Your search keyword '"Pascal Stang"' showing total 23 results

1. Microcontrollers in Music HCI Instruction - Reflections on our Switch to the Atmel AVR Platform.

Author

Scott Wilson, Michael Gurevich, Bill Verplank, and Pascal Stang

Published

2003

2. Stanley: The robot that won the DARPA Grand Challenge.

Author

Sebastian Thrun, Michael Montemerlo, Hendrik Dahlkamp, David Stavens, Andrei Aron, James Diebel, Philip W. Fong, John Gale, Morgan Halpenny, Gabriel Hoffmann, Kenny Lau, Celia M. Oakley, Mark Palatucci, Vaughan R. Pratt, Pascal Stang, Sven Strohband, Cedric Dupont, Lars-Erik Jendrossek, Christian Koelen, Charles Markey, Carlo Rummel, Joe van Niekerk, Eric Jensen, Philippe Alessandrini, Gary R. Bradski, Bob Davies, Scott Ettinger, Adrian Kaehler, Ara V. Nefian, and Pamela Mahoney

Published

2006

3. Thermo-Acoustic Ultrasound for Detection of RF-Induced Device Lead Heating in MRI

Author

Greig C. Scott, Neerav Dixit, Pascal Stang, and John M. Pauly

Subjects

Scanner, Hot Temperature, Materials science, Radio Waves, Signal, Article, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Image Processing, Computer-Assisted, medicine, Humans, Computer Simulation, Electrical and Electronic Engineering, Lead (electronics), Ultrasonography, Radiological and Ultrasound Technology, medicine.diagnostic_test, Phantoms, Imaging, business.industry, Ultrasound, Signal Processing, Computer-Assisted, Magnetic resonance imaging, Equipment Design, Prostheses and Implants, Magnetic Resonance Imaging, Computer Science Applications, Thermography, Electromagnetic coil, Patient Safety, Radio frequency, business, 030217 neurology & neurosurgery, Software, Biomedical engineering

Abstract

Patients who have implanted medical devices with long conductive leads are often restricted from receiving MRI scans due to the danger of RF-induced heating near the lead tips. Phantom studies have shown that this heating varies significantly on a case-by-case basis, indicating that many patients with implanted devices can receive clinically useful MRI scans without harm. However, the difficulty of predicting RF-induced lead tip heating prior to scanning prevents numerous implant recipients from being scanned. Here, we demonstrate that thermo-acoustic ultrasound (TAUS) has the potential to be utilized for a pre-scan procedure assessing the risk of RF-induced lead tip heating in MRI. A system was developed to detect TAUS signals by four different TAUS acquisition methods. We then integrated this system with an MRI scanner and detected a peak in RF power absorption near the tip of a model lead when transmitting from the scanner's body coil. We also developed and experimentally validated simulations to characterize the thermo-acoustic signal generated near lead tips. These results indicate that TAUS is a promising method for assessing RF implant safety, and with further development, a TAUS pre-scan could allow many more patients to have access to MRI scans of significant clinical value.

Published

2018

4. An RF-gated wireless power transfer system for wireless MRI receive arrays

Author

Pascal Stang, Kelly Byron, John M. Pauly, Fraser Robb, Greig C. Scott, and Shreyas S. Vasanawala

Subjects

Radiological and Ultrasound Technology, business.industry, Computer science, 020208 electrical & electronic engineering, Electrical engineering, 02 engineering and technology, Noise (electronics), Article, 030218 nuclear medicine & medical imaging, law.invention, Background noise, 03 medical and health sciences, Electric power system, Capacitor, 0302 clinical medicine, law, Electromagnetic coil, 0202 electrical engineering, electronic engineering, information engineering, Wireless, Radiology, Nuclear Medicine and imaging, Wireless power transfer, Physical and Theoretical Chemistry, business, Energy harvesting, Spectroscopy

