PHIVE: A Physics-Informed Variational Encoder Enables Rapid Spectral Fitting of Brain Metabolite Mapping at 7T

Magnetic Resonance Spectroscopic Imaging (MRSI) enables non-invasive mapping of brain metabolite concentrations but remains computationally intensive and challenging due to a low signal-to-noise ratio (SNR) and overlapping spectral features. Traditional spectral fitting methods, such as LCModel, are time-consuming and often lack comprehensive uncertainty quantification. In this study, we propose Physics-Informed Variational Encoder (PHIVE), a novel deep learning framework that integrates physics-based priors into a variational autoencoder architecture for rapid and accurate metabo-lite quantification. PHIVE enables simultaneous estimation of metabolite concentrations and uncertainty metrics, including Cramér-Rao Lower Bound (CRLB), aleatoric, and epistemic uncertainties.

PHIVE was evaluated on whole-brain MRSI data from 7T acquisitions of healthy controls. The method achieved comparable accuracy to LCModel for key metabolites, such as Total N-acetylaspartate (tNAA), Glutamate-Glutamine complex (Glx), and Myo-inositol (mIns) while demonstrating a six-order magnitude reduction in computational time (6 ms per dataset). Uncertainty quantification highlighted PHIVE’s robustness in regions with low SNR. Additionally, a conditional baseline modeling approach was introduced, enabling dynamic flexibility in spectral baseline estimation during inference time.

These results suggest that PHIVE offers a fast, reliable, and interpretable solution for high-resolution metabolite quantification, paving the way for real-time MRSI applications in clinical and research settings. Future work will focus on expanding its validation across diverse datasets and investigating its utility in longitudinal and multicenter studies.