Relationship Between Contrast Media Volume and Tube Voltage in CT for Optimal Liver Enhancement, Based on Body Weight.

Not Applicable

Completed

• Conditions: Radiation; Contrast Media; Liver; Body Weight
• Interventions: Radiation: Radiation dose reduction; Radiation: Unenhanced slice; Other: Contrast media volume reduction; Diagnostic Test: Weight

• Registration Number: NCT03735706
• Lead Sponsor: Maastricht University Medical Center

Brief Summary

Computed Tomography (CT) is widely used in abdominal imaging for a variety of indications. Contrast media (CM) is used to enhance vascular structures and organ parenchyma. Attenuation of the liver makes it possible to recognize hypo- and hypervascular lesions, which are often invisible on unenhanced CT images. Lesions can only be detected in case they are large enough and the contrast with the background is high enough. Heiken et al. showed already in 1995 that a difference in Hounsfield Units (HU) of at least 50 HU is needed to be able to recognize liver lesions \[1\]. On the other hand, patients should not receive more CM than necessarily, because of possible underlying physiological effects \[2-4\]. Although there has been some controversy about this recently, there is no need to give patients more CM than needed, because of increased costs, no quality improvement and their might still be a relationship with contrast induced nephropathy (CIN) \[5\].

Recent publications suggested individualization of injection protocols that can be based on either total body weight (TBW) or lean body weight (LBW) \[6-9\]. In the investigators department an injection protocol based on TBW is currently used.

Besides the CM injection parameters, scanner parameters are of influence on the attenuation as well. Because of recent technical developments it became possible to reach a good image quality (IQ) at lower tube voltages \[10\]. When the x-ray output comes closer to the 33 keV k-edge of Iodine, attenuation increases. In short, decreasing the tube voltage increases the attenuation of iodine. Scanning at a lower tube voltage therefore gives rise to even lower CM volumes. Lastly, it would be revolutionary to accomplish a liver enhancement that is homogenous, sufficient for lesion detection and comparable between patients and in the same patients, regardless of weight and scanner settings used.

Detailed Description

Computed Tomography (CT) is a non-invasive imaging tool, used for a great variety of indications. Contrast media (CM) is used to enhance vascular structures and organ parenchyma. The visibility of liver lesions depends mainly on the ratio between the size and the difference of the lesion to the background. A large lesion might be visible without administration of CM, whilst a smaller lesion needs the addition of CM to become visible. Additionally, CM can be useful in the characterization of liver lesions. Heiken et al. (1995) found that an attenuation of the parenchyma after CM administration of at least ∆ 50 Hounsfield units (HU) compared to an unenhanced scan (in the same patient) is necessary to recognize liver lesions. This study proposed a dosing factor of 0.521 g I/kg to be necessary to reach such attenuation at a tube voltage of 120 kV \[1\].

The parenchymal enhancement depends on patient, CT scanner and CM factors. Weight, height, cardiac output, age, gender, venous access, breath-holding, renal function and comorbidity all fall under patient factors \[8\]. Recently much research showed preferable outcomes for individualized CM injection protocols, in which the contrast bolus is adapted to patient TBW, LBW or body surface area (BSA) \[6, 7, 9, 13-15\]. In a recent feasibility study in the department of the investigators, the attenuation of the liver parenchyma was evaluated. Results showed that a body weight adapted CM injection protocol resulted in more homogeneous liver enhancement compared to a fixed CM dose (not published yet).

With recent technological developments in X-ray tube technology it became possible to use lower tube voltages. As a result making it possible to perform scans with a sufficient image quality (IQ) and a low tube voltage and therefore a lower radiation dose \[10\]. Another advantage lies in the fact that reducing the tube voltage, approaching 33 keV k-edge of iodine, results in an increase in attenuation of the iodine. The new technological developments make it possible to reduce the radiation dose and CM volume at the same time. So reducing the tube voltage, makes it also possible to reduce the CM volume.

As recommended by the supplier, it is possible to calculate the total iodine load (TIL) that can be spared with the use of lower kV settings \[16\]. A reduction of 10 kV should result in a 10% reduction in CM volume. Reducing the tube voltage from 120 to 90 kV should therefore lead to a 30% reduction in CM volume. As mentioned before it is preferred to use an individualized CM injection protocol based on TBW or LBW. For this study, this theory is adapted to the concept of TBW. The following indicates which dosing factors should be used for each kV setting, based on the recommendations mentioned in the above.

