4.6 Article

Integrating multiple MRI sequences for pelvic organs segmentation via the attention mechanism

期刊

MEDICAL PHYSICS
卷 48, 期 12, 页码 7930-7945

出版社

WILEY
DOI: 10.1002/mp.15285

关键词

computer vision; image processing; MRI; segmentation

资金

  1. Youth Innovation Project of Sun Yat-sen University Cancer Center [PT21020601]
  2. Student's Platform for Innovation and Entrepreneurship Training Program [S202113902030, 202113902116]
  3. Cancer Precision Radiotherapy Summit Plan of Clinical Scientific Research Public Welfare Project [2021-DF-009]
  4. Pearl River S&T Nova Program of Guangzhou [201710010162]
  5. Natural Science Foundation of Guangdong Province [2017A030310217]

向作者/读者索取更多资源

The study aims to create a network utilizing multi-sequence MRI for automatic contouring and compared its performance with manual human contouring. Results showed that the proposed network outperformed baseline models in all metrics. Additionally, it was found that three-sequence fusion (T1-T1DIXONC-T2) was superior to two-sequence fusion (T1-T2 and T1-T1DIXONC).
Purpose To create a network which fully utilizes multi-sequence MRI and compares favorably with manual human contouring. Methods We retrospectively collected 89 MRI studies of the pelvic cavity from patients with prostate cancer and cervical cancer. The dataset contained 89 samples from 87 patients with a total of 84 valid samples. MRI was performed with T1-weighted (T1), T2-weighted (T2), and Enhanced Dixon T1-weighted (T1DIXONC) sequences. There were two cohorts. The training cohort contained 55 samples and the testing cohort contained 29 samples. The MRI images in the training cohort contained contouring data from radiotherapist alpha. The MRI images in the testing cohort contained contouring data from radiotherapist alpha and contouring data from another radiotherapist: radiotherapist beta. The training cohort was used to optimize the convolution neural networks, which included the attention mechanism through the proposed activation module and the blended module into multiple MRI sequences, to perform autodelineation. The testing cohort was used to assess the networks' autodelineation performance. The contoured organs at risk (OAR) were the anal canal, bladder, rectum, femoral head (L), and femoral head (R). Results We compared our proposed network with UNet and FuseUNet using our dataset. When T1 was the main sequence, we input three sequences to segment five organs and evaluated the results using four metrics: the DSC (Dice similarity coefficient), the JSC (Jaccard similarity coefficient), the ASD (average mean distance), and the 95% HD (robust Hausdorff distance). The proposed network achieved improved results compared with the baselines among all metrics. The DSC were 0.834 +/- 0.029, 0.818 +/- 0.037, and 0.808 +/- 0.050 for our proposed network, FuseUNet, and UNet, respectively. The 95% HD were 7.256 +/- 2.748 mm, 8.404 +/- 3.297 mm, and 8.951 +/- 4.798 mm for our proposed network, FuseUNet, and UNet, respectively. Our proposed network also had superior performance on the JSC and ASD coefficients. Conclusion Our proposed activation module and blended module significantly improved the performance of FuseUNet for multi-sequence MRI segmentation. Our proposed network integrated multiple MRI sequences efficiently and autosegmented OAR rapidly and accurately. We also discovered that three-sequence fusion (T1-T1DIXONC-T2) was superior to two-sequence fusion (T1-T2 and T1-T1DIXONC, respectively). We infer that the more MRI sequences fused, the better the automatic segmentation results.

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