Abstract

In MRI systems, cable-free receive arrays would simplify setup while reducing the bulk and weight of coil arrays and improve patient comfort and throughput. Since battery power would limit scan time, wireless power transfer (WPT) is a viable option to continuously supply several watts of power to on-coil electronics. To minimize added noise and decouple the wireless power system from MRI coils, restrictions are placed on the coil geometry of the wireless power system, which are shown to limit its efficiency. Continuous power harvesting can also cause a large increase in the background noise of the image due to diode rectifier up-conversion of noise around the frequency of the transmitted power. However, by RF gating the transmitted power off during the MRI receive time while continuing to supply power from a storage capacitor, WPT is demonstrated to have minimal impact on image quality at received power levels up to 11 W. The integration of WPT with a 1.5T scanner is demonstrated.

Published

2019

5. Corrigendum to 'Design and implementation of a low-cost, tabletop MRI scanner for education and research prototyping' [J. Magn. Reson. 310 (2020) 106625]

Author

Feng Jia, Thomas Witzel, Jason P. Stockmann, Lawrence L. Wald, Wenhui Yang, Greig C. Scott, Elfar Adalsteinsson, Clarissa Zimmerman Cooley, Wang Zheng, Azma Mareyam, Jacob K. White, Pascal Stang, Cris LaPierre, and Maxim Zaitsev

Subjects

Nuclear and High Energy Physics, Scanner, Computer science, Computer graphics (images), Biophysics, Condensed Matter Physics, Biochemistry

Published

2020

6. Design and implementation of a low-cost, tabletop MRI scanner for education and research prototyping

Author

Feng Jia, Elfar Adalsteinsson, Wang Zheng, Lawrence L. Wald, Azma Mareyam, Pascal Stang, Jacob K. White, Yang Wen-hui, Greig C. Scott, Thomas Witzel, Jason P. Stockmann, Maxim Zaitsev, Cris LaPierre, and Clarissa Zimmerman Cooley

Subjects

Diagnostic Imaging, Nuclear and High Energy Physics, Engineering drawing, Scanner, Signal processing, Phantoms, Imaging, Research, Teaching, Testbed, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Biophysics, Schematic, Signal Processing, Computer-Assisted, Equipment Design, 010402 general chemistry, Condensed Matter Physics, Magnetic Resonance Imaging, 01 natural sciences, Biochemistry, 030218 nuclear medicine & medical imaging, 0104 chemical sciences, 03 medical and health sciences, Electromagnetic Fields, 0302 clinical medicine, Students

Abstract

While access to a laboratory MRI system is ideal for teaching MR physics as well as many aspects of signal processing, providing multiple MRI scanners can be prohibitively expensive for educational settings. To address this need, we developed a small, low-cost, open-interface tabletop MRI scanner for academic use. We constructed and tested 20 of these scanners for parallel use by teams of 2–3 students in a teaching laboratory. With simplification and down-scaling to a 1 cm FOV, fully-functional scanners were achieved within a budget of $10,000 USD each. The design was successful for teaching MR principles and basic signal processing skills and serves as an accessible testbed for more advanced MR research projects. Customizable GUIs, pulse sequences, and reconstruction code accessible to the students facilitated tailoring the scanner to the needs of laboratory exercise. The scanners have been used by >800 students in 6 different courses and all designs, schematics, sequences, GUIs, and reconstruction code is open-source.

Published

2020

7. Controlling radiofrequency-induced currents in guidewires using parallel transmit

Author

Greig C. Scott, Adam B. Kerr, Maryam Etezadi-Amoli, John M. Pauly, and Pascal Stang

Subjects

Coupling, Materials science, business.industry, Acoustics, Ranging, Null (physics), Imaging phantom, Dielectric heating, Radiology, Nuclear Medicine and imaging, Current sensor, Current (fluid), Telecommunications, business, Electrical conductor

