Individualized prescriptive inference in ischaemic stroke

The gold standard in the treatment of ischaemic stroke is set by evidence from randomized controlled trials. Yet the manifest complexity of the brain's functional, connective, and vascular architectures introduces heterogeneity in treatment susceptibility that violates the underlying statistical premisses, potentially leading to substantial errors at both individual and population levels. The counterfactual nature of therapeutic inference has made quantifying the impact of this defect difficult. Combining large-scale meta-analytic connective, functional, genetic expression, and receptor distribution data with high-resolution maps of 4 119 acute ischaemic lesions, here we conduct a comprehensive series of semi-synthetic virtual interventional trials, quantifying the fidelity of the traditional approach in inferring individual treatment effects against biologically plausible, empirically informed ground truths, across 103 628 800 distinct simulations. Combining deep generative models expressive enough to capture the observed lesion heterogeneity with flexible causal modelling, we find that the richness of the lesion representation is decisive in determining individual-level fidelity, even where freedom from treatment allocation bias cannot be guaranteed. Our results indicate that complex modelling with richly represented lesion data is critical to individualized prescriptive inference in ischaemic stroke.