Multi-objective Parameter Optimization of DWI-based Global Fiber Tracking with Neuronal Tracer Signal as a Reference

Diffusion magnetic resonance imaging (MRI) allows non-invasive exploration of brain structural information, crucial for understanding the human-brain; however, present-day diffusion-based tractography approaches are still lacking in accuracy. Improvement efforts included comparison with anatomical connectivity data, the usage of higher quality data, more sophisticated algorithms and parameters assessment. Despite that, well-known problems such as low sensitivity, dominance of false positives, the accurate reconstruction of long-range connections could not be avoided or minimized. Current methods include several parameters, typically tuned in a heuristic way, with settings to increase the sensitivity, without attenuating the overall problem. We propose a new way to optimize fiber-tracking results by multi-objectives tailored to minimize the current issues. Our approach uses comparison with marmoset fluorescent tracer injection data from the Japan Brain/MINDS to validate and optimize ex-vivo diffusion weighted MRI (DWI)-based global fiber tracking results of the same subject. The approach includes multiple comparisons at a higher-than-DWI resolution standard brain space to evaluate objectives of coverage and passage constraint. The coverage objectives maximize sensitivity while constraining the growth of false positives, promoting the generation of long connections to the projection areas. The passage constraint minimizes the number of fibers crossing hemispheres outside the commissures. We implemented a non-dominated sorting genetic algorithm (NSGA-II) strategy to explore the parameters space. Evolutionary optimization runs for 10 brain samples in parallel while sharing champion settings over samples, encouraging convergence of parameters in a similar locus. We evaluate the generalization capability of the optimized parameters on unseen marmoset test data leading to promising results.