Abstract

Purpose Elongated conductors, such as pacemaker leads, neurostimulator leads, and conductive guidewires used for interventional procedures can couple to the MRI radiofrequency (RF) transmit field, potentially causing dangerous tissue heating. The purpose of this study was to demonstrate the feasibility of using parallel transmit to control induced RF currents in elongated conductors, thereby reducing the RF heating hazard. Methods Phantom experiments were performed on a four-channel parallel transmit system at 1.5T. Parallel transmit “null mode” excitations that induce minimal wire current were designed using coupling measurements derived from axial B1+ maps. The resulting current reduction performance was evaluated with B1+ maps, current sensor measurements, and fluoroptic temperature probe measurements. Results Null mode excitations reduced the maximum coupling mode current by factors ranging from 2 to 80. For the straight wire experiment, a current null imposed at a single wire location was sufficient to reduce tip heating below detectable levels. For longer insertion lengths and a curved geometry, imposing current nulls at two wire locations resulted in more distributed current reduction along the wire length. Conclusion Parallel transmit can be used to create excitations that induce minimal RF current in elongated conductors, thereby decreasing the RF heating risk, while still allowing visualization of the surrounding volume. Magn Reson Med, 2014. © 2014 Wiley Periodicals, Inc.

Published

2014

8. Interventional device visualization with toroidal transceiver and optically coupled current sensor for radiofrequency safety monitoring

Author

Adam B. Kerr, Greig C. Scott, John M. Pauly, Maryam Etezadi-Amoli, and Pascal Stang

Subjects

Materials science, Electromagnetic coil, Interventional magnetic resonance imaging, Acoustics, Dielectric heating, Radiology, Nuclear Medicine and imaging, Current sensor, Transceiver, Fiducial marker, Electrical conductor, Imaging phantom

Abstract

Purpose The development of catheters and guidewires that are safe from radiofrequency (RF) -induced heating and clearly visible against background tissue is a major challenge in interventional MRI. An interventional imaging approach using a toroidal transmit–receive (transceive) coil is presented. This toroidal transceiver allows controlled, low levels of RF current to flow in the catheter/guidewire for visualization, and can be used with conductive interventional devices that have a localized low-impedance tip contact. Methods Toroidal transceivers were built, and phantom experiments were performed to quantify transmit power levels required for device visibility and to detect heating hazards. Imaging experiments in a pig cadaver tested the extendibility to higher field strength and nonphantom settings. A photonically powered optically coupled toroidal current sensor for monitoring induced RF currents was built, calibrated, and tested using an independent image-based current estimation method. Results Results indicate that high signal-to-noise ratio visualization is achievable using milliwatts of transmit power—power levels orders of magnitude lower than levels that induce measurable heating in phantom tests. Agreement between image-based current estimates and RF current sensor measurements validates sensor accuracy. Conclusion The toroidal transceiver, integrated with power and current sensing, could offer a promising platform for safe and effective interventional device visualization. Magn Reson Med 73:1315–1327, 2015. © 2014 Wiley Periodicals, Inc.

Published

2014

9. Offline impedance measurements for detection and mitigation of dangerous implant interactions: An RF safety prescreen

Author

Pascal Stang, Maryam Etezadi-Amoli, Greig C. Scott, John M. Pauly, and Christopher W. Ellenor

Subjects

implant safety, Materials science, Radio Waves, interventional MRI, Acoustics, Sensitivity and Specificity, Imaging phantom, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Nuclear magnetic resonance, Scattering parameters, Humans, parallel radiofrequency transmission, Radiology, Nuclear Medicine and imaging, Current sensor, Electrical conductor, Electrical impedance, Equipment Safety, Phantoms, Imaging, Contraindications, Burns, Electric, Reproducibility of Results, Hardware and Instrumentation—Full Papers, RF safety, Equipment Design, Prostheses and Implants, pacemakers and MRI, Network analyzer (electrical), Magnetic Resonance Imaging, Equipment Failure Analysis, Electromagnetic coil, 030217 neurology & neurosurgery, Radiofrequency coil

