 |
|
Dancing atoms now understood
December 02, 2008Scientists crack secret of unusual magnetic resonance, key to enhanced MRIs
In developing a model to explain the motion of atoms in a magnetic field, scientists have overcome a decades-old obstacle to understanding a key component of magnetic resonance.
The new understanding may eventually lead to better control of magnetic resonance imaging (MRI) and higher resolution MRI diagnoses.
Collaborators at Ohio State University in Columbus and three institutions in France--the Centre National de la Recherche Scientifique, the Université d'Orléans, and the Université de Lyon--presented their findings in a paper that appears early online Nov. 25, 2008, in the Journal of Chemical Physics.
"This is very exciting work", said Tanja Pietraß, the program officer at the National Science Foundation who partially supported this project. "The fact that the researchers did not set out to work on this problem but more or less stumbled upon it and then used their ingenuity to solve it, demonstrates the importance of conducting basic research. In this case, the work may have a major impact on magnetic resonance imaging, positively affecting many peoples' lives."
The key breakthrough is a new understanding of a type of physical process called adiabaticity. Adiabatic processes are what physicists and engineers routinely use to control atoms in nuclear magnetic resonance (NMR) spectroscopy, and its better known sister, MRI.
"An adiabatic process can be visualized as one where a system is 'held tightly'and slowly dragged by a controlling force from one state to the next," said chemist Philip Grandinetti of Ohio State. In MRI, magnetic energy holds the atoms in a patient's body in a steady state while radio waves are the controlling force that drags the atoms from one state to the next. "In a 'perfect' adiabatic process, the controlling force is moved infinitely slowly with the system's trajectory locked to the controlling force's trajectory," said Grandinetti.
Both NMR and MRI exploit a peculiar quantum mechanical property of subatomic particles called "spin". The nuclei of many atoms, most notably hydrogen, spin like tiny tops and possess a magnetic moment like a tiny bar magnet. In NMR and MRI the object under investigation--in medical applications, the patient--is placed inside a strong magnetic field that causes these tiny tops to align with the magnetic field and precess (or wobble, much like a child's top), in the direction of the gravitational field.
For MRI, the strong magnetic field needed for these techniques is generated inside the all too familiar tube that causes many patients claustrophobia, which can require sedation before a procedure. Once inside the magnet, each nucleus broadcasts its identity by emitting radio waves at its unique precession frequency, which depends on its interaction with surrounding atoms as well as the magnetic field strength.
The interaction with surrounding atoms is what makes NMR such a useful tool for chemists and biologists, allowing them to identify different chemical environments and molecular structures.
For MRI, it is the interaction of the nuclei with the magnetic field that is key, as magnetic field strength varies with location, enabling a researcher to code different parts of the body with different frequencies. Through the measurement of the atomic precession frequencies, an MRI radiologist can reconstruct a two-dimensional or three-dimensional image that accurately depicts the interior of a patient's body.
In performing such measurements, scientists often need to invert the nuclei so they are aligned against the magnetic field. Inverting the nuclei of people inside MRI scanners can reveal such things as cancer tumors, whose slightly different interaction with the nuclear spins can be used to detect their presence amid surrounding healthy tissue.
This is where adiabatic processes come into play. The inversions are often done "adiabatically", by subjecting the target to low power radio waves that sweep through a specific range of frequencies. If the sweep is performed slowly enough, then all the nuclei will ultimately be inverted.
"The confounding thing", says Grandinetti, "is that for decades adiabatic sweeps worked in many situations, even though the theory predicted that they should not have. To be fair, it wasn't clear that this discrepancy posed a real problem, and most people thought the conventional theoretical approach was doing a fine job in guiding them towards the optimum adiabatic process. It was only after we fully understood the reason for the discrepancy that we realized the conventional theoretical approach contained a flaw that might prevent the optimum adiabatic process from being discovered".
In the recent paper, Grandinetti and his colleagues solve this long-standing puzzle by introducing the concept of super-adiabaticity into the problem. Super-adiabaticity was first described in 1987 by Sir Michael Berry, a mathematical physicist at University of Bristol. When applied to magnetic resonance, it uncovers hidden behavior in the nuclear inversions that researchers had previously considered unrelated to adiabaticity.
