AI Article Synopsis
- The study developed a convolutional neural network (CNN) to analyze lumbar spinal muscles in MRI scans of patients with lower back pain, focusing on segmenting muscle and classifying fatty degeneration.
- The CNN was trained using 3,650 axial T2-weighted MRI images from 100 patients and showed high accuracy in muscle segmentation but struggled with fatty tissue, achieving a dice similarity coefficient (DSC) of 0.51 for that aspect.
- Despite promising results with overall muscle segmentation and a 75% accuracy in classification, the study indicates the need for larger datasets and additional model training to improve fatty tissue segmentation for clinical use.
Article Abstract
Purpose: This single-center study aimed to develop a convolutional neural network to segment multiple consecutive axial magnetic resonance imaging (MRI) slices of the lumbar spinal muscles of patients with lower back pain and automatically classify fatty muscle degeneration.
Methods: We developed a fully connected deep convolutional neural network (CNN) with a pre-trained U-Net model trained on a dataset of 3,650 axial T2-weighted MRI images from 100 patients with lower back pain. We included all qualities of MRI; the exclusion criteria were fractures, tumors, infection, or spine implants. The training was performed using k-fold cross-validation (k = 10), and performance was evaluated using the dice similarity coefficient (DSC) and cross-sectional area error (CSA error). For clinical correlation, we used a simplified Goutallier classification (SGC) system with three classes.
Results: The mean DSC was high for overall muscle (0.91) and muscle tissue segmentation (0.83) but showed deficiencies in fatty tissue segmentation (0.51). The CSA error was small for the overall muscle area of 8.42%, and fatty tissue segmentation showed a high mean CSA error of 40.74%. The SGC classification was correctly predicted in 75% of the patients.
Conclusion: Our fully connected CNN segmented overall muscle and muscle tissue with high precision and recall, as well as good DSC values. The mean predicted SGC values of all available patient axial slices showed promising results. With an overall Error of 25%, further development is needed for clinical implementation. Larger datasets and training of other model architectures are required to segment fatty tissue more accurately.
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| http://dx.doi.org/10.1007/s00586-021-07073-y | DOI Listing |
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