基于卷积神经网络的宫颈癌自动轮廓勾画系统

Automatic contouring system for cervical cancer using convolutional neural networks.

作者信息

Rhee Dong Joo, Jhingran Anuja, Rigaud Bastien, Netherton Tucker, Cardenas Carlos E, Zhang Lifei, Vedam Sastry, Kry Stephen, Brock Kristy K, Shaw William, O'Reilly Frederika, Parkes Jeannette, Burger Hester, Fakie Nazia, Trauernicht Chris, Simonds Hannah, Court Laurence E

机构信息

MD Anderson UTHealth Graduate School, Houston, TX, USA.

Department of Radiation Physics, Division of Radiation Oncology, The University of Texas MD Anderson Cancer Center, Houston, TX, USA.

出版信息

Med Phys. 2020 Nov;47(11):5648-5658. doi: 10.1002/mp.14467. Epub 2020 Oct 9.

DOI:10.1002/mp.14467

PMID:32964477

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7756586/

Abstract

PURPOSE

To develop a tool for the automatic contouring of clinical treatment volumes (CTVs) and normal tissues for radiotherapy treatment planning in cervical cancer patients.

METHODS

An auto-contouring tool based on convolutional neural networks (CNN) was developed to delineate three cervical CTVs and 11 normal structures (seven OARs, four bony structures) in cervical cancer treatment for use with the Radiation Planning Assistant, a web-based automatic plan generation system. A total of 2254 retrospective clinical computed tomography (CT) scans from a single cancer center and 210 CT scans from a segmentation challenge were used to train and validate the CNN-based auto-contouring tool. The accuracy of the tool was evaluated by calculating the Sørensen-dice similarity coefficient (DSC) and mean surface and Hausdorff distances between the automatically generated contours and physician-drawn contours on 140 internal CT scans. A radiation oncologist scored the automatically generated contours on 30 external CT scans from three South African hospitals.

RESULTS

The average DSC, mean surface distance, and Hausdorff distance of our CNN-based tool were 0.86/0.19 cm/2.02 cm for the primary CTV, 0.81/0.21 cm/2.09 cm for the nodal CTV, 0.76/0.27 cm/2.00 cm for the PAN CTV, 0.89/0.11 cm/1.07 cm for the bladder, 0.81/0.18 cm/1.66 cm for the rectum, 0.90/0.06 cm/0.65 cm for the spinal cord, 0.94/0.06 cm/0.60 cm for the left femur, 0.93/0.07 cm/0.66 cm for the right femur, 0.94/0.08 cm/0.76 cm for the left kidney, 0.95/0.07 cm/0.84 cm for the right kidney, 0.93/0.05 cm/1.06 cm for the pelvic bone, 0.91/0.07 cm/1.25 cm for the sacrum, 0.91/0.07 cm/0.53 cm for the L4 vertebral body, and 0.90/0.08 cm/0.68 cm for the L5 vertebral bodies. On average, 80% of the CTVs, 97% of the organ at risk, and 98% of the bony structure contours in the external test dataset were clinically acceptable based on physician review.

CONCLUSIONS

Our CNN-based auto-contouring tool performed well on both internal and external datasets and had a high rate of clinical acceptability.

摘要

目的

开发一种用于宫颈癌患者放射治疗计划中临床治疗靶区（CTV）和正常组织自动轮廓勾画的工具。

方法

开发了一种基于卷积神经网络（CNN）的自动轮廓勾画工具，用于在宫颈癌治疗中勾勒出三个宫颈CTV和11个正常结构（七个危及器官，四个骨质结构），以便与基于网络的自动计划生成系统“放射治疗计划助手”配合使用。来自单个癌症中心的2254例回顾性临床计算机断层扫描（CT）以及来自一次分割挑战赛的210例CT扫描用于训练和验证基于CNN的自动轮廓勾画工具。通过计算140例内部CT扫描上自动生成的轮廓与医生绘制的轮廓之间的 Sørensen - 骰子相似系数（DSC）、平均表面距离和豪斯多夫距离来评估该工具的准确性。一位放射肿瘤学家对来自三家南非医院的30例外部CT扫描上自动生成的轮廓进行评分。

结果

我们基于CNN的工具对于原发CTV的平均DSC、平均表面距离和豪斯多夫距离分别为0.86 / 0.19厘米 / 2.02厘米，对于淋巴结CTV为0.81 / 0.21厘米 / 2.09厘米，对于全盆腔CTV为0.76 / 0.27厘米 / 2.00厘米，对于膀胱为0.89 / 0.11厘米 / 1.07厘米，对于直肠为0.81 / 0.18厘米 / 1.66厘米，对于脊髓为0.90 / 0.06厘米 / 0.65厘米，对于左股骨为0.94 / 0.06厘米 / （待续）（接上页）0.60厘米，对于右股骨为0.93 / 0.07厘米 / 0.66厘米，对于左肾为0.94 / 0.08厘米 / 0.76厘米，对于右肾为0.95 / 0.07厘米 / 0.84厘米，对于骨盆为0.93 / 0.05厘米 / 1.06厘米，对于骶骨为0.91 / 0.07厘米 / 1.25厘米，对于L4椎体为0.91 / 0.07厘米 / 0.53厘米，对于L5椎体为0.90 / 0.08厘米 / 0.68厘米。根据医生的评估，外部测试数据集中平均80%的CTV、97%的危及器官和98%的骨质结构轮廓在临床上是可接受的。

结论

我们基于CNN的自动轮廓勾画工具在内部和外部数据集上均表现良好，并且具有较高的临床可接受率。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/1828/7756586/ec37c05a4737/MP-47-5648-g001.jpg

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基于卷积神经网络的宫颈癌自动轮廓勾画系统

Automatic contouring system for cervical cancer using convolutional neural networks.

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