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Main Authors: Gkotsis, Dimosthenis E., Gotsis, Efstathios D., Pappas, Eleftherios P., Kapsalaki, Eftichia Z., Seimenis, Ioannis
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2402.09431
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author Gkotsis, Dimosthenis E.
Gotsis, Efstathios D.
Pappas, Eleftherios P.
Kapsalaki, Eftichia Z.
Seimenis, Ioannis
author_facet Gkotsis, Dimosthenis E.
Gotsis, Efstathios D.
Pappas, Eleftherios P.
Kapsalaki, Eftichia Z.
Seimenis, Ioannis
contents Signal-to-noise ratio optimization, regarding repetition time selection, was explored mathematically and experimentally for single-voxel proton magnetic resonance spectroscopy. Theoretical findings were benchmarked against phantom measurements at 1.5 Tesla and localized in vivo proton brain spectra acquired at both 1.5 Tesla/3.0 Tesla. A detailed mathematical description of signal-to-noise ratio per unit time was derived, yielding an optimal repetition time of 1.256 times the metabolite longitudinal relaxation time. While long-repetition-time acquisitions minimize longitudinal relaxation time contributions, a repetition time of ~1.5s results in maximum signal-to-noise ratio per unit time, which can in turn be invested into smaller voxel sizes. The latter is of utmost importance in brain oncology, allowing accurate spectroscopic characterization of small lesions.
format Preprint
id arxiv_https___arxiv_org_abs_2402_09431
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Signal-to-noise per unit time optimization for in vivo single-voxel proton magnetic resonance spectroscopy of the brain: Theoretical formulation and experimental verification at two field strengths
Gkotsis, Dimosthenis E.
Gotsis, Efstathios D.
Pappas, Eleftherios P.
Kapsalaki, Eftichia Z.
Seimenis, Ioannis
Medical Physics
Signal-to-noise ratio optimization, regarding repetition time selection, was explored mathematically and experimentally for single-voxel proton magnetic resonance spectroscopy. Theoretical findings were benchmarked against phantom measurements at 1.5 Tesla and localized in vivo proton brain spectra acquired at both 1.5 Tesla/3.0 Tesla. A detailed mathematical description of signal-to-noise ratio per unit time was derived, yielding an optimal repetition time of 1.256 times the metabolite longitudinal relaxation time. While long-repetition-time acquisitions minimize longitudinal relaxation time contributions, a repetition time of ~1.5s results in maximum signal-to-noise ratio per unit time, which can in turn be invested into smaller voxel sizes. The latter is of utmost importance in brain oncology, allowing accurate spectroscopic characterization of small lesions.
title Signal-to-noise per unit time optimization for in vivo single-voxel proton magnetic resonance spectroscopy of the brain: Theoretical formulation and experimental verification at two field strengths
topic Medical Physics
url https://arxiv.org/abs/2402.09431