120 kV -\> 0.521 g I/kg 110 kV -\> 0.469 g I/kg 100 kV -\> 0.417 g I/kg 90 kV -\> 0.365 g I/kg 80 kV -\> 0.313 g I/kg 70 kV -\> 0.261 g I/kg

The aim of present study is to investigate if adapting the dosing factor based on TBW and therefore the CM volume to the tube voltage used, results in a more homogeneous liver enhancement. The hypothesis is to find a more homogeneous enhancement between patients and in the same patient, regardless of body composition and tube voltage used.

Study Timeline

• Study First Submitted: 2018-10-31
• Study First Submitted QC: 2018-11-07
• Study First Posted: 2018-11-08
• Study Start: 2018-12-13
• Primary Completion: 2019-06-26
• Study Completion: 2019-06-26
• Status Verified: 2020-02
• Last Update Submitted: 2020-02-06
• Last Update Posted: 2020-02-10

Recruitment & Eligibility

• Status: COMPLETED
• Sex: All
• Target Recruitment: 245

Inclusion Criteria

• Patients referred for abdominal CT in portal venous phase
• Patients ≥ 18 years and competent to sign an informed consent

Exclusion Criteria

• Hemodynamic instability
• Pregnancy
• Renal insufficiency (defined as Glomerular Filtration Rate (GFR) < 30 mL/min/1,73m2 [Odin protocol 004720])
• Iodine allergy (Odin protocol 022199)
• Age <18 years
• Absence of informed consent