Grandinetti and his colleagues describe a mathematical algorithm that can be used to predict the previously mysterious paths that the nuclei took on their way to the proper target state. This revelation, and the mathematical algorithm for its discovery, are particularly exciting as they open the door to new approaches for designing adiabatic processes in magnetic resonance as well as in other related fields.
One example is in a search for an MRI technique that does not require a patient to enter the confines of a large tube. Researchers are trying to exploit the stray fields of large magnets to do MRI, where the magnetic field is not contained only in the interior of a contraption but is leaking to the outside. The field becomes weaker as one moves further away from the center of the magnet, but researchers have been working on exploiting this natural non-uniformity as an aid to observe internal structures in objects.
"The problem is that these stray fields are highly inhomogeneous in nature, and to make up for this deficiency, researchers must control the dance of the spins in a way that compensates for this," said Grandinetti. "And this is exactly where the more precise control of superadiabaticity may prove to be a revolution in MRI. Who knows--may be a few years from now, you will be casually sitting next to the intimidating device, without the need for sedation?"
National Science Foundation
Collaborators at Ohio State University in Columbus and three institutions in France--the Centre National de la Recherche Scientifique, the Université d'Orléans, and the Université de Lyon--presented their findings in a paper that appears early online Nov. 25, 2008, in the Journal of Chemical Physics.
"This is very exciting work", said Tanja Pietraß, the program officer at the National Science Foundation who partially supported this project. "The fact that the researchers did not set out to work on this problem but more or less stumbled upon it and then used their ingenuity to solve it, demonstrates the importance of conducting basic research. In this case, the work may have a major impact on magnetic resonance imaging, positively affecting many peoples' lives."
The key breakthrough is a new understanding of a type of physical process called adiabaticity. Adiabatic processes are what physicists and engineers routinely use to control atoms in nuclear magnetic resonance (NMR) spectroscopy, and its better known sister, MRI.
"An adiabatic process can be visualized as one where a system is 'held tightly'and slowly dragged by a controlling force from one state to the next," said chemist Philip Grandinetti of Ohio State. In MRI, magnetic energy holds the atoms in a patient's body in a steady state while radio waves are the controlling force that drags the atoms from one state to the next. "In a 'perfect' adiabatic process, the controlling force is moved infinitely slowly with the system's trajectory locked to the controlling force's trajectory," said Grandinetti.
Both NMR and MRI exploit a peculiar quantum mechanical property of subatomic particles called "spin". The nuclei of many atoms, most notably hydrogen, spin like tiny tops and possess a magnetic moment like a tiny bar magnet. In NMR and MRI the object under investigation--in medical applications, the patient--is placed inside a strong magnetic field that causes these tiny tops to align with the magnetic field and precess (or wobble, much like a child's top), in the direction of the gravitational field.
For MRI, the strong magnetic field needed for these techniques is generated inside the all too familiar tube that causes many patients claustrophobia, which can require sedation before a procedure. Once inside the magnet, each nucleus broadcasts its identity by emitting radio waves at its unique precession frequency, which depends on its interaction with surrounding atoms as well as the magnetic field strength.
The interaction with surrounding atoms is what makes NMR such a useful tool for chemists and biologists, allowing them to identify different chemical environments and molecular structures.
For MRI, it is the interaction of the nuclei with the magnetic field that is key, as magnetic field strength varies with location, enabling a researcher to code different parts of the body with different frequencies. Through the measurement of the atomic precession frequencies, an MRI radiologist can reconstruct a two-dimensional or three-dimensional image that accurately depicts the interior of a patient's body.
In performing such measurements, scientists often need to invert the nuclei so they are aligned against the magnetic field. Inverting the nuclei of people inside MRI scanners can reveal such things as cancer tumors, whose slightly different interaction with the nuclear spins can be used to detect their presence amid surrounding healthy tissue.
This is where adiabatic processes come into play. The inversions are often done "adiabatically", by subjecting the target to low power radio waves that sweep through a specific range of frequencies. If the sweep is performed slowly enough, then all the nuclei will ultimately be inverted.
"The confounding thing", says Grandinetti, "is that for decades adiabatic sweeps worked in many situations, even though the theory predicted that they should not have. To be fair, it wasn't clear that this discrepancy posed a real problem, and most people thought the conventional theoretical approach was doing a fine job in guiding them towards the optimum adiabatic process. It was only after we fully understood the reason for the discrepancy that we realized the conventional theoretical approach contained a flaw that might prevent the optimum adiabatic process from being discovered".
