Geometrical Influences on Atherosclerosis and Blood Flow

The locally adapted workflow for the identification of high-risk atherosclerotic plaques that may cause Acute Coronary Syndrome (ACS) based on the integration of CCT and CFD is carried out systematically. These are the steps in the presented methodology, namely, the patient cohort, imaging, data handling and analysis, CFD simulation, and clinical implementation.

Firstly, select patients based on symptoms of coronary artery disease (CAD), high-risk factors (e.g., family history, hypertension, diabetes), or those requiring further evaluation after preliminary tests and then Preparation: Give drugs to achieve a proper rate of heartbeat. The order includes checking the patient's habits for proper hydration and contraindications to the use of contrast media. If investigators read this, then follow CCT imaging protocol. Conduct CCT with the help of a multi-detector CT scanner only. Take detailed images of the coronary arteries. Plan to administer iodinated contrast material to improve the visual display of coronary arteries. Moreover, electrocardiographic gating ensures the timely exposure of the patient's heart to radiation during the cardiac cycle to minimize motion. All the above processes have to be accomplished then the remaining work is taken care of by Mimics and Ansys Simulation software. Create reconstructions of the coronary arteries using Ansys software and out of the CCT data that was acquired. Grasp positive remodeling, low attenuation plaque, napkin ring sign, and spotty calcification in atherosclerotic plaques. Document the features that were noticed about the plaques that are in the identified places; the sizes and the shapes and the location certainly. The working process is, to a large extent, sequential. When one of them is absent the other does not work, or does not operate within the protocol, we do not discover our result. Following that, ''Cut out' the coronary artery regions of interest from the reconstructed 3D images. Develop a mesh based on the segmented coronary artery regions. This entails the segmentation of the artery into small parts that are useful in making a CFD analysis. CFD Simulation has some conditions that are important for the results of the research.

Boundary Conditions: Define physiological boundary conditions, such as blood flow rates, pressure, and velocity, based on patient-specific data.

Simulation: Configure the CFD software with the segmented geometry and boundary conditions. Run the CFD simulations to calculate hemodynamic parameters, including wall shear stress (WSS), and flow velocity profiles.

Data Analysis: Analyze the CFD results to understand the hemodynamic environment within the coronary arteries and identify regions with abnormal hemodynamic forces.

After Completing the above processes, Integrate anatomical data from CCT (plaque characteristics) with hemodynamic data from CFD (WSS). Identify high-risk plaques based on combined criteria, including anatomical vulnerability and hemodynamic stress. Then, the investigators Generate a detailed report summarizing the findings from CCT and CFD analysis. The investigators Stratify patients into different risk categories (low, moderate, high) based on the comprehensive assessment. Finally, the investigators will adjust the treatment plan based on the findings and analysis of the patient's response.