Your search keyword '"Jonas Schollenberger"' showing total 2 results

1. Noninvasive quantification of cerebrovascular pressure changes using 4D Flow MRI

Author

C. Alberto Figueroa, Alistair A. Young, Susanne Schnell, Yue Ma, Jonas Schollenberger, David Nordsletten, Elazer R. Edelman, David Marlevi, Maria Aristova, and Edward Ferdian

Subjects

Physics, Mean squared error, Hemodynamics, Magnetic Resonance Imaging, Healthy Volunteers, Bernoulli's principle, Imaging, Three-Dimensional, Nuclear magnetic resonance, Sampling (signal processing), Healthy volunteers, Relative pressure, Image noise, Humans, Computer Simulation, Radiology, Nuclear Medicine and imaging, Image resolution, Blood Flow Velocity

Abstract

Purpose Hemodynamic alterations are indicative of cerebrovascular disease. However, the narrow and tortuous cerebrovasculature complicates image-based assessment, especially when quantifying relative pressure. Here, we present a systematic evaluation of image-based cerebrovascular relative pressure mapping, investigating the accuracy of the routinely used reduced Bernoulli (RB), the extended unsteady Bernoulli (UB), and the full-field virtual work-energy relative pressure ( ν WERP) method. Methods Patient-specific in silico models were used to generate synthetic cerebrovascular 4D Flow MRI, with RB, UB, and ν WERP performance quantified as a function of spatiotemporal sampling and image noise. Cerebrovascular relative pressures were also derived in 4D Flow MRI from healthy volunteers ( n = 8 ), acquired at two spatial resolutions (dx = 1.1 and 0.8 mm). Results The in silico analysis indicate that accurate relative pressure estimations are inherently coupled to spatial sampling: at dx = 1.0 mm high errors are reported for all methods; at dx = 0.5 mm ν WERP recovers relative pressures at a mean error of 0.02 ± 0.25 mm Hg, while errors remain higher for RB and UB (mean error of -2.18 ± 1.91 and -2.18 ± 1.87 mm Hg, respectively). The dependence on spatial sampling is also indicated in vivo, albeit with higher correlative dependence between resolutions using ν WERP (k = 0.64, R2 = 0.81 for dx = 1.1 vs. 0.8 mm) than with RB or UB (k = 0.04, R2 = 0.03, and k = 0.07, R2 = 0.07, respectively). Conclusion Image-based full-field methods such as ν WERP enable cerebrovascular relative pressure mapping; however, accuracy is directly dependent on utilized spatial resolution.

Published

2021

2. Practical considerations for territorial perfusion mapping in the cerebral circulation using super‐selective pseudo‐continuous arterial spin labeling

Author

C. Alberto Figueroa, Jon-Fredrik Nielsen, Luis Hernandez-Garcia, and Jonas Schollenberger

Subjects

Adult, Male, Image quality, Signal-To-Noise Ratio, Article, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, Cerebral circulation, 0302 clinical medicine, Calibration, Humans, Computer Simulation, Radiology, Nuclear Medicine and imaging, Mathematics, Brain, Reproducibility of Results, Heart, Arteries, Perfusion, Cerebrovascular Circulation, Arterial spin labeling, Female, Spin Labels, Continuous arterial spin labeling, Rotation (mathematics), Location tracking, Blood Flow Velocity, Magnetic Resonance Angiography, 030217 neurology & neurosurgery, Biomedical engineering

Abstract

Purpose This paper discusses several challenges faced by super-selective pseudo-continuous arterial spin labeling, which is used to quantify territorial perfusion in the cerebral circulation. The effects of off-resonance, pulsatility, vessel movement, and label rotation scheme are investigated, and methods to maximize labeling efficiency and overall image quality are evaluated. A strategy to calculate the territorial perfusion fractions of individual vessels is proposed. Methods The effects of off-resonance, label rotation scheme, and vessel movement on labeling efficiency were simulated. Two off-resonance compensation strategies (multiphase prescan, field map), cardiac triggering, and vessel movement were studied in vivo in a group of 10 subjects. Subsequently, a territorial perfusion fraction map was acquired in 2 subjects based on the mean vessel labeling efficiency. Results Multiphase calibration provided the highest labeling efficiency (P = .002) followed by the field map compensation (P = .037) compared with the uncompensated acquisition. Cardiac triggering resulted in a qualitative improvement of the image and an increase in signal contrast between the perfusion territory and the surrounding tissue (P = .010) but failed to show a significant change in temporal and spatial SNR. The constant clockwise label rotation scheme yielded the highest labeling efficiency. Significant vessel movement (>2 mm according to simulations) was observed in 50% of subjects. The measured territorial perfusion fractions showed good agreement with anatomical data. Conclusion Optimized labeling efficiency resulted in increased image quality and accuracy of territorial perfusion fraction maps. Labeling efficiency depends critically on off-resonance calibration, cardiac triggering, optimal label rotation scheme, and vessel location tracking.

Published

2019