Litcius/Paper detail

Deuterium imaging of the Warburg effect at sub‐millimolar concentrations by joint processing of the kinetic and spectral dimensions

Elton Tadeu Montrazi, Qingjia Bao, Ricardo P. Martinho, Dana C. Peters, Talia Harris, Keren Sasson, Lilach Agemy, Avigdor Scherz, Lucio Frydman

2023NMR in Biomedicine18 citationsDOIOpen Access PDF

Abstract

]-lactate as a result of the Warburg effect, providing a distinct resonance whose mapping using time-resolved spectroscopic imaging can diagnose cancer. The MR detection of low-concentration metabolites such as lactate, however, is challenging. It has been recently shown that multi-echo balanced steady-state free precession (ME-bSSFP) increases the signal-to-noise ratio (SNR) of these experiments approximately threefold over regular chemical shift imaging; the present study examines how DMI's sensitivity can be increased further by advanced processing methods. Some of these, such as compressed sensing multiplicative denoising and block-matching/3D filtering, can be applied to any spectroscopic/imaging methods. Sensitivity-enhancing approaches were also specifically tailored to ME-bSSFP DMI, by relying on priors related to the resonances' positions and to features of the metabolic kinetics. Two new methods are thus proposed that use these constraints for enhancing the sensitivity of both the spectral images and the metabolic kinetics. The ability of these methods to improve DMI is evidenced in pancreatic cancer studies carried at 15.2 T, where suitable implementations of the proposals imparted eightfold or more SNR improvement over the original ME-bSSFP data, at no informational cost. Comparisons with other propositions in the literature are briefly discussed.

Topics & Concepts

ChemistryWarburg effectKineticsDeuteriumNuclear magnetic resonanceBiological systemSensitivity (control systems)Computer sciencePhysicsMetabolismBiochemistryQuantum mechanicsBiologyEngineeringGlycolysisElectronic engineeringAdvanced MRI Techniques and ApplicationsAtomic and Subatomic Physics ResearchAdvanced NMR Techniques and Applications