Table 2.
Different nodule detection and characterization system using CNN-based deep learning approach in lung CT images
| Sl. No. | First author with publication year | Method | Purpose | Performance |
|---|---|---|---|---|
| 1. | Paul et al. (2018) [37] | Pre-trained vgg-s network with merge CNN | Nodule characterization | Accuracy = 76.79%, ROC = 0.87 |
| 2. | Liu et al. (2018) [157] | Multi-view multi-scale CNN | Nodule categorization | Overall accuracy = 92.3% (LIDC dataset) and 90.3% (ELCAP dataset) |
| 3. | Yuan et al. (2017) [155] | Pre-trained vgg network followed by CNN-based features fused with handcraft-based features (multi-view multi-scale CNN) | Nodule categorization | Overall accuracy = 93.1% (LIDC dataset) and 93.9% (ELCAP dataset) |
| 4. | Xie et al. (2017) [156] | Applied CNN at decision level | Nodule characterization | AUC of 96.65%, 94.45%, and 81.24% |
| 5. | Silva et al. (2017) [154] | Genetic algorithm-based CNN | Nodule characterization | Sensitivity = 94.66%, specificity = 95.14%, accuracy of 94.78%, and area under the ROC curve of 0.949. |
| 6. | Wang et al. (2017) [153] | Data-driven-based machine learning model using central focused convolutional neural network (CF-CNN) | Nodule segmentation | Dice score = 82.15% (LIDC dataset) and 80.02% (GDGH dataset) |
| 7. | Dou et al. (2016) [152] | Three 3-D CNN applied with fusion technique | Nodule detection | Sensitivity = 94.4% and sensitivity = 92.2% at 8FPs/scan |
| 8. | Shen et al. (2016) [149] | Multi-crop convolutional neural network (MC-CNN) | Nodule characterization | Accuracy = 87.14%, AUC = 0.93, sensitivity = 77%, specificity = 93% |
| 9. | Setio et al. (2016) [150] | Multiple streams of 2-D ConvNets (multi-view architecture) | Nodule detection | Sensitivity = 85.4% with 1 FP/scan and 90.1% with 4 FPs/scan |
| 10. | Ciompi et al. (2015) [151] | 2-D convolution-based architecture named as “OverFeat” | Peri-fissural nodules (PFNs) detection | Area under curve (AUC) = 0.868 |