Abstract

Purpose The concept of a “radiofrequency safety prescreen” is investigated, wherein dangerous interactions between radiofrequency fields used in MRI, and conductive implants in patients are detected through impedance changes in the radiofrequency coil. Theory The behavior of coupled oscillators is reviewed, and the resulting, observable impedance changes are discussed. Methods A birdcage coil is loaded with a static head phantom and a wire phantom with a wire close to its resonant length, the shape, position, and orientation of which can be changed. Interactions are probed with a current sensor and network analyzer. Results Impedance spectra show dramatic, unmistakable splitting in cases of strong coupling, and strong correlation is observed between induced current and scattering parameters. Conclusions The feasibility of a new, low-power prescreening technique has been demonstrated in a simple phantom experiment, which can unambiguously detect resonant interactions between an implanted wire and an imaging coil. A new technique has also been presented which can detect parallel transmit null modes for the wire. Magn Reson Med 73:1328–1339, 2015. © 2014 Wiley Periodicals, Inc.

Published

2014

10. RF Field Visualization of RF Ablation at the Larmor Frequency

Author

Greig C. Scott, K. Shultz, Adam B. Kerr, John M. Pauly, and Pascal Stang

Subjects

Electromagnetic field, Materials science, Swine, medicine.medical_treatment, Catheter ablation, Article, Body Temperature, Electromagnetic Fields, Nuclear magnetic resonance, medicine, Animals, Electrical and Electronic Engineering, Larmor precession, Radiological and Ultrasound Technology, medicine.diagnostic_test, Electric Conductivity, Magnetic resonance imaging, Ablation, Magnetic Resonance Imaging, Computer Science Applications, Surgery, Computer-Assisted, Thermography, Catheter Ablation, Feasibility Studies, Radio frequency, Current density, Software, Biomedical engineering

Abstract

Radio-frequency ablation (RFA) is an effective minimally invasive treatment for tumors. One primary source of difficulty is monitoring and controlling the ablation region. Currently, RFA is performed at 460 kHz, for which magnetic resonance imaging (MRI) could play a role given its capability for temperature monitoring and tumor visualization. If instead the ablation were to be performed at the MRI Larmor frequency, then the MR capability for B(1) field mapping could be used to directly visualize the radio-frequency (RF) fields created by the ablation currents. Visualizing the RF fields may enable better control of the ablation currents, enabling better control of lesion shape and size and improving repeatability. We demonstrate the feasibility of performing RFAs at 64 MHz and show preliminary results from imaging the RF fields from the ablation. The post-ablation RF fields show an increase in current density in the ablated region, consistent with an increase in conductivity of the ablated tissue.

Published

2012

11. VERSE-guided numerical RF pulse design: A fast method for peak RF power control

Author

Pascal Stang, Michael Lustig, Adam B. Kerr, John M. Pauly, Daeho Lee, and William A. Grissom

Subjects

Phantoms, Imaging, Radio Waves, Computer science, RF power amplifier, Image processing, Models, Theoretical, Image Enhancement, Magnetic Resonance Imaging, Sensitivity and Specificity, Article, Pulse (physics), Controllability, Software Design, Image Processing, Computer-Assisted, Electronic engineering, Humans, Oversampling, Waveform, Software design, Radiology, Nuclear Medicine and imaging, Artifacts, Algorithms, Radio wave

Abstract

In parallel excitation, the computational speed of numerical radiofrequency (RF) pulse design methods is critical when subject dependencies and system nonidealities need to be incorporated on-the-fly. One important concern with optimization-based methods is high peak RF power exceeding hardware or safety limits. Hence, online controllability of the peak RF power is essential. Variable-rate selective excitation pulse reshaping is ideally suited to this problem due to its simplicity and low computational cost. In this work, we first improve the fidelity of variable-rate selective excitation implementation for discrete-time waveforms through waveform oversampling such that variable-rate selective excitation can be robustly applied to numerically designed RF pulses. Then, a variable-rate selective excitation-guided numerical RF pulse design is suggested as an online RF pulse design framework, aiming to simultaneously control peak RF power and compensate for off-resonance.

