tube voltage MDCT angiography in patients with peripheral arterial disease. Eur Radiol 2010; 20:2758–2765.

20.

Yanaga

Awai

Nakaura

, et al. Hepatocellular carcinoma in patients weighing 70 kg or less: initial trial of compact-bolus dynamic CT with low-dose contrast material at 80 kVp. AJR Am J Roentgenol 2011; 196:1324–1331.

21.

Nakaura

Nakamura

Maruyama

, et al. Low contrast agent and radiation dose protocol for hepatic dynamic CT of thin adults at 256-detector row CT: effect of low tube voltage and hybrid iterative reconstruction algorithm on image quality. Radiology 2012; 264:445–454.

22.

Meinel

Canstein

Schoepf

, et al. Image quality and radiation dose of low tube voltage 3rd generation dual-source coronary CT angiography in obese patients: a phantom study. Eur Radiol 2014; 24:1643–1650.

23.

Froemming

Kawashima

Takahashi

, et al. Individualized kV selection and tube current reduction in excretory phase computed tomography urography: potential for radiation dose reduction and the contribution of iterative reconstruction to image quality. J Comput Assist Tomogr 2013; 37:551–559.

24.

Namimoto

Oda

Utsunomiya

, et al. Improvement of image quality at low-radiation dose and low-contrast material dose abdominal CT in patients with cirrhosis: intraindividual comparison of low tube voltage with iterative reconstruction algorithm and standard tube voltage. J Comput Assist Tomogr 2012; 36:495–501.

25.

Noda

Kanematsu

Goshima

, et al. Reducing iodine load in hepatic CT for patients with chronic liver disease with a combination of low-tube-voltage and adaptive statistical iterative reconstruction. Eur J Radiol 2015; 84:11–18.

26.

Kanematsu

Goshima

Kawai

, et al. Low-iodine-load and low-tube-voltage CT angiographic imaging of the kidney by using bolus tracking with saline flushing. Radiology 2015; 275:832–840.

Image quality in abdominal CT using an iodine contrast reduction algorithm employing patient size and weight and low kV CT technique

Abstract

Background

Purpose

Material and Methods

Results

Conclusion

Keywords

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References