In the recent paper, Grandinetti and his colleagues solve this long-standing puzzle by introducing the concept of super-adiabaticity into the problem. Super-adiabaticity was first described in 1987 by Sir Michael Berry, a mathematical physicist at University of Bristol. When applied to magnetic resonance, it uncovers hidden behavior in the nuclear inversions that researchers had previously considered unrelated to adiabaticity.
Grandinetti and his colleagues describe a mathematical algorithm that can be used to predict the previously mysterious paths that the nuclei took on their way to the proper target state. This revelation, and the mathematical algorithm for its discovery, are particularly exciting as they open the door to new approaches for designing adiabatic processes in magnetic resonance as well as in other related fields.
One example is in a search for an MRI technique that does not require a patient to enter the confines of a large tube. Researchers are trying to exploit the stray fields of large magnets to do MRI, where the magnetic field is not contained only in the interior of a contraption but is leaking to the outside. The field becomes weaker as one moves further away from the center of the magnet, but researchers have been working on exploiting this natural non-uniformity as an aid to observe internal structures in objects.
"The problem is that these stray fields are highly inhomogeneous in nature, and to make up for this deficiency, researchers must control the dance of the spins in a way that compensates for this," said Grandinetti. "And this is exactly where the more precise control of superadiabaticity may prove to be a revolution in MRI. Who knows--may be a few years from now, you will be casually sitting next to the intimidating device, without the need for sedation?"
National Science Foundation
Science News and Science Current Events Tag Cloud
This tag cloud is a visual representation of term frequencies of random science news topics with common terms grouped together and emphasized by their display size.
Radiation Therapy Anorexia Abdominal Fat Quarks Smoking Upper Atmosphere Diabetic Retinopathy Pheromones Pesticides Social Behavior Fungus Oxytocin Huntington's disease Hydrogen Storage Algal Blooms Ischemic Stroke Hip Fracture Stroke Patients Periodontal Disease Tropical Disease Gamma-ray Burst Genome Cancer Diagnosis Dialysis HIV
See More: Science News Tags
Magnetic Field Current Events and Magnetic Field News RSSUnexpectedly long-range effects in advanced magnetic devices
A tiny grid pattern has led materials scientists at the National Institute of Standards and Technology (NIST) and the Institute of Solid State Physics in Russia to an unexpected finding-the surprisingly strong and long-range effects of certain electromagnetic nanostructures used in data storage.
Implant bacteria, beware: Researchers create nano-sized assassins
Staphylococcus epidermidis is quite an opportunist. Commonly found on human skin, the bacteria pose little danger. But S. epidermidis is a leading cause of infections in hospitals.
Toxic molecule may help birds 'see' north and south
Researchers at the University of Illinois report that a toxic molecule known to damage cells and cause disease may also play a pivotal role in bird migration.
IBEX spacecraft detects fast neutral hydrogen coming from the moon
NASA's Interstellar Boundary Explorer (IBEX) spacecraft has made the first observations of very fast hydrogen atoms coming from the moon, following decades of speculation and searching for their existence.
Scientists create first comprehensive computer model of sunspots
In a breakthrough that will help scientists unlock mysteries of the sun and its impacts on Earth, scientists have created the first-ever comprehensive computer model of sunspots.
Shape matters in the case of cobalt nanoparticles
Shape is turning out to be a particularly important feature of some commercially important nanoparticles-but in subtle ways.
Giant eruption reveals 'dead' star
An enormous eruption has found its way to Earth after travelling for many thousands of years across space. Studying this blast with ESA's XMM-Newton and Integral space observatories, astronomers have discovered a dead star belonging to a rare group: the magnetars.
European Satellites Probe a New Magnetar
On Aug. 22, 2008, NASA's Swift satellite reported multiple blasts of radiation from a rare object known as a soft gamma repeater, or SGR.
New fabricated material changes color instantly in response to external magnetic field
A research team led by a chemist at the University of California, Riverside has fabricated microscopic polymer beads that change color instantly and reversibly when external magnetic fields acting upon the microspheres change orientation.
Caltech visiting associate champions the study of solar eclipses in the modern era
Championing the modern-day use of solar eclipses to solve a set of modern problems is the goal of a review article written by Jay Pasachoff, visiting associate at the California Institute of Technology (Caltech) and Field Memorial Professor of Astronomy at Williams College.