Published

2011

12. Multiparametric imaging of tumor oxygenation, redox status, and anatomical structure using overhauser-enhanced MRI-prepolarized MRI system

Author

Dimitre Hristov, Kang-Hyun Ahn, Pascal Stang, Greig C. Scott, and S. M. Conolly

Subjects

Nitroxide mediated radical polymerization, Nuclear magnetic resonance, Diagnostic quality, Field cycling, Tumor hypoxia, law, Chemistry, Power deposition, Radiology, Nuclear Medicine and imaging, Tumor Oxygenation, Electron paramagnetic resonance, Redox status, law.invention

Abstract

An integrated Overhauser-enhanced MRI-Prepolarized MRI system was developed to obtain radiobiological information that could be accurately coregistered with diagnostic quality anatomic images. EPR and NMR images were acquired through the double resonance technique and field cycling of the main magnetic field from 5 mT to 0.5 T. Dedicated EPR and NMR coils were devised to minimize radiofrequency power deposition with high signal-to-noise ratio. Trityl and nitroxide radicals were used to characterize oxygen and redox sensitivities of multispin echo Overhauser-enhanced MRI. Oxygen resolution of 3 mmHg was obtained from 2 mM deoxygenated trityl phantoms. Trityl radicals were stable in reducing environments and did not alter the redox-sensitive decaying rate of the nitroxide signals. Nitroxide radicals had a compounding effect for the trityl oximetry. Tumor oxygenation and redox status were acquired with anatomical images by injecting trityl and nitroxide probes subsequently in murine tumors. The Overhauser-enhanced MRI-Prepolarized MRI system is ready for quantitative longitudinal imaging studies of tumor hypoxia and redox status as radiotherapy prognostic factors.

Published

2010

13. Minimum envelope roughness pulse design for reduced amplifier distortion in parallel excitation

Author

Greig C. Scott, Adam B. Kerr, John M. Pauly, William A. Grissom, and Pascal Stang

Subjects

Physics, Signal processing, business.industry, Amplifier, Data_CODINGANDINFORMATIONTHEORY, Surface finish, Parallel excitation, Optics, Hardware_GENERAL, Amplifier distortion, Waveform, Radiology, Nuclear Medicine and imaging, Radio frequency, business, Communication channel

Abstract

Parallel excitation uses multiple transmit channels and coils, each driven by independent waveforms, to afford the pulse designer an additional spatial encoding mechanism that complements gradient encoding. In contrast to parallel reception, parallel excitation requires individual power amplifiers for each transmit channel, which can be cost prohibitive. Several groups have explored the use of low-cost power amplifiers for parallel excitation; however, such amplifiers commonly exhibit nonlinear memory effects that distort radio frequency pulses. This is especially true for pulses with rapidly varying envelopes, which are common in parallel excitation. To overcome this problem, we introduce a technique for parallel excitation pulse design that yields pulses with smoother envelopes. We demonstrate experimentally that pulses designed with the new technique suffer less amplifier distortion than unregularized pulses and pulses designed with conventional regularization.

Published

2010

14. Ensuring safety of implanted devices under MRI using reversed RF polarization

Author

Greig C. Scott, William R. Overall, Pascal Stang, and John M. Pauly

Subjects

Materials science, medicine.diagnostic_test, medicine, Safety Equipment, Radiology, Nuclear Medicine and imaging, Magnetic resonance imaging, Radio frequency, Polarization (waves), Imaging phantom, Radio wave, Biomedical engineering

Abstract

Patients with long-wire medical implants are currently prevented from undergoing magnetic resonance imaging (MRI) scans due to the risk of radio frequency (RF) heating. We have developed a simple technique for determining the heating potential for these implants using reversed radio frequency (RF) polarization. This technique could be used on a patient-to-patient basis as a part of the standard prescan procedure to ensure that the subject's device does not pose a heating risk. By using reversed quadrature polarization, the MR scan can be sensitized exclusively to the potentially dangerous currents in the device. Here, we derive the physical principles governing the technique and explore the primary sources of inaccuracy. These principles are verified through finite-difference simulations and through phantom scans of implant leads. These studies demonstrate the potential of the technique for sensitively detecting potentially dangerous coupling conditions before they can do any harm.

