Introduction: The failure to translate promising preclinical stroke therapies into clinical success is largely attributed to a lack of rigorous, reproducible outcome measures. While magnetic resonance imaging (MRI) offers a translational alternative to traditional histology, its use in large, multi-site trials is challenged by data heterogeneity and the need for scalable analysis. To address this, we developed and validated a fully automated, open-source image analysis pipeline for the Stroke Preclinical Assessment Network (SPAN), a six-center preclinical trial. Methods: T2 and ADC MRI scans were acquired from 2443 mice and rats (including aged and obese cohorts) at 6 centers 2 and 30 days after middle cerebral artery occlusion (MCAO). Our open-source pipeline performs a complete workflow ( Figure 1 ): 1) preprocessing (image reconstruction, denoising, parameter estimation and quality assessment measures); 2) intensity harmonization to reduce inter-site variability; 3) brain extraction using either traditional rule-based segmentation (rats) or U-net deep learning model (mice); 4) rule-based lesion segmentation via thresholding of harmonized T2 and ADC maps ( Figure 2A-G ); and 5) quantification of midline shift as a proxy for swelling and atrophy ( Figure 3A ). Validation was performed against expert manual tracing on both MRI and 2,3,5-Triphenyltetrazolium chloride (TTC)-stained tissue. Results: The pipeline successfully processed thousands of scans from a heterogeneous collection of scanners. The U-net brain extraction model was highly accurate (Dice score=0.964) and successfully segmented cases where traditional methods failed. Automated lesion volumes correlated strongly with manual expert MRI tracing (R=0.957) and with TTC staining in optimal preparations (R=0.86; Figure 2H ). Harmonization significantly reduced site-specific differences in MRI values. Our geometric midline estimation consistently demonstrated a midline shift towards the contralesional side indicative of swelling on Day 2 and a midline shift towards the ipsilesional side indicative of atrophy on Day 30 ( Figure 3B ). Conclusion: We have developed a validated, end-to-end automated pipeline for quantifying stroke injury in large, multi-site preclinical trials. This work delivers a scalable, objective, and reproducible framework as a shareable, open-source tool that enhances the rigor of preclinical research to help bridge the translational gap in stroke.
Lynch et al. (Thu,) studied this question.