Automation of a Rule-based Workflow to Estimate Age from Brain MR Imaging of Infants and Children Up to 2 Years Old Using Stacked Deep Learning

Akihiko Wada; Yuya Saito; Shohei Fujita; Ryusuke Irie; Toshiaki Akashi; Katsuhiro Sano; Shinpei Kato; Yutaka Ikenouchi; Akifumi Hagiwara; Kanako Sato; Nobuo Tomizawa; Yayoi Hayakawa; Junko Kikuta; Koji Kamagata; Michimasa Suzuki; Masaaki Hori; Atsushi Nakanishi; Shigeki Aoki

doi:10.2463/mrms.mp.2021-0068

Automation of a Rule-based Workflow to Estimate Age from Brain MR Imaging of Infants and Children Up to 2 Years Old Using Stacked Deep Learning

Magn Reson Med Sci. 2023 Jan 1;22(1):57-66. doi: 10.2463/mrms.mp.2021-0068. Epub 2021 Dec 10.

Authors

Akihiko Wada¹, Yuya Saito¹, Shohei Fujita¹, Ryusuke Irie¹, Toshiaki Akashi¹, Katsuhiro Sano¹, Shinpei Kato¹, Yutaka Ikenouchi¹, Akifumi Hagiwara¹, Kanako Sato¹, Nobuo Tomizawa¹, Yayoi Hayakawa¹, Junko Kikuta¹, Koji Kamagata¹, Michimasa Suzuki¹, Masaaki Hori¹, Atsushi Nakanishi¹, Shigeki Aoki¹

Affiliation

¹ Department of Radiology, Juntendo University School of Medicine.

Abstract

Purpose: Myelination-related MR signal changes in white matter are helpful for assessing normal development in infants and children. A rule-based myelination evaluation workflow regarding signal changes on T1-weighted images (T1WIs) and T2-weighted images (T2WIs) has been widely used in radiology. This study aimed to simulate a rule-based workflow using a stacked deep learning model and evaluate age estimation accuracy.

Methods: The age estimation system involved two stacked neural networks: a target network-to extract five myelination-related images from the whole brain, and an age estimation network from extracted T1- and T2WIs separately. A dataset was constructed from 119 children aged below 2 years with two MRI systems. A four-fold cross-validation method was adopted. The correlation coefficient (CC), mean absolute error (MAE), and root mean squared error (RMSE) of the corrected chronological age of full-term birth, as well as the mean difference and the upper and lower limits of 95% agreement, were measured. Generalization performance was assessed using datasets acquired from different MR images. Age estimation was performed in Sturge-Weber syndrome (SWS) cases.

Results: There was a strong correlation between estimated age and corrected chronological age (MAE: 0.98 months; RMSE: 1.27 months; and CC: 0.99). The mean difference and standard deviation (SD) were -0.15 and 1.26, respectively, and the upper and lower limits of 95% agreement were 2.33 and -2.63 months. Regarding generalization performance, the performance values on the external dataset were MAE of 1.85 months, RMSE of 2.59 months, and CC of 0.93. Among 13 SWS cases, 7 exceeded the limits of 95% agreement, and a proportional bias of age estimation based on myelination acceleration was exhibited below 12 months of age (P = 0.03).

Conclusion: Stacked deep learning models automated the rule-based workflow in radiology and achieved highly accurate age estimation in infants and children up to 2 years of age.

Keywords: deep learning; infant and child development; magnetic resonance imaging; myelination.

MeSH terms

Automation
Brain / diagnostic imaging
Child
Deep Learning*
Humans
Infant
Magnetic Resonance Imaging / methods
Workflow

Grants and funding

This work was supported in part by JSPS KAKENHI Grant Number 18K07730.