Published

2010

15. Narrowband Magnetic Particle Imaging

Author

Greig C. Scott, Steven M. Conolly, Patrick W. Goodwill, and Pascal Stang

Subjects

Materials science, Preamplifier, Ferric Compounds, Magnetics, Mice, Nuclear magnetic resonance, Optics, Narrowband, Magnetic particle imaging, Animals, Computer Simulation, Electrical and Electronic Engineering, Tomography, Tomographic reconstruction, Radiological and Ultrasound Technology, Phantoms, Imaging, business.industry, Bandwidth (signal processing), Specific absorption rate, Computer Science Applications, Liver, Nanoparticles, Magnetic nanoparticles, business, Algorithms, Software

Abstract

The magnetic particle imaging (MPI) method directly images the magnetization of super-paramagnetic iron oxide (SPIO) nanoparticles, which are contrast agents commonly used in magnetic resonance imaging (MRI). MPI, as originally envisioned, requires a high-bandwidth receiver coil and preamplifier, which are difficult to optimally noise match. This paper introduces Narrowband MPI, which dramatically reduces bandwidth requirements and increases the signal-to-noise ratio for a fixed specific absorption rate. We employ a two-tone excitation (called intermodulation) that can be tailored for a high-Q, narrowband receiver coil. We then demonstrate a new MPI instrument capable of full 3-D tomographic imaging of SPIO particles by imaging acrylic and tissue phantoms.

Published

2009

16. Interventional device visualization with toroidal transceiver and optically coupled current sensor for radiofrequency safety monitoring

Author

Maryam, Etezadi-Amoli, Pascal, Stang, Adam, Kerr, John, Pauly, and Greig, Scott

Subjects

Catheters, Equipment Safety, Phantoms, Imaging, Radio Waves, Burns, Electric, Reproducibility of Results, Equipment Design, Magnetic Resonance Imaging, Interventional, Sensitivity and Specificity, Article, Equipment Failure Analysis, Magnetics, Fiducial Markers, Thermography, Humans

Abstract

The development of catheters and guidewires that are safe from radiofrequency (RF) -induced heating and clearly visible against background tissue is a major challenge in interventional MRI. An interventional imaging approach using a toroidal transmit-receive (transceive) coil is presented. This toroidal transceiver allows controlled, low levels of RF current to flow in the catheter/guidewire for visualization, and can be used with conductive interventional devices that have a localized low-impedance tip contact.Toroidal transceivers were built, and phantom experiments were performed to quantify transmit power levels required for device visibility and to detect heating hazards. Imaging experiments in a pig cadaver tested the extendibility to higher field strength and nonphantom settings. A photonically powered optically coupled toroidal current sensor for monitoring induced RF currents was built, calibrated, and tested using an independent image-based current estimation method.Results indicate that high signal-to-noise ratio visualization is achievable using milliwatts of transmit power-power levels orders of magnitude lower than levels that induce measurable heating in phantom tests. Agreement between image-based current estimates and RF current sensor measurements validates sensor accuracy.The toroidal transceiver, integrated with power and current sensing, could offer a promising platform for safe and effective interventional device visualization.