Study & Design

• Study Type: INTERVENTIONAL
• Study Design: PARALLEL

Arm && Interventions

Group	Intervention	Description
90 kV - 0.521 g I/kg	Radiation dose reduction	Weight is measured prior to the scan. Before performing the contrast enhanced CT scan(s), an unenhanced slice through the liver, at the level of the portal vein, is performed. Contrast media injection protocol with a standard dosing factor of 0.521 g I/kg of TBW. A radiation dose reduction from 120 to 90 kV. The intervention is a change in tube voltage to 90 kV, compared to group 1. The other intervention; contrast media volume, is unchanged compared to group 1.
100 kV - 0.417 g I/kg	Radiation dose reduction	Weight is measured prior to the scan. Before performing the contrast enhanced CT scan(s), an unenhanced slice through the liver, at the level of the portal vein, is performed. Contrast media volume reduction with a dosing factor of 0.417 g I/kg of TBW. A radiation dose reduction from 120 to 100 kV compared to group 1. The intervention is a change in tube voltage to 100 kV, compared to group 1. The other intervention is a change in contrast media volume, which is adapted to the tube voltage used and therefore lowered to 0.417 g I/kg.
90 kV - 0.365 g I/kg	Contrast media volume reduction	Weight is measured prior to the scan. Before performing the contrast enhanced CT scan(s), an unenhanced slice through the liver, at the level of the portal vein, is performed. Contrast media volume reduction with a dosing factor of 0.365 g I/kg of TBW. A radiation dose reduction from 120 to 90 kV compared to group 1. The intervention is a change in tube voltage to 90 kV, compared to group 1. The other intervention is a change in contrast media volume, which is adapted to the tube voltage used and therefore lowered to 0.365 g I/kg.
Control group - 120 kV - 0.521 g I/kg	Weight	Weight is measured prior to the scan. Before performing the contrast enhanced CT scan(s), an unenhanced slice through the liver, at the level of the portal vein, is performed. Contrast media injection protocol with a standard dosing factor of 0.521 g I/kg of TBW and a tube voltage of 120 kV. The intervention is the application of a standard contrast media volume and a standard tube voltage of 120 kV.
Control group - 120 kV - 0.521 g I/kg	Unenhanced slice	Weight is measured prior to the scan. Before performing the contrast enhanced CT scan(s), an unenhanced slice through the liver, at the level of the portal vein, is performed. Contrast media injection protocol with a standard dosing factor of 0.521 g I/kg of TBW and a tube voltage of 120 kV. The intervention is the application of a standard contrast media volume and a standard tube voltage of 120 kV.
90 kV - 0.521 g I/kg	Weight	Weight is measured prior to the scan. Before performing the contrast enhanced CT scan(s), an unenhanced slice through the liver, at the level of the portal vein, is performed. Contrast media injection protocol with a standard dosing factor of 0.521 g I/kg of TBW. A radiation dose reduction from 120 to 90 kV. The intervention is a change in tube voltage to 90 kV, compared to group 1. The other intervention; contrast media volume, is unchanged compared to group 1.
100 kV - 0.417 g I/kg	Unenhanced slice	Weight is measured prior to the scan. Before performing the contrast enhanced CT scan(s), an unenhanced slice through the liver, at the level of the portal vein, is performed. Contrast media volume reduction with a dosing factor of 0.417 g I/kg of TBW. A radiation dose reduction from 120 to 100 kV compared to group 1. The intervention is a change in tube voltage to 100 kV, compared to group 1. The other intervention is a change in contrast media volume, which is adapted to the tube voltage used and therefore lowered to 0.417 g I/kg.
100 kV - 0.417 g I/kg	Weight	Weight is measured prior to the scan. Before performing the contrast enhanced CT scan(s), an unenhanced slice through the liver, at the level of the portal vein, is performed. Contrast media volume reduction with a dosing factor of 0.417 g I/kg of TBW. A radiation dose reduction from 120 to 100 kV compared to group 1. The intervention is a change in tube voltage to 100 kV, compared to group 1. The other intervention is a change in contrast media volume, which is adapted to the tube voltage used and therefore lowered to 0.417 g I/kg.
90 kV - 0.365 g I/kg	Radiation dose reduction	Weight is measured prior to the scan. Before performing the contrast enhanced CT scan(s), an unenhanced slice through the liver, at the level of the portal vein, is performed. Contrast media volume reduction with a dosing factor of 0.365 g I/kg of TBW. A radiation dose reduction from 120 to 90 kV compared to group 1. The intervention is a change in tube voltage to 90 kV, compared to group 1. The other intervention is a change in contrast media volume, which is adapted to the tube voltage used and therefore lowered to 0.365 g I/kg.
90 kV - 0.521 g I/kg	Unenhanced slice	Weight is measured prior to the scan. Before performing the contrast enhanced CT scan(s), an unenhanced slice through the liver, at the level of the portal vein, is performed. Contrast media injection protocol with a standard dosing factor of 0.521 g I/kg of TBW. A radiation dose reduction from 120 to 90 kV. The intervention is a change in tube voltage to 90 kV, compared to group 1. The other intervention; contrast media volume, is unchanged compared to group 1.
100 kV - 0.417 g I/kg	Contrast media volume reduction	Weight is measured prior to the scan. Before performing the contrast enhanced CT scan(s), an unenhanced slice through the liver, at the level of the portal vein, is performed. Contrast media volume reduction with a dosing factor of 0.417 g I/kg of TBW. A radiation dose reduction from 120 to 100 kV compared to group 1. The intervention is a change in tube voltage to 100 kV, compared to group 1. The other intervention is a change in contrast media volume, which is adapted to the tube voltage used and therefore lowered to 0.417 g I/kg.
90 kV - 0.365 g I/kg	Unenhanced slice	Weight is measured prior to the scan. Before performing the contrast enhanced CT scan(s), an unenhanced slice through the liver, at the level of the portal vein, is performed. Contrast media volume reduction with a dosing factor of 0.365 g I/kg of TBW. A radiation dose reduction from 120 to 90 kV compared to group 1. The intervention is a change in tube voltage to 90 kV, compared to group 1. The other intervention is a change in contrast media volume, which is adapted to the tube voltage used and therefore lowered to 0.365 g I/kg.
90 kV - 0.365 g I/kg	Weight	Weight is measured prior to the scan. Before performing the contrast enhanced CT scan(s), an unenhanced slice through the liver, at the level of the portal vein, is performed. Contrast media volume reduction with a dosing factor of 0.365 g I/kg of TBW. A radiation dose reduction from 120 to 90 kV compared to group 1. The intervention is a change in tube voltage to 90 kV, compared to group 1. The other intervention is a change in contrast media volume, which is adapted to the tube voltage used and therefore lowered to 0.365 g I/kg.

