Your search keyword '"Nina Weinfurtner"' showing total 3 results

1. Volumetric mapping of intra‐ and extracellular pH in the human brain using 31 P MRSI at 7T

Author

Peter Bachert, Nina Weinfurtner, Andreas Korzowski, Steffen Goerke, Johannes Breitling, Sebastian Mueller, Daniel Paech, Heinz Peter Schlemmer, and Mark E. Ladd

Subjects

Chemistry, Intracellular pH, Human brain, medicine.disease, computer.software_genre, White matter, medicine.anatomical_structure, In vivo, Voxel, Glioma, Healthy volunteers, Extracellular, medicine, Radiology, Nuclear Medicine and imaging, computer, Biomedical engineering

Abstract

Purpose: In vivo 31 P MRSI enables noninvasive mapping of absolute pH values via the pH-dependent chemical shifts of inorganic phosphates (Pi ). A particular challenge is the quantification of extracellular Pi with low SNR in vivo. The purpose of this study was to demonstrate feasibility of assessing both intra- and extracellular pH across the whole human brain via volumetric 31 P MRSI at 7T.Methods: 3D 31 P MRSI data sets of the brain were acquired from three healthy volunteers and three glioma patients. Low-rank denoising was applied to enhance the SNR of 31 P MRSI data sets that enables detection of extracellular Pi at high spatial resolutions. A robust two-compartment quantification model for intra- and extracellular Pi signals was implemented.Results: In particular low-rank denoising enabled volumetric mapping of intra- and extracellular pH in the human brain with voxel sizes of 5.7 mL. The average intra- and extracellular pH measured in white matter of healthy volunteers were 7.00 ± 0.00 and 7.33 ± 0.03, respectively. In tumor tissue of glioma patients, both the average intra- and extracellular pH increased to 7.12 ± 0.01 and 7.44 ± 0.01, respectively, compared to normal appearing tissue.Conclusion: Mapping of pH values via 31 P MRSI at 7T using the proposed two-compartment quantification model improves reliability of pH values obtained in vivo, and has the potential to provide novel insights into the pH heterogeneity of various tissues.

Published

2020

2. Dynamic glucose‐enhanced (DGE) MRI in the human brain at 7 T with reduced motion‐induced artifacts based on quantitative R1ρ mapping

Author

Steffen Goerke, Johannes Breitling, Peter Bachert, Daniel Paech, Nina Weinfurtner, Moritz Zaiss, Philip S. Boyd, Mark E. Ladd, Ferdinand Zimmermann, Heinz-Peter Schlemmer, Andreas Korzowski, and Patrick Schuenke

Subjects

Image Series, Computer science, media_common.quotation_subject, fungi, Human brain, Time gap, Motion (physics), 030218 nuclear medicine & medical imaging, Acquisition Protocol, 03 medical and health sciences, 0302 clinical medicine, medicine.anatomical_structure, Robustness (computer science), Relaxation rate, medicine, Contrast (vision), Radiology, Nuclear Medicine and imaging, 030217 neurology & neurosurgery, Biomedical engineering, media_common

Abstract

Purpose Dynamic glucose-enhanced (DGE)-MRI based on chemical exchange-sensitive MRI, that is, glucoCEST and gluco-chemical exchange-sensitive spin-lock (glucoCESL), is intrinsically prone to motion-induced artifacts because the final DGE contrast relies on the difference of images, which were acquired with a time gap of several mins. In this study, identification of different types of motion-induced artifacts led to the development of a 3D acquisition protocol for DGE examinations in the human brain at 7 T with improved robustness in the presence of subject motion. Methods DGE-MRI was realized by the chemical exchange-sensitive spin-lock approach based either on relaxation rate in the rotating frame (R1ρ )-weighted or quantitative R1ρ imaging. A 3D image readout was implemented at 7 T, enabling retrospective volumetric coregistration of the image series and quantification of subject motion. An examination of a healthy volunteer without administration of glucose allowed for the identification of isolated motion-induced artifacts. Results Even after coregistration, significant motion-induced artifacts remained in the DGE contrast based on R1ρ -weighted images. This is due to the spatially varying sensitivity of the coil and was found to be compensated by a quantitative R1ρ approach. The coregistered quantitative approach allowed the observation of a clear increase of the DGE contrast in a patient with glioblastoma, which did not correlate with subject motion. Conclusion The presented 3D acquisition protocol enables DGE-MRI examinations in the human brain with improved robustness against motion-induced artifacts. Correction of motion-induced artifacts is of high importance for DGE-MRI in clinical studies where an unambiguous assignment of contrast changes due to an actual change in local glucose concentration is a prerequisite.

Published

2020

3. Dynamic glucose-enhanced (DGE) MRI in the human brain at 7 T with reduced motion-induced artifacts based on quantitative R

Author

Philip S, Boyd, Johannes, Breitling, Ferdinand, Zimmermann, Andreas, Korzowski, Moritz, Zaiss, Patrick, Schuenke, Nina, Weinfurtner, Heinz-Peter, Schlemmer, Mark E, Ladd, Peter, Bachert, Daniel, Paech, and Steffen, Goerke

Subjects

Motion, Glucose, Brain, Humans, Artifacts, Image Enhancement, Magnetic Resonance Imaging, Retrospective Studies

Abstract

Dynamic glucose-enhanced (DGE)-MRI based on chemical exchange-sensitive MRI, that is, glucoCEST and gluco-chemical exchange-sensitive spin-lock (glucoCESL), is intrinsically prone to motion-induced artifacts because the final DGE contrast relies on the difference of images, which were acquired with a time gap of several mins. In this study, identification of different types of motion-induced artifacts led to the development of a 3D acquisition protocol for DGE examinations in the human brain at 7 T with improved robustness in the presence of subject motion.DGE-MRI was realized by the chemical exchange-sensitive spin-lock approach based either on relaxation rate in the rotating frame (REven after coregistration, significant motion-induced artifacts remained in the DGE contrast based on RThe presented 3D acquisition protocol enables DGE-MRI examinations in the human brain with improved robustness against motion-induced artifacts. Correction of motion-induced artifacts is of high importance for DGE-MRI in clinical studies where an unambiguous assignment of contrast changes due to an actual change in local glucose concentration is a prerequisite.

Published

2019