# Neural network assessment of aortic, iliac, renal, and mesenteric artery calcification in CTA: Normalized scoring framework and comparison to threshold-based method

**Authors:** Johannes Halkoaho, Oskari Niiranen, Tuomas Kaseva, Arttu Ruohola, Eero Salli, Sauli Savolainen, Harri Hakovirta, Marko Kangasniemi

PMC · DOI: 10.1177/20584601261431608 · 2026-03-05

## TL;DR

This paper introduces a deep learning method to automatically quantify calcification in abdominal arteries from CT scans, offering a reliable alternative to manual or threshold-based methods.

## Contribution

A normalized deep learning framework for calcification quantification in abdominal arteries, benchmarked against threshold-based methods.

## Key findings

- The neural network achieved performance comparable to threshold-based methods with slight improvements in segmentation metrics.
- Predicted calcification burden scores correlated highly with ground truth scores.
- The method enables fast and reproducible quantification of calcification in major abdominal vessels.

## Abstract

Calcification of abdominal arteries is an important risk marker in vascular disease. Automated, objective quantification methods could improve reproducibility and reduce observer dependency in clinical practice.

To develop and evaluate a deep learning method for quantifying abdominal arterial calcification from contrast-enhanced CT angiography (CTA).

We retrospectively collected 223 CTA volumes, divided into 147 training and 76 test cases. Ground truth calcification segmentations were manually annotated, while vessel segmentations were generated by a previously trained neural network and manually refined. Two nnU-Net models were trained, one for artery segmentation and one for calcification segmentation. Renal, mesenteric, and common iliac arteries were shortened algorithmically. Performance of the models was evaluated using Dice score, volumetric similarity, sensitivity, precision, and Jaccard index. Calcification burden was defined as the ratio of calcified volume to artery volume. The amount and the average size of calcification clusters were investigated. The performance of the method was benchmarked against an idealized threshold-based approach and a more clinically realistic approach.

The neural network achieved performance comparable to the optimized threshold-based method, with slight improvements across several segmentation metrics. Dice scores and volumetric similarity demonstrated reliable vessel and calcification detection. The predicted calcification burden score showed high correlation with the ground truth calcification burden score.

The proposed deep learning tool enables fast, reproducible, and observer-independent quantification of calcification in major abdominal vessels, offering a practical alternative to manual or threshold-based scoring methods.

## Full-text entities

- **Diseases:** PAD (MESH:D058729), ischemia (MESH:D007511), CCA (MESH:C566443), atherosclerosis (MESH:D050197), abdominal aortic aneurysms (MESH:D017544), arterial calcification (MESH:D061205), ORCID iDs (MESH:C535742), abdominal arterial calcification (MESH:D015746), vascular disease (MESH:D014652), Calcification (MESH:D002114), renal insufficiency (MESH:D051437), HUS (MESH:D006463), , renal, and mesenteric artery calcification (MESH:D012078)
- **Chemicals:** CT660 (-)
- **Species:** Homo sapiens (human, species) [taxon 9606]
- **Mutations:** M 50 F, M 28 F

## Figures

10 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12966520/full.md

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Source: https://tomesphere.com/paper/PMC12966520