Evaluation of multiple-vendor AI autocontouring solutions.

IF 3.3 2区医学 Q2 ONCOLOGY Radiation Oncology Pub Date : 2024-05-31 DOI:10.1186/s13014-024-02451-4

Lee Goddard, Christian Velten, Justin Tang, Karin A Skalina, Robert Boyd, William Martin, Amar Basavatia, Madhur Garg, Wolfgang A Tomé

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Abstract

Background: Multiple artificial intelligence (AI)-based autocontouring solutions have become available, each promising high accuracy and time savings compared with manual contouring. Before implementing AI-driven autocontouring into clinical practice, three commercially available CT-based solutions were evaluated.

Materials and methods: The following solutions were evaluated in this work: MIM-ProtégéAI+ (MIM), Radformation-AutoContour (RAD), and Siemens-DirectORGANS (SIE). Sixteen organs were identified that could be contoured by all solutions. For each organ, ten patients that had manually generated contours approved by the treating physician (AP) were identified, totaling forty-seven different patients. CT scans in the supine position were acquired using a Siemens-SOMATOMgo 64-slice helical scanner and used to generate autocontours. Physician scoring of contour accuracy was performed by at least three physicians using a five-point Likert scale. Dice similarity coefficient (DSC), Hausdorff distance (HD) and mean distance to agreement (MDA) were calculated comparing AI contours to "ground truth" AP contours.

Results: The average physician score ranged from 1.00, indicating that all physicians reviewed the contour as clinically acceptable with no modifications necessary, to 3.70, indicating changes are required and that the time taken to modify the structures would likely take as long or longer than manually generating the contour. When averaged across all sixteen structures, the AP contours had a physician score of 2.02, MIM 2.07, RAD 1.96 and SIE 1.99. DSC ranged from 0.37 to 0.98, with 41/48 (85.4%) contours having an average DSC ≥ 0.7. Average HD ranged from 2.9 to 43.3 mm. Average MDA ranged from 0.6 to 26.1 mm.

Conclusions: The results of our comparison demonstrate that each vendor's AI contouring solution exhibited capabilities similar to those of manual contouring. There were a small number of cases where unusual anatomy led to poor scores with one or more of the solutions. The consistency and comparable performance of all three vendors' solutions suggest that radiation oncology centers can confidently choose any of the evaluated solutions based on individual preferences, resource availability, and compatibility with their existing clinical workflows. Although AI-based contouring may result in high-quality contours for the majority of patients, a minority of patients require manual contouring and more in-depth physician review.

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评估多家供应商的人工智能自动构图解决方案。

背景：目前已有多种基于人工智能（AI）的自动构图解决方案，每种解决方案都承诺比人工构图更准确、更省时。在将人工智能驱动的自动构图应用于临床实践之前，我们对三种基于 CT 的商用解决方案进行了评估：本研究对以下解决方案进行了评估：MIM-ProtégéAI+ (MIM)、Radformation-AutoContour (RAD) 和 Siemens-DirectORGANS (SIE)。所有解决方案均可对 16 个器官进行轮廓分析。针对每个器官，确定了十名经主治医生（AP）批准手动生成轮廓的患者，共计四十七名不同的患者。使用西门子-SOMATOMgo 64 片螺旋扫描仪采集仰卧位 CT 扫描图像，并用于生成自动轮廓。轮廓准确性由至少三名医生使用五点李克特量表进行评分。将人工智能轮廓与 "地面实况 "AP轮廓进行比较，计算出骰子相似系数（DSC）、豪斯多夫距离（HD）和平均一致距离（MDA）：医生的平均得分从 1.00 到 3.70 不等，1.00 表示所有医生都认为轮廓在临床上可以接受，无需修改；3.70 则表示需要修改，而且修改结构所需的时间可能与手动生成轮廓的时间相当或更长。如果对所有 16 个结构进行平均，AP 轮廓的医生评分为 2.02，MIM 为 2.07，RAD 为 1.96，SIE 为 1.99。DSC 从 0.37 到 0.98 不等，41/48（85.4%）个轮廓的平均 DSC ≥ 0.7。平均 HD 值从 2.9 毫米到 43.3 毫米不等。平均 MDA 为 0.6 至 26.1 毫米：我们的比较结果表明，每个供应商的人工智能轮廓分析解决方案都具有与人工轮廓分析类似的能力。在少数病例中，不寻常的解剖结构导致一个或多个解决方案得分较低。三家供应商解决方案的一致性和可比性表明，放射肿瘤中心可以根据个人偏好、资源可用性以及与现有临床工作流程的兼容性，放心地选择任何一种评估过的解决方案。尽管基于人工智能的轮廓分析可以为大多数患者绘制出高质量的轮廓，但仍有少数患者需要人工轮廓分析和更深入的医生审查。

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来源期刊

Radiation Oncology ONCOLOGY-RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING

CiteScore

6.50

自引率

2.80%

发文量

181

审稿时长

3-6 weeks

期刊介绍： Radiation Oncology encompasses all aspects of research that impacts on the treatment of cancer using radiation. It publishes findings in molecular and cellular radiation biology, radiation physics, radiation technology, and clinical oncology.