Fusion Modeling: Combining Clinical and Imaging Data to Advance Cardiac Care

Overview

Journal Circ Cardiovasc Imaging

Specialties Cardiology & Vascular Diseases
Radiology

Date 2023 Dec 11

PMID 38073535

Authors

Marly van Assen

Amara Tariq

Alexander C Razavi

Carl Yang

Imon Banerjee

Carlo N De Cecco

Affiliations

Soon will be listed here.

Abstract

In addition to the traditional clinical risk factors, an increasing amount of imaging biomarkers have shown value for cardiovascular risk prediction. Clinical and imaging data are captured from a variety of data sources during multiple patient encounters and are often analyzed independently. Initial studies showed that fusion of both clinical and imaging features results in superior prognostic performance compared with traditional scores. There are different approaches to fusion modeling, combining multiple data resources to optimize predictions, each with its own advantages and disadvantages. However, manual extraction of clinical and imaging data is time and labor intensive and often not feasible in clinical practice. An automated approach for clinical and imaging data extraction is highly desirable. Convolutional neural networks and natural language processing can be utilized for the extraction of electronic medical record data, imaging studies, and free-text data. This review outlines the current status of cardiovascular risk prediction and fusion modeling; and in addition gives an overview of different artificial intelligence approaches to automatically extract data from images and electronic medical records for this purpose.

Citing Articles

Use of AI in Cardiac CT and MRI: A Scientific Statement from the ESCR, EuSoMII, NASCI, SCCT, SCMR, SIIM, and RSNA.

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