Published

2013

17. Medusa: a scalable MR console using USB

Author

Juan M. Santos, Pascal Stang, John M. Pauly, Greig C. Scott, and S. M. Conolly

Subjects

Serial communication, Computer science, Transducers, USB, Sensitivity and Specificity, Synchronization, Article, Synthetic instrument, law.invention, Computer Communication Networks, Magnetics, law, Synchronization (computer science), Image Interpretation, Computer-Assisted, Electrical and Electronic Engineering, Scientific instrument, Radiological and Ultrasound Technology, business.industry, Reproducibility of Results, Signal Processing, Computer-Assisted, Equipment Design, Modular design, Magnetic Resonance Imaging, Computer Science Applications, Programmable logic device, Equipment Failure Analysis, Embedded system, Scalability, Proprietary hardware, business, Computer hardware, Software

Abstract

Magnetic resonance imaging (MRI) pulse sequence consoles typically employ closed proprietary hardware, software, and interfaces, making difficult any adaptation for innovative experimental technology. Yet MRI systems research is trending to higher channel count receivers, transmitters, gradient/shims, and unique interfaces for interventional applications. Customized console designs are now feasible for researchers with modern electronic components, but high data rates, synchronization, scalability, and cost present important challenges. Implementing large multichannel MR systems with efficiency and flexibility requires a scalable modular architecture. With Medusa, we propose an open system architecture using the universal serial bus (USB) for scalability, combined with distributed processing and buffering to address the high data rates and strict synchronization required by multichannel MRI. Medusa uses a modular design concept based on digital synthesizer, receiver, and gradient blocks, in conjunction with fast programmable logic for sampling and synchronization. Medusa is a form of synthetic instrument, being reconfigurable for a variety of medical/scientific instrumentation needs. The Medusa distributed architecture, scalability, and data bandwidth limits are presented, and its flexibility is demonstrated in a variety of novel MRI applications.

Published

2011

18. Frequency-offset Cartesian feedback for MRI power amplifier linearization

Author

John M. Pauly, Greig C. Scott, Pascal Stang, Marta G. Zanchi, and Adam B. Kerr

Subjects

Physics, Radiological and Ultrasound Technology, Fourier Analysis, Phantoms, Imaging, Amplifier, RF power amplifier, Automatic frequency control, Gain compression, Signal Processing, Computer-Assisted, Magnetic Resonance Imaging, Article, Computer Science Applications, Feedback, Linearization, Control theory, Image Processing, Computer-Assisted, Frequency offset, Radio frequency, Electrical and Electronic Engineering, Software, DC bias

Abstract

High-quality magnetic resonance imaging (MRI) requires precise control of the transmit radio-frequency (RF) field. In parallel excitation applications such as transmit SENSE, high RF power linearity is essential to cancel aliased excitations. In widely-employed class AB power amplifiers, gain compression, cross-over distortion, memory effects, and thermal drift all distort the RF field modulation and can degrade image quality. Cartesian feedback (CF) linearization can mitigate these effects in MRI, if the quadrature mismatch and dc offset imperfections inherent in the architecture can be minimized. In this paper, we present a modified Cartesian feedback technique called “frequency-offset Cartesian feedback” (FOCF) that significantly reduces these problems. In the FOCF architecture, the feedback control is performed at a low intermediate frequency rather than dc, so that quadrature ghosts and dc errors are shifted outside the control bandwidth. FOCF linearization is demonstrated with a variety of typical MRI pulses. Simulation of the magnetization obtained with the Bloch equation demonstrates that high-fidelity RF reproduction can be obtained even with inexpensive class AB amplifiers. Finally, the enhanced RF fidelity of FOCF over CF is demonstrated with actual images obtained in a 1.5 T MRI system.

Published

2010

19. Multiparametric imaging of tumor oxygenation, redox status, and anatomical structure using Overhauser-enhanced MRI-prepolarized MRI system

Author

Kang-Hyun, Ahn, Greig, Scott, Pascal, Stang, Steve, Conolly, and Dimitre, Hristov

Subjects

Male, Mice, Phantoms, Imaging, Animals, Feasibility Studies, Mice, Nude, Nitrogen Oxides, Trityl Compounds, Oximetry, Colorectal Neoplasms, Image Enhancement, Magnetic Resonance Imaging, Oxidation-Reduction

