Abstract
Detecting multiple sclerosis lesions in spinal cord MRI is a critical but complex task for radiologists and neurologists. While deep learning models have shown promise for this task, training these models requires large manually annotated datasets, which are time consuming and expensive to create. To reduce the annotation burden, this study proposes LesionSCynth, a parametric framework for synthesising hyperintense lesions in spinal cord MRI. Based on analysis of the intensity distribution of real lesions in sagittal T2-weighted acquisitions, LesionSCynth generates realistic synthetic lesions that can augment small annotated datasets. Segmentation models trained on a combination of these synthetic lesions and 17 real acquisitions achieved notably better performance than those trained on the real lesions alone (0.52 vs. 0.46 FROC, respectively). Notably, models trained with LesionSCynth lesions achieved similar detection performance to a model trained on eight times more real lesions (0.55 FROC for both). Moreover, LesionSCynth outperformed two leading lesion synthesis methods, LesionMix (0.43) and CarveMix (0.41), in low-data regimes. These findings position LesionSCynth as a practical and effective solution for reducing the annotation burden while improving multiple sclerosis (MS) lesion detection and segmentation in spinal cord MRI.