Your search keyword '"Jafar, Maysam"' showing total 2 results

1. Assessment of a carbon fibre MRI flatbed insert for radiotherapy treatment planning.

Author

JAFAR, MAYSAM M., REEVES, JONATHAN, RUTHVEN, MATTHIEU A., DEAN, CHRISTOPHER J., MACDOUGALL, NIALL D., TUCKER, ARTHUR T., and MIQUEL, MARC E.

Subjects

*MAGNETIC resonance imaging, *CARBON fibers, *RADIOTHERAPY treatment planning, *THERMOMETRY, *RADIOFREQUENCY heating

Abstract

Objective: The purpose of this work was to assess heating and radiofrequency (RF) deposition and image quality effects of a prototype three-section carbon fibre flatbed insert for use in MRI. Methods: RF deposition was assessed using two different thermometry techniques, infrared thermometry and Bragg-grating thermometry. Image quality effects were assessed with and without the flatbed insert in place by using mineral oil phantoms and a human subject. Results: Neither technique detected heating of the insert in typical MRI examinations. We found that the insert was less suitable for MRI applications owing to severe RF shielding artefact. For spin-echo (SE), turbo spin-echo (TSE) and gradient-echo sequences, the reduction in signal-to-noise ratio (SNR) was as much as 89% when the insert was in place compared with the standard couch, making it less suitable as a patient-support material. Turning on the MultiTransmit switch together with using the scanner's quadrature body coil improved the reduction in SNR from 89% to 39% for the SE sequence and from 82% to 12% for the TSE sequence. Conclusion: No evidence was found to support reports in the literature that carbon fibre is an unsuitable material for use in MRI because of heating. Advances in knowledge: This study suggests that carbon fibre is less suitable for large-scale MRI applications owing to it causing severe RF shading. Further research is needed to establish the suitability of the flatbed for treatment planning using alternative sequences or whether an alternative carbon fibre composite for largescale MRI applications or a design that can minimize shielding can be found. [ABSTRACT FROM AUTHOR]

Published

2016

2. Model Free Approach to Kinetic Analysis of Real-Time Hyperpolarized 13C Magnetic Resonance Spectroscopy Data.

Author

Hill, Deborah K., Orton, Matthew R., Mariotti, Erika, Boult, Jessica K. R., Panek, Rafal, Jafar, Maysam, Parkes, Harold G., Jamin, Yann, Miniotis, Maria Falck, Al-Saffar, Nada M. S., Beloueche-Babari, Mounia, Robinson, Simon P., Leach, Martin O., Chung, Yuen-Li, and Eykyn, Thomas R.

Subjects

*CARBON isotopes, *NUCLEAR magnetic resonance spectroscopy, *METABOLIC flux analysis, *CHEMICAL kinetics, *CHEMICAL reactions, *CANCER cells, *CELL lines

Abstract

Real-time detection of the rates of metabolic flux, or exchange rates of endogenous enzymatic reactions, is now feasible in biological systems using Dynamic Nuclear Polarization Magnetic Resonance. Derivation of reaction rate kinetics from this technique typically requires multi-compartmental modeling of dynamic data, and results are therefore model-dependent and prone to misinterpretation. We present a model-free formulism based on the ratio of total areas under the curve (AUC) of the injected and product metabolite, for example pyruvate and lactate. A theoretical framework to support this novel analysis approach is described, and demonstrates that the AUC ratio is proportional to the forward rate constant k. We show that the model-free approach strongly correlates with k for whole cell in vitro experiments across a range of cancer cell lines, and detects response in cells treated with the pan-class I PI3K inhibitor GDC-0941 with comparable or greater sensitivity. The same result is seen in vivo with tumor xenograft-bearing mice, in control tumors and following drug treatment with dichloroacetate. An important finding is that the area under the curve is independent of both the input function and of any other metabolic pathways arising from the injected metabolite. This model-free approach provides a robust and clinically relevant alternative to kinetic model-based rate measurements in the clinical translation of hyperpolarized 13C metabolic imaging in humans, where measurement of the input function can be problematic. [ABSTRACT FROM AUTHOR]

Published

2013