Abstract

An integrated Overhauser-enhanced MRI-Prepolarized MRI system was developed to obtain radiobiological information that could be accurately coregistered with diagnostic quality anatomic images. EPR and NMR images were acquired through the double resonance technique and field cycling of the main magnetic field from 5 mT to 0.5 T. Dedicated EPR and NMR coils were devised to minimize radiofrequency power deposition with high signal-to-noise ratio. Trityl and nitroxide radicals were used to characterize oxygen and redox sensitivities of multispin echo Overhauser-enhanced MRI. Oxygen resolution of 3 mmHg was obtained from 2 mM deoxygenated trityl phantoms. Trityl radicals were stable in reducing environments and did not alter the redox-sensitive decaying rate of the nitroxide signals. Nitroxide radicals had a compounding effect for the trityl oximetry. Tumor oxygenation and redox status were acquired with anatomical images by injecting trityl and nitroxide probes subsequently in murine tumors. The Overhauser-enhanced MRI-Prepolarized MRI system is ready for quantitative longitudinal imaging studies of tumor hypoxia and redox status as radiotherapy prognostic factors.

Published

2010

20. Stanley: The Robot That Won the DARPA Grand Challenge

Author

Sebastian Thrun, Mike Montemerlo, Hendrik Dahlkamp, David Stavens, Andrei Aron, James Diebel, Philip Fong, John Gale, Morgan Halpenny, Gabriel Hoffmann, Kenny Lau, Celia Oakley, Mark Palatucci, Vaughan Pratt, Pascal Stang, Sven Strohband, Cedric Dupont, Lars-Erik Jendrossek, Christian Koelen, Charles Markey, Carlo Rummel, Joe van Niekerk, Eric Jensen, Philippe Alessandrini, Gary Bradski, Bob Davies, Scott Ettinger, Adrian Kaehler, Ara Nefian, and Pamela Mahoney

Published

2007

21. Development and Teleoperation of Robotic Vehicles

Author

Jeffrey M. Ota, Pascal Stang, N. Quinn, Christopher Kitts, and B. Palmintier

Subjects

Computer science, Teleoperation, Control engineering

Published

2003

22. TH-D-304A-01: Development of Multi-Parametric Molecular Imager by Integrating Overhauser-Enhanced MRI (OMRI) with Prepolarized MRI (PMRI)

Author

Kang-Hyun Ahn, Dimitre Hristov, Pascal Stang, Greig C. Scott, and S. M. Conolly

Subjects

Nitroxide mediated radical polymerization, Materials science, medicine.diagnostic_test, Pulse (signal processing), Magnetic resonance imaging, General Medicine, Nuclear Overhauser effect, Imaging phantom, law.invention, Free induction decay, Nuclear magnetic resonance, law, medicine, Electron paramagnetic resonance, Hyperfine structure

Abstract

Purpose: To develop a multi‐parametric molecular imager to assess tumor hypoxia and redox status by integrating Overhauser‐enhanced MRI (OMRI) with prepolarized MRI (PMRI). Method and Materials: PMRI system acquires anatomic MR images comparable to conventional MRI. With a moderate hardware augmentation of the PMRI, we implemented field‐cycled OMRI and obtained electron paramagnetic resonance(EPR)images of nitroxide spin probes. Phantoms were made of 2‐cc tubes filled with pure water

Published

2009

23. Overhauser-enhanced MRI (OMRI) - Prepolarized MRI (PMRI) System for Longitudinal Explorations of Tumor Hypoxia and Redox Status as Radiotherapy Prognostic Factors

Author

Greig C. Scott, Pascal Stang, Kang-Hyun Ahn, Dimitre Hristov, and S. M. Conolly

Subjects

Radiation therapy, Cancer Research, medicine.medical_specialty, Radiation, Oncology, Tumor hypoxia, business.industry, medicine.medical_treatment, medicine, Radiology, Nuclear Medicine and imaging, Radiology, business, Redox status

Published

2010