Your search keyword '"Richard J. Eames"' showing total 3 results

1. T 1 mapping performance and measurement repeatability: results from the multi-national T 1 mapping standardization phantom program (T1MES)

Author

Gabriella Captur, Abhiyan Bhandari, Rüdiger Brühl, Bernd Ittermann, Kathryn E. Keenan, Ye Yang, Richard J. Eames, Giulia Benedetti, Camilla Torlasco, Lewis Ricketts, Redha Boubertakh, Nasri Fatih, John P. Greenwood, Leonie E. M. Paulis, Chris B. Lawton, Chiara Bucciarelli-Ducci, Hildo J. Lamb, Richard Steeds, Steve W. Leung, Colin Berry, Sinitsyn Valentin, Andrew Flett, Charlotte de Lange, Francesco DeCobelli, Magalie Viallon, Pierre Croisille, David M. Higgins, Andreas Greiser, Wenjie Pang, Christian Hamilton-Craig, Wendy E. Strugnell, Tom Dresselaers, Andrea Barison, Dana Dawson, Andrew J. Taylor, François-Pierre Mongeon, Sven Plein, Daniel Messroghli, Mouaz Al-Mallah, Stuart M. Grieve, Massimo Lombardi, Jihye Jang, Michael Salerno, Nish Chaturvedi, Peter Kellman, David A. Bluemke, Reza Nezafat, Peter Gatehouse, James C. Moon, and on behalf of the T1MES Consortium

Subjects

T 1 mapping, Standardization, Calibration, Phantom, Repeatability, Extracellular volume, Diseases of the circulatory (Cardiovascular) system, RC666-701

Abstract

Abstract Background The T 1 Mapping and Extracellular volume (ECV) Standardization (T1MES) program explored T 1 mapping quality assurance using a purpose-developed phantom with Food and Drug Administration (FDA) and Conformité Européenne (CE) regulatory clearance. We report T 1 measurement repeatability across centers describing sequence, magnet, and vendor performance. Methods Phantoms batch-manufactured in August 2015 underwent 2 years of structural imaging, B 0 and B 1, and “reference” slow T 1 testing. Temperature dependency was evaluated by the United States National Institute of Standards and Technology and by the German Physikalisch-Technische Bundesanstalt. Center-specific T 1 mapping repeatability (maximum one scan per week to minimum one per quarter year) was assessed over mean 358 (maximum 1161) days on 34 1.5 T and 22 3 T magnets using multiple T 1 mapping sequences. Image and temperature data were analyzed semi-automatically. Repeatability of serial T 1 was evaluated in terms of coefficient of variation (CoV), and linear mixed models were constructed to study the interplay of some of the known sources of T 1 variation. Results Over 2 years, phantom gel integrity remained intact (no rips/tears), B 0 and B 1 homogenous, and “reference” T 1 stable compared to baseline (% change at 1.5 T, 1.95 ± 1.39%; 3 T, 2.22 ± 1.44%). Per degrees Celsius, 1.5 T, T 1 (MOLLI 5s(3s)3s) increased by 11.4 ms in long native blood tubes and decreased by 1.2 ms in short post-contrast myocardium tubes. Agreement of estimated T 1 times with “reference” T 1 was similar across Siemens and Philips CMR systems at both field strengths (adjusted R 2 ranges for both field strengths, 0.99–1.00). Over 1 year, many 1.5 T and 3 T sequences/magnets were repeatable with mean CoVs

Published

2020

2. A medical device-grade T1 and ECV phantom for global T1 mapping quality assurance—the T1 Mapping and ECV Standardization in cardiovascular magnetic resonance (T1MES) program

Author

Michael Salerno, Kathryn E. Keenan, Redha Boubertakh, Gabriella Captur, Jacqueline Donovan, Camilla Torlasco, Celine Royet, Martin J. Graves, Richard J. Eames, Friso Gerben Heslinga, Reza Nezafat, Marcel Prothmann, Andrew Bathgate, Giulia Benedetti, Ruediger Bruehl, Peter D. Gatehouse, James C. Moon, Peter Kellman, Wenjie Pang, Bernd Ittermann, Magnetic Detection and Imaging, Faculty of Science and Technology, Captur, G, Gatehouse, P, Keenan, K, Heslinga, F, Bruehl, R, Prothmann, M, Graves, M, Eames, R, Torlasco, C, Benedetti, G, Donovan, J, Ittermann, B, Boubertakh, R, Bathgate, A, Royet, C, Pang, W, Nezafat, R, Salerno, M, Kellman, P, Moon, J, Graves, Martin [0000-0003-4327-3052], and Apollo - University of Cambridge Repository

Subjects

Medical device, Phantom, Standardization, 030204 cardiovascular system & hematology, Imaging phantom, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Medicine, Radiology, Nuclear Medicine and imaging, IR-102571, Medicine(all), MED/36 - DIAGNOSTICA PER IMMAGINI E RADIOTERAPIA, Reproducibility, Radiological and Ultrasound Technology, medicine.diagnostic_test, business.industry, Magnetic resonance imaging, MED/11 - MALATTIE DELL'APPARATO CARDIOVASCOLARE, T1 mapping, Design collaboration, 3. Good health, Metrology, T$_1$ mapping, Cardiovascular and Metabolic Diseases, METIS-319593, Cardiology and Cardiovascular Medicine, Nuclear medicine, business, Quality assurance

