A 3D surface coil with deep learning-based noise reduction for parotid gland imaging at 7T

iRadiology Pub Date : 2024-06-10 DOI:10.1002/ird3.79
Sayim Gokyar, Chenyang Zhao, Shajan Gunamony, Liyang Tang, Jonathan West, Niels Kokot, Danny J. J. Wang
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Abstract

Background

Background: Parotid gland neoplasms occur near the facial nerve. Hence, it is crucial to determine whether the malignant neoplasms involve the facial nerve and whether sacrifice of the nerve in surgery is necessary. Furthermore, while 20% of all neoplasms are malignant, the most common benign neoplasm, pleomorphic adenoma, has a risk for malignant transformation, making early detection and treatment essential. 7T magnetic resonance imaging offers increased signal-to-noise ratio (SNR) and sensitivity.

Aim

In this work, we address imaging the parotid gland since it remains challenging at 7T because of its spatial location.

Materials and Methods

Here, we present a novel three-dimensional surface coil (3D Coil) architecture that offers increased depth penetration and SNR compared to the single channel surface coil. We further developed a deep learning (DL)-based noise reduction method that receives inputs from three elements of the 3D Coil.

Results

The 3D coil with DL-based denoising method offers twice the SNR compared to the single channel surface coil for parotid gland imaging at 7T.

Discussion and Conclusion

The proposed 3D Coil and DL-based noise reduction method offers a promising way of achieving higher SNR for parotid salivary gland imaging at 7T, paving the road for clinical applications.

Abstract Image

基于深度学习降噪技术的三维表面线圈,用于 7T 下的腮腺成像
背景介绍腮腺肿瘤发生在面神经附近。因此,确定恶性肿瘤是否累及面神经以及手术中是否需要牺牲面神经至关重要。此外,虽然所有肿瘤中有 20% 是恶性的,但最常见的良性肿瘤--多形性腺瘤也有恶变的风险,因此早期发现和治疗至关重要。7T磁共振成像技术提高了信噪比(SNR)和灵敏度。在这项工作中,我们针对腮腺成像进行了研究,因为腮腺的空间位置决定了它在7T下的成像仍具有挑战性。我们进一步开发了一种基于深度学习(DL)的降噪方法,该方法接收来自三维线圈三个元件的输入。与单通道表面线圈相比,三维线圈和基于 DL 的去噪方法在 7T 下进行腮腺成像时的信噪比提高了一倍。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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