Primary Outcome Measures

Name	Time	Method
A liver attenuation (Δ HU)	Measurement for each scan is performed withing 1 month after the scan.	The attenuation of the liver parenchyma as assessed by measuring the Hounsfield units (HU) of the liver parenchyma in an unenhanced CT scan and a scan in portal venous phase. The difference between the enhanced and unenhanced CT scan is the Δ HU. It is expected that scans in all groups have a Δ HU of at least 50 HU, which is considered sufficient. Therefore it is a non-inferiority outcome.

Secondary Outcome Measures

Name	Time	Method
Objective image quality - signal-to-noise and contrast-to-noise ratio	Measurement for each scan is performed within 1 month after the scan.	The objective image quality parameters consist of signal-to-noise ratio (SNR) and contrast-to-noise ratio (CNR). SNR is calculated by dividing the attenuation of the liver parenchyma by the corresponding standard deviation (SD) of the attenuation. The attenuation of the left erector spinae muscle is measured at the level of the liver to calculate CNR using the following established formula: liver segment attenuation minus intramuscular attenuation, divided by the SD of the intramuscular attenuation. For both a higher number indicated a better image quality. The outcome should not be significantly different between groups.
Weight	Directly prior to the scan it is measured and data is collected within one month after the scan.	Patients weight (in kg) is assessed by using a weighting scale
Contrast media volume	Data is retrieved from the system within 1 month after the scan.	A dedicated data acquisition program (Certega Informatics Solution; Bayer) continuously monitors and collects all injection parameters (eg, total amount of CM \[milliliter\] and peak flow rate \[milliliter per seconds\]). A higher number means a higher radiation dose and is therefore a worse outcome. And results are compared between groups.
BMI	Calculated after the scan, within 1 month after the scan.	Weight and height will be combined to report BMI in kg/m\^2
Sex	Collected before the scan by the technician and retrieved from the system within 1 month after the scan.	Is collected
Scan indication	Collected before the scan by the technician and retrieved from the system within 1 month after the scan.	Is collected
Subjective image quality - assessed with a 5-point Likert scale	Measurement for each scan is performed within 1 month after the scan.	Two experienced radiologists will assess the subjective image quality in consensus, while being blinded for the protocol used. A 5-point Likert scale is used, in which 1= excellent; 2= good; 3 = moderate; 4 = poor; 5 = very poor. So a higher number is a worse outcome. The scale does not have a particular name.
Height (in m)	Directly prior to the scan it is measured and data is collected within one month after the scan.	Patients height is asked
Radiation dose	Measurement for each scan is performed within 1 month after the scan.	The mean effective mAs (± SD), mean CTDIvol (mGy) (± SD) and the Mean DLP (mGy\*cm) (± SD) are visible on screen and reported, to compare the difference in radiation dose between groups. A higher number means a higher radiation dose and is therefore a worse outcome.
Needle placement	Data is retrieved from the system within 1 month after the scan.	A dedicated data acquisition program (Certega Informatics Solution; Bayer) continuously monitors and collects all injection parameters, among which needle placement is one of the parameters. In general it is expected that the needle placement is not significantly different between groups.
Age	Collected before the scan by the technician and retrieved from the system within 1 month after the scan.	Is collected
Flow rate	Data is retrieved from the system within 1 month after the scan.	A dedicated data acquisition program (Certega Informatics Solution; Bayer) continuously monitors and collects peak flow rate \[milliliter per seconds\]).
Needle size	Data is retrieved from the system within 1 month after the scan. It is finished when all patients are scanned.	A dedicated data acquisition program (Certega Informatics Solution; Bayer) continuously monitors and collects all injection parameters, among which needle size is one of the parameters. A smaller gauge of the needle could possibly mean that the desired flow rate is not possible. In general it is expected that the needle size used is not significantly different between groups.
Concentration of the contrast media	Data is retrieved from the system within 1 month after the scan.	All patients receive the identical contrast media concentration as used in daily clinical routine; 300 mg/ml

Trial Locations

Locations (1)

MUMC+; 🇳🇱 Maastricht, Limburg, Netherlands