More Magnetic Field Current Events and Magnetic Field News Articles
 |
69 Love Songs by Magnetic Fields 1999 and first new material in four years by Stephin Merrit 's main band (his side projects include Future Bible Heroes, Gothic Archies and The 6ths). Limited three disc set f eaturing more wonderful, yet cynically skewed, pop songs as only Merritt (and a midi) can do 'em! Features all three volumes of '69 Love Songs' (also sold separately), as well as a76 page booklet only available in this box! Each disc comes in a separate standard jewel case & together they come in a colorful CD-sized slipcase box. 69 tracks. |
 |
Magnetic Field(s) by Ron Loewinsohn (Author) |
 |
The Book Of Love by Merge Records |
 |
Distortion by Magnetic Fields Distortion, Magnetic Fields’ second Nonesuch release, features the brilliant melodies and wry lyrics that composer and band leader Stephin Merritt has long been praised for, but, as the album title suggests, he serves them up with a twist. If the late, great Cole Porter had somehow been resurrected just in time to appear at the Coachella indie-rock fest, the results might sound something like this –"small, ironic tales of love and woe," as National Public Radio has described Merritt’s songs, startlingly enveloped in layers of live feedback that recall the noisy pop provocations of legendary Scottish quartet The Jesus and Mary Chain. As album producer, Merritt takes a completely novel approach to his deployment of feedback, going well beyond mere fuzzed-out guitar to... |
 |
The Charm of the Highway Strip by Magnetic Fields Sweet and sour, incurably romantic, and deeply misanthropic, Magnetic Fields' mastermind Stephin Merritt is a one-of-a-kind voice in modern lo-fi pop. This 1994 outing is a bit of a departure, with Merritt taking his trademark ABBA-styled Casio-pop for a spin in the country--literally. Awash in lush, Nashville-ready production, songs like the doleful "Lonely Highway" (which encompasses snatches of the Lee Hazelwood classic "Jackson") and "Born on a Train" are nothing short of thrilling. But much of this particular stretch of the Fields is lacking in charm, since Merritt's wry stance chafes a bit too hard against the guileless melodies. Completists may feel compelled to take a ride, but novices should probably stick to the more urbane journeys offered by Holiday and Distant Plastic Trees.... |
 |
Magnetic Fields: A Comprehensive Theoretical Treatise for Practical Use by Heinz E. Knoepfel (Author) A unique resource for physicists and engineers working with magnetic fields An understanding of magnetic phenomena is essential for anyone working on the practical application of electromagnetic theory. Magnetic Fields: A Comprehensive Theoretical Treatise for Practical Use provides physicists and engineers with a thorough treatment of the magnetic aspects of classical electromagnetic theory, focusing on key issues and problems arising in the generation and application of magnetic fields. From magnetic potentials and diffusion phenomena to magnetohydrodynamics and properties of matter-topics are carefully selected for their relevance to the theoretical framework as well as current technologies. Outstanding in its organization, clarity, and scope, Magnetic Fields: * Examines... |
|
|
69 Love Songs Volume 1 by Merge Records |
 |
i by Magnetic Fields The long-awaited follow-up to the acclaimed 1999 release 69 Love Songs, i finds singer/songwriter Stephin Merritt in full possession of his acerbic wit. Featuring lyrics ripe with melancholy and bittersweet imagery, the record's fourteen tracks are possibly the most personal Merritt has created to date -- a departure from the many voices on 69 Love Songs. |
 |
Know Your Magnetic Field Book Description: "One of the mainstays of New Thought has been the concept that diseases can be healed using mental abilities inherent in everyone. This short book describes one view of the mechanics of this in simple terms. This is far outside what conventional medicine believes to be effective, and obviously using this as a first resort would be unwise. However, it is today possible to find practicioners of this method, or something similar, in the phone book in most large cities. At the worst, the techniques described here appear to be harmless." (Quote from sacred-texts.com) Table of Contents: Publisher's Preface; Introduction; Mechanics; Nerve Fuel; Heart Energy; Life Energy Control; Spastic Conditions; Stroke; Arthritis; Sleeping Sickness; Fluid Accumulation;... |
 |
Magnetic Fields' 69 Love Songs: A Field Guide (33 1/3) by L. D. Beghtol (Author) This is a fully illustrated oral history of the Magnetic Fields' 1999 triple album, "69 