Your search keyword '"Alves, Brayan"' showing total 6 results

1. Noise-reduction techniques for 1H-FID-MRSI at 14.1T: Monte-Carlo validation & in vivo application

Author

Alves, Brayan, Simicic, Dunja, Mosso, Jessie, Lê, Thanh Phong, Briand, Guillaume, Bogner, Wolfgang, Lanz, Bernard, Strasser, Bernhard, Klauser, Antoine, and Cudalbu, Cristina

Subjects

Physics - Medical Physics

Abstract

Proton magnetic resonance spectroscopic imaging (1H-MRSI) is a powerful tool that enables the multidimensional non-invasive mapping of the neurochemical profile at high-resolution over the entire brain. The constant demand for higher spatial resolution in 1H-MRSI led to increased interest in post-processing-based denoising methods aimed at reducing noise variance. The aim of the present study was to implement two noise-reduction techniques, the Marchenko-Pastur principal component analysis (MP-PCA) based denoising and the low-rank total generalized variation (LR-TGV) reconstruction, and to test their potential and impact on preclinical 14.1T fast in vivo 1H-FID-MRSI datasets. Since there is no known ground truth for in vivo metabolite maps, additional evaluations of the performance of both noise-reduction strategies were conducted using Monte-Carlo simulations. Results showed that both denoising techniques increased the apparent signal-to-noise ratio SNR while preserving noise properties in each spectrum for both in vivo and Monte-Carlo datasets. Relative metabolite concentrations were not significantly altered by either methods and brain regional differences were preserved in both synthetic and in vivo datasets. Increased precision of metabolite estimates was observed for the two methods, with inconsistencies noted on lower concentrated metabolites. Our study provided a framework on how to evaluate the performance of MP-PCA and LR-TGV methods for preclinical 1H-FID MRSI data at 14.1T. While gains in apparent SNR and precision were observed, concentration estimations ought to be treated with care especially for low-concentrated metabolites., Comment: Brayan Alves and Dunja Simicic are joint first authors. Currently in revision for NMR in Biomedicine

Published

2023

2. Fast high-resolution metabolite mapping in the rat brain using 1H-FID-MRSI at 14.1T

Author

Simicic, Dunja, Alves, Brayan, Mosso, Jessie, Briand, Guillaume, Lê, Thanh Phong, van Heeswijk, Ruud B., Starčuková, Jana, Lanz, Bernard, Klauser, Antoine, Strasser, Bernhard, Bogner, Wolfgang, and Cudalbu, Cristina

Subjects

Physics - Medical Physics

Abstract

Magnetic resonance spectroscopic imaging (MRSI) enables the simultaneous non-invasive acquisition of MR spectra from multiple spatial locations inside the brain. While 1H-MRSI is increasingly used in the human brain, it is not yet widely applied in the preclinical settings, mostly because of difficulties specifically related to very small nominal voxel size in the rodent brain and low concentration of brain metabolites, resulting in low signal-to-noise ratio SNR. In this context, we implemented a free induction decay 1H-MRSI sequence (1H-FID-MRSI) in the rat brain at 14.1T. We combined the advantages of 1H-FID-MRSI with the ultra-high magnetic field to achieve higher SNR, coverage and spatial resolution in the rodent brain, and developed a custom dedicated processing pipeline with a graphical user interface: MRS4Brain toolbox. LCModel fit, using the simulated metabolite basis-set and in-vivo measured MM, provided reliable fits for the data at acquisition delays of 1.3 and 0.94 ms. The resulting Cram\'er-Rao lower bounds were sufficiently low (<30%) for eight metabolites of interest, leading to highly reproducible metabolic maps. Similar spectral quality and metabolic maps were obtained between 1 and 2 averages, with slightly better contrast and brain coverage due to increased SNR in the latter case. Furthermore, the obtained metabolic maps were accurate enough to confirm the previously known brain regional distribution of some metabolites. The acquisitions proved high reproducibility over time. We demonstrated that the increased SNR and spectral resolution at 14.1T can be translated into high spatial resolution in 1H-FID-MRSI of the rat brain in 13 minutes, using the sequence and processing pipeline described herein. High-resolution 1H-FID-MRSI at 14.1T provided reproducible and high-quality metabolic mapping of brain metabolites with significantly reduced technical limitations., Comment: Dunja Simicic and Brayan Alves are joint first authors

Published

2023

3. Noise‐reduction techniques for 1H‐FID‐MRSI at 14.1 T: Monte Carlo validation and in vivo application.

Author

Alves, Brayan, Simicic, Dunja, Mosso, Jessie, Lê, Thanh Phong, Briand, Guillaume, Bogner, Wolfgang, Lanz, Bernard, Strasser, Bernhard, Klauser, Antoine, and Cudalbu, Cristina

Subjects

MAGNETIC resonance imaging, PROTON magnetic resonance, MONTE Carlo method, PRINCIPAL components analysis, REGIONAL differences

Abstract

Proton magnetic resonance spectroscopic imaging (1H‐MRSI) is a powerful tool that enables the multidimensional non‐invasive mapping of the neurochemical profile at high resolution over the entire brain. The constant demand for higher spatial resolution in 1H‐MRSI has led to increased interest in post‐processing‐based denoising methods aimed at reducing noise variance. The aim of the present study was to implement two noise‐reduction techniques, Marchenko–Pastur principal component analysis (MP‐PCA) based denoising and low‐rank total generalized variation (LR‐TGV) reconstruction, and to test their potential with and impact on preclinical 14.1 T fast in vivo 1H‐FID‐MRSI datasets. Since there is no known ground truth for in vivo metabolite maps, additional evaluations of the performance of both noise‐reduction strategies were conducted using Monte Carlo simulations. Results showed that both denoising techniques increased the apparent signal‐to‐noise ratio (SNR) while preserving noise properties in each spectrum for both in vivo and Monte Carlo datasets. Relative metabolite concentrations were not significantly altered by either method and brain regional differences were preserved in both synthetic and in vivo datasets. Increased precision of metabolite estimates was observed for the two methods, with inconsistencies noted for lower‐concentration metabolites. Our study provided a framework for how to evaluate the performance of MP‐PCA and LR‐TGV methods for preclinical 1H‐FID MRSI data at 14.1 T. While gains in apparent SNR and precision were observed, concentration estimations ought to be treated with care, especially for low‐concentration metabolites. [ABSTRACT FROM AUTHOR]

Published

2024

4. Fast high-resolution metabolite mapping on a preclinical 14.1T scanner using 1H-FID-MRSI

Author

Simicic, Dunja, primary, Alves, Brayan, additional, Mosso, Jessie, additional, Lê, Thanh Phong, additional, van Heeswijk, Ruud B., additional, Starcukova, Jana, additional, Klauser, Antoine, additional, Strasser, Bernhard, additional, Bogner, Wolfgang, additional, and Cudalbu, Cristina, additional

5. MP-PCA and Low-rank noise-reduction in 1H-FID-MRSI data in the rat brain at 14.1T

Author

Alves, Brayan, primary, Simicic, Dunja, additional, Mosso, Jessie, additional, Jelescu, Ileana, additional, Cudalbu, Cristina, additional, and Klauser, Antoine, additional

6. Noise-reduction techniques for 1 H-FID-MRSI at 14.1 T: Monte Carlo validation and in vivo application.

Author

Alves B, Simicic D, Mosso J, Lê TP, Briand G, Bogner W, Lanz B, Strasser B, Klauser A, and Cudalbu C

Subjects

Proton Magnetic Resonance Spectroscopy methods, Humans, Male, Principal Component Analysis, Reproducibility of Results, Computer Simulation, Magnetic Resonance Imaging methods, Animals, Monte Carlo Method, Signal-To-Noise Ratio, Brain metabolism, Brain diagnostic imaging

Abstract

Proton magnetic resonance spectroscopic imaging ( 1 H-MRSI) is a powerful tool that enables the multidimensional non-invasive mapping of the neurochemical profile at high resolution over the entire brain. The constant demand for higher spatial resolution in 1 H-MRSI has led to increased interest in post-processing-based denoising methods aimed at reducing noise variance. The aim of the present study was to implement two noise-reduction techniques, Marchenko-Pastur principal component analysis (MP-PCA) based denoising and low-rank total generalized variation (LR-TGV) reconstruction, and to test their potential with and impact on preclinical 14.1 T fast in vivo 1 H-FID-MRSI datasets. Since there is no known ground truth for in vivo metabolite maps, additional evaluations of the performance of both noise-reduction strategies were conducted using Monte Carlo simulations. Results showed that both denoising techniques increased the apparent signal-to-noise ratio (SNR) while preserving noise properties in each spectrum for both in vivo and Monte Carlo datasets. Relative metabolite concentrations were not significantly altered by either method and brain regional differences were preserved in both synthetic and in vivo datasets. Increased precision of metabolite estimates was observed for the two methods, with inconsistencies noted for lower-concentration metabolites. Our study provided a framework for how to evaluate the performance of MP-PCA and LR-TGV methods for preclinical 1 H-FID MRSI data at 14.1 T. While gains in apparent SNR and precision were observed, concentration estimations ought to be treated with care, especially for low-concentration metabolites., (© 2024 The Author(s). NMR in Biomedicine published by John Wiley & Sons Ltd.)

Published

2024