Abstract

$\textbf{Background:}$ T$_1$ mapping and extracellular volume (ECV) have the potential to guide patient care and serve as surrogate end-points in clinical trials, but measurements differ between cardiovascular magnetic resonance (CMR) scanners and pulse sequences. To help deliver T$_1$ mapping to global clinical care, we developed a phantom-based quality assurance (QA) system for verification of measurement stability over time at individual sites, with further aims of generalization of results across sites, vendor systems, software versions and imaging sequences. We thus created T1MES: The T1 Mapping and ECV Standardization Program. $\textbf{Methods:}$ A design collaboration consisting of a specialist MRI small-medium enterprise, clinicians, physicists and national metrology institutes was formed. A phantom was designed covering clinically relevant ranges of T$_1$ and T$_2$ in blood and myocardium, pre and post-contrast, for 1.5 T and 3 T. Reproducible mass manufacture was established. The device received regulatory clearance by the Food and Drug Administration (FDA) and Conformité Européene (CE) marking. $\textbf{Results:}$ The T1MES phantom is an agarose gel-based phantom using nickel chloride as the paramagnetic relaxation modifier. It was reproducibly specified and mass-produced with a rigorously repeatable process. Each phantom contains nine differently-doped agarose gel tubes embedded in a gel/beads matrix. Phantoms were free of air bubbles and susceptibility artifacts at both field strengths and T$_1$ maps were free from off-resonance artifacts. The incorporation of high-density polyethylene beads in the main gel fill was effective at flattening the $B_1$ field. T$_1$ and T$_2$ values measured in T1MES showed coefficients of variation of 1 % or less between repeat scans indicating good short-term reproducibility. Temperature dependency experiments confirmed that over the range 15-30 °C the short-T$_1$ tubes were more stable with temperature than the long-T$_1$ tubes. A batch of 69 phantoms was mass-produced with random sampling of ten of these showing coefficients of variations for T$_1$ of 0.64 ± 0.45 % and 0.49 ± 0.34 % at 1.5 T and 3 T respectively. $\textbf{Conclusion:}$ The T1MES program has developed a T$_1$ mapping phantom to CE/FDA manufacturing standards. An initial 69 phantoms with a multi-vendor user manual are now being scanned fortnightly in centers worldwide. Future results will explore T$_1$ mapping sequences, platform performance, stability and the potential for standardization.

Published

2016

3. A medical device-grade T1 and ECV phantom for global T1 mapping quality assurance-the T

Author

Gabriella, Captur, Peter, Gatehouse, Kathryn E, Keenan, Friso G, Heslinga, Ruediger, Bruehl, Marcel, Prothmann, Martin J, Graves, Richard J, Eames, Camilla, Torlasco, Giulia, Benedetti, Jacqueline, Donovan, Bernd, Ittermann, Redha, Boubertakh, Andrew, Bathgate, Celine, Royet, Wenjie, Pang, Reza, Nezafat, Michael, Salerno, Peter, Kellman, and James C, Moon

Subjects

Phantom, Research, T1 mapping, Standardization

Abstract

Background T1 mapping and extracellular volume (ECV) have the potential to guide patient care and serve as surrogate end-points in clinical trials, but measurements differ between cardiovascular magnetic resonance (CMR) scanners and pulse sequences. To help deliver T1 mapping to global clinical care, we developed a phantom-based quality assurance (QA) system for verification of measurement stability over time at individual sites, with further aims of generalization of results across sites, vendor systems, software versions and imaging sequences. We thus created T1MES: The T1 Mapping and ECV Standardization Program. Methods A design collaboration consisting of a specialist MRI small-medium enterprise, clinicians, physicists and national metrology institutes was formed. A phantom was designed covering clinically relevant ranges of T1 and T2 in blood and myocardium, pre and post-contrast, for 1.5 T and 3 T. Reproducible mass manufacture was established. The device received regulatory clearance by the Food and Drug Administration (FDA) and Conformité Européene (CE) marking. Results The T1MES phantom is an agarose gel-based phantom using nickel chloride as the paramagnetic relaxation modifier. It was reproducibly specified and mass-produced with a rigorously repeatable process. Each phantom contains nine differently-doped agarose gel tubes embedded in a gel/beads matrix. Phantoms were free of air bubbles and susceptibility artifacts at both field strengths and T1 maps were free from off-resonance artifacts. The incorporation of high-density polyethylene beads in the main gel fill was effective at flattening the B1 field. T1 and T2 values measured in T1MES showed coefficients of variation of 1 % or less between repeat scans indicating good short-term reproducibility. Temperature dependency experiments confirmed that over the range 15–30 °C the short-T1 tubes were more stable with temperature than the long-T1 tubes. A batch of 69 phantoms was mass-produced with random sampling of ten of these showing coefficients of variations for T1 of 0.64 ± 0.45 % and 0.49 ± 0.34 % at 1.5 T and 3 T respectively. Conclusion The T1MES program has developed a T1 mapping phantom to CE/FDA manufacturing standards. An initial 69 phantoms with a multi-vendor user manual are now being scanned fortnightly in centers worldwide. Future results will explore T1 mapping sequences, platform performance, stability and the potential for standardization. Electronic supplementary material The online version of this article (doi:10.1186/s12968-016-0280-z) contains supplementary material, which is available to authorized users.

Published

2016