Zhao Wei, Su Xiuyun, Guo Yao, Li Haojin, Basnet Shiva, Chen Jianyu, Yang Zide, Zhong Rihang, Liu Jiang, Chui Elvis Chun-Sing, Pei Guoxian, Li Heng
School of Medicine, Southern University of Science and Technology, Shenzhen, China.
Medical Intelligence and Innovation Academy, Southern University of Science and Technology Hospital, Shenzhen, China.
Quant Imaging Med Surg. 2023 Aug 1;13(8):5306-5320. doi: 10.21037/qims-23-9. Epub 2023 Jun 25.
Ultrasound is widely used for image-guided therapy (IGT) in many surgical fields, thanks to its various advantages, such as portability, lack of radiation and real-time imaging. This article presents the first attempt to utilize multiple deep learning algorithms in distal humeral cartilage segmentation for dynamic, volumetric ultrasound images employed in minimally invasive surgery.
The dataset, consisting 5,321 ultrasound images were collected from 12 healthy volunteers. These images were randomly split into training and validation sets in an 8:2 ratio. Based on deep learning algorithms, 9 semantic segmentation networks were developed and trained using our dataset at Southern University of Science and Technology Hospital in September 2022. The performance of the networks was evaluated based on their segmenting accuracy and processing efficiency. Furthermore, these networks were implemented in an IGT system to assess their feasibility in 3-dimentional imaging precision.
In 2D segmentation, Medical Transformer (MedT) showed the highest accuracy result with a Dice score of 89.4%, however, the efficiency in processing images was relatively lower at 2.6 frames per second (FPS). In 3D imaging, the average root mean square (RMS) between ultrasound (US)-generated models based on the networks and magnetic resonance imaging (MRI)-generated models was no more than 1.12 mm.
The findings of this study indicate the technological feasibility of a novel method for real-time visualization of distal humeral cartilage. The increased precision of ultrasound calibration and segmentation are both important approaches to improve the accuracy of 3D imaging.
由于超声具有便携性、无辐射和实时成像等多种优势,其在许多外科领域被广泛用于图像引导治疗(IGT)。本文首次尝试在用于微创手术的动态容积超声图像的肱骨远端软骨分割中运用多种深度学习算法。
从12名健康志愿者收集了由5321幅超声图像组成的数据集。这些图像以8:2的比例随机分为训练集和验证集。基于深度学习算法,2022年9月在南方科技大学医院使用我们的数据集开发并训练了9个语义分割网络。根据网络的分割精度和处理效率对其性能进行评估。此外,这些网络在一个IGT系统中实现,以评估它们在三维成像精度方面的可行性。
在二维分割中,医学变压器(MedT)显示出最高的准确率结果,骰子系数为89.4%,然而,其处理图像的效率相对较低,为每秒2.6帧(FPS)。在三维成像中,基于这些网络生成的超声(US)模型与磁共振成像(MRI)生成的模型之间的平均均方根(RMS)不超过1.12毫米。
本研究结果表明一种用于肱骨远端软骨实时可视化的新方法在技术上是可行的。提高超声校准和分割的精度都是提高三维成像准确性的重要方法。
