Evaluation of PCD-CT Based Image Parameters in the Assessment and Quantification of Coronary Artery Disease

Not yet recruiting

• Conditions: Coronary Artery Disease
• Interventions: Diagnostic Test: Photon Counting Detector Coronary Computed Tomography Angiography

• Registration Number: NCT05877768
• Lead Sponsor: University Medical Center Mainz

Brief Summary

The goal of this observational study is to learn about a new type of computed tomography (Photon-Counting Detector CT) in patients with coronary artery disease.

The main questions it aims to answer are:

* How good is the image quality for the new CT

* How accurate are measurements in the images of the new CT

* Is there a relationship between measurements in the images and the management of the disease (e.g. new medication or additional investigations)

* Is there a relationship between measurements in the images and the results of follow-up investigations

* Is there a relationship between measurements in the images and the patient outcome

Participants will undergo normal clinical assessment of coronary artery disease and all data from the CT scan and additional investigations will be collected. There will be no additional investigations for the purpose of the study. After 1, 2 and 5 years, participants will be asked to answer a health questionaire.

Detailed Description

Not available

Study Timeline

• Status Verified: 2023-05
• Study First Submitted: 2023-05-10
• Study First Submitted QC: 2023-05-23
• Last Update Submitted: 2023-05-23
• Study First Posted: 2023-05-26
• Last Update Posted: 2023-05-26
• Study Start: 2023-06-30
• Primary Completion: 2033-06-30
• Study Completion: 2033-06-30

Recruitment & Eligibility

• Status: NOT_YET_RECRUITING
• Sex: All
• Target Recruitment: 3000

Inclusion Criteria

• Clinical indication for a coronary computed tomography angiography (CCTA) for the suspicion of coronary artery disease or the progression thereof
• Written informed consent

Exclusion Criteria

• Contraindications preventing the execution of the CCTA (e.g., pregnancy)

Study & Design

• Study Type: OBSERVATIONAL
• Study Design: Not specified

Arm && Interventions

Group	Intervention	Description
Coronary Artery Disease	Photon Counting Detector Coronary Computed Tomography Angiography	Patients with suspected coronary artery disease and those with known coronary artery disease and the suspicion of progressive disease who undergo clinically indicated Coronary Computed Tomography Angiography on the Photon-Counting Detector CT will be enrolled after written consent. All data from the CT scan and potential additional investigations (e.g. invasive coronary angiographies) will be collected. There will be no additional investigations for the purpose of the study. After 1, 2 and 5 years, participants will be asked to answer a health questionaire.

Primary Outcome Measures

Name	Time	Method
Major Adverse Cardiac Events	From inclusion to a maximum follow-up of 5 years	Composite endpoint: major adverse cardiovascular event (MACE); defined as at least one of the following: cardiovascular death, nonfatal myocardial infarction, and nonfatal stroke.

Secondary Outcome Measures

Name	Time	Method
Subjective Image Noise of PCD-CCTA	during the PCD-CCTA examination	Image Noise of PCD-CCTA judged subjectively on a 5-point Likert scale.
Objective Vessel sharpness in PCD-CCTA	during the PCD-CCTA examination	Vessel sharpness in PCD-CCTA measured objectively using the slope of fitted double sigmoid curves (1/mm)
Subjective Image Quality in PCD-CCTA	during the PCD-CCTA examination	Subjective Image Quality in PCD-CCTA judged subjectively on a 5-point Likert scale.
Quantitative analysis of Coronary Calcium Scoring from PCD-CCTA	during the PCD-CCTA examination	Quantitative analysis of Coronary Calcium volume (mm\^3), mass (g) and resulting score according to the Agatston classification.
Influence of radiation dose on quantitative parameters of the PCD-CCTA	during the PCD-CCTA examination	Influence of radiation dose (mGy) on quantitative parameters of the PCD-CCTA
Subjective Vessel sharpness in PCD-CCTA	during the PCD-CCTA examination	Vessel sharpness in PCD-CCTA judged subjectively on a 5-point Likert scale.
Objective Image Quality in PCD-CCTA	during the PCD-CCTA examination	Objective Image Quality in PCD-CCTA measured objectively by contrast-to-noise ratio (HU/HU)
Influence of the patients heart rate on quantitative parameters of the PCD-CCTA	during the PCD-CCTA examination	Influence of the patients maximum, minimum and average heart rate (1/min) on quantitative parameters of the PCD-CCTA
Influence of kernel sharpness level on quantitative parameters of the PCD-CCTA	during the PCD-CCTA examination	Influence of kernel sharpness level (40-90) on quantitative parameters of the PCD-CCTA
Correlation of quantitative PCD-CCTA parameters with the results of additional imaging ischemia tests	Imaging ischemia tests within 3 months of initial PCD-CCTA	Correlation of quantitative PCD-CCTA parameters with imaging ischemia tests in patients who had both PCD-CCTA and one of the following tests done: stress echo, stress Single Photon Emission Computed Tomography (SPECT), stress Positron Emission Tomography (PET), and stress MRI.
Correlation of quantitative PCD-CCTA parameters with the results of additional other imaging tests	Imaging tests within 3 months of initial PCD-CCTA	Correlation of quantitative PCD-CCTA parameters with imaging tests in patients who had both PCD-CCTA and one of the following tests done: transthoracic echo, transesophageal echo, cardiac MRI.
Influence of slice thickness of reconstruction on image quality of the PCD-CCTA	during the PCD-CCTA examination	Influence of slice thickness of reconstruction (mm) on image quality of the PCD-CCTA
Influence of reconstruction kernel on image quality of the PCD-CCTA	during the PCD-CCTA examination	Influence of reconstruction kernel (Bv/Br/Qr) on image quality of the PCD-CCTA
Influence of kernel sharpness level on image quality of the PCD-CCTA	during the PCD-CCTA examination	Influence of kernel sharpness level (40-90) on image quality of the PCD-CCTA
Influence of radiation dose on image quality of the PCD-CCTA	during the PCD-CCTA examination	Influence of radiation dose (mGy) on image quality of the PCD-CCTA
Influence of the acquisition type on quantitative parameters of the PCD-CCTA	during the PCD-CCTA examination	Influence of the acquisition type (Sequential, Spiral, Ultra-High Resolution, Spectral) on quantitative parameters of the PCD-CCTA
Influence of the acquisition type on image quality of the PCD-CCTA	during the PCD-CCTA examination	Influence of the acquisition type (Sequential, Spiral, Ultra-High Resolution, Spectral) on image quality of the PCD-CCTA
Analysis of Stenosis Classification from PCD-CCTA	during the PCD-CCTA examination	Analysis of Coronary stenosis classification according to the Coronary Artery Disease-Reporting and Data System (CAD-RADS, 0-5, higher numbers indicating more severe stenosis).
Quantitative analysis of Coronary Diameter Stenoses from PCD-CCTA	during the PCD-CCTA examination	Quantitative analysis of Coronary Diameter Stenoses (%) from PCD-CCTA
Quantitative analysis of Coronary Area Stenoses from PCD-CCTA	during the PCD-CCTA examination	Quantitative analysis of Coronary Area Stenoses (%) from PCD-CCTA
Quantitative analysis of computed Fractional Flow Reserve from PCD-CCTA	during the PCD-CCTA examination	Quantitative analysis of computed Fractional Flow Reserve (absolute number) from PCD-CCTA.
Rates of patients undergoing further cardiac diagnostics	2 weeks after initial PCD-CCTA, 1-year follow-up, 2-year follow-up and final follow-up up to a max of 5 years	Rates of patients undergoing further cardiac diagnostics, such as additional CT or Invasive Coronary Angiography (ICA), Electrocardiography (ECG), Exercise ECG, Echo, Stress Echo, Magnetic Resonance Imaging (MRI) within 3 months following PCD-CCTA (defined as: related to these tests) and more than 3 months after PCD-CCTA until follow-up (unrelated to these tests).
Correlation and agreement of Percent diameter stenosis measurement from PCD-CCTA with Fractional Flow Reserve from ICA	ICA within 3 months of initial PCD-CCTA	Correlation and agreement of stenosis quantification by PCD-CCTA and invasive Fractional Flow Reserve.
Correlation and agreement of Plaque composition assessment from PCD-CCTA with intracoronary techniques	ICA within 3 months of initial PCD-CCTA	Correlation and agreement of Plaque composition assessment from PCD-CCTA in comparison to intracoronary techniques such as optical coherence tomography (OCT) in patients who had both tests done.
Quantitative analysis of myocardial density from PCD-CCTA	during the PCD-CCTA examination	Quantitative analysis of myocardial density (HU) from PCD-CCTA.
Rates of patients undergoing cardiac interventions	2 weeks after initial PCD-CCTA, 1-year follow-up, 2-year follow-up and final follow-up up to a max of 5 years	Cardiac interventions such as coronary revascularization by ICA, coronary artery bypass grafting (CABG), Valve replacement (operatively and interventional), other cardiothoracic surgeries, implantation of an cardioverter/defibrillator or cardiac resynchronization device, ablation, others
Patient management	at baseline, 1-year follow-up, 2-year follow-up and final follow-up up to a max of 5 years	Recommended and actually performed management based on PCD-CCTA
Correlation and agreement of quantitative measurements from PCD-CCTA with ICA	ICA within 3 months of initial PCD-CCTA	Correlation and agreement of percent diameter stenosis quantification by PCD-CCTA in comparison to quantitative assessment from ICA.
Correlation and agreement of non-invasive Fractional Flow Reserve from PCD-CCTA with invasive Fractional Flow Reserve from ICA	ICA within 3 months of initial PCD-CCTA	Correlation and agreement of non-invasively estimated Fractional Flow Reserve by Computed Tomography with invasive Fractional Flow Reserve
Quantitative analysis of myocardial iodine content from PCD-CCTA	during the PCD-CCTA examination	Quantitative analysis of myocardial iodine content (µg/cm\^3) from PCD-CCTA.
Quantitative analysis of extracellular volume fraction from PCD-CCTA	during the PCD-CCTA examination	Quantitative analysis of the extracellular volume fraction (%) from PCD-CCTA.
Influence of BMI on quantitative parameters of the PCD-CCTA	during the PCD-CCTA examination	Influence of Body Mass Index (BMI, kg/m\^2) on quantitative parameters of the PCD-CCTA
Influence of biological sex on quantitative parameters of the PCD-CCTA	during the PCD-CCTA examination	Influence of patients biological sex (male/female) on quantitative parameters of the PCD-CCTA
Influence of monoenergetic energy levels on quantitative parameters of the PCD-CCTA	during the PCD-CCTA examination	Influence of monoenergetic energy levels (keV) on quantitative parameters of the PCD-CCTA
Analysis of occurrence in Major Adverse Cardiac Events in subgroups	at baseline, 1-year follow-up, 2-year follow-up and final follow-up up to a max of 5 years	Composite outcome: Analysis of occurrence in MACE as a secondary outcome in following subgroups: CT plaque characteristic groups: high risk versus other plaques versus no plaques; Plaque burden groups: P1 vs. P2 vs. P3 vs. P4 according to the CAD-RADS 2.0 classification; Gender: male versus female; Age: occurrence of MACE in patient a) under 45 years, b) between 45 and 65 years and c) over 65 years; BMI: Patients with BMI a) under 25, b) between 25 and 30 and c) over 30;
Objective Assessment of Noise-Power Spectra of PCD-CCTA	during the PCD-CCTA examination	Image Noise of PCD-CCTA measured objectively using noise-power spectra (W/Hz).
Objective Image Noise of Photon-Counting Detector Coronary Computed Tomography Angiography (PCD-CCTA)	during the PCD-CCTA examination	Image Noise of PCD-CCTA measured objectively using measurements of CT values (HU).
Influence of BMI on image quality of the PCD-CCTA	during the PCD-CCTA examination	Influence of Body Mass Index (BMI, kg/m\^2) on image quality of the PCD-CCTA
Influence of biological sex on image quality of the PCD-CCTA	during the PCD-CCTA examination	Influence of patients biological sex (male/female) on image quality of the PCD-CCTA
Influence of monoenergetic energy levels on image quality of the PCD-CCTA	during the PCD-CCTA examination	Influence of monoenergetic energy levels (keV) on image quality of the PCD-CCTA
Influence of the patients heart rate on image quality of the PCD-CCTA	during the PCD-CCTA examination	Influence of the patients maximum, minimum and average heart rate (1/min) on image quality of the PCD-CCTA
Influence of slice thickness of reconstruction on quantitative parameters of the PCD-CCTA	during the PCD-CCTA examination	Influence of slice thickness of reconstruction (mm) on quantitative parameters of the PCD-CCTA
Influence of reconstruction kernel on quantitative parameters of the PCD-CCTA	during the PCD-CCTA examination	Influence of reconstruction kernel (Bv/Br/Qr) on quantitative parameters of the PCD-CCTA

Trial Locations

Locations (1)

University Medical Center Mainz; 🇩🇪 Mainz, Rhineland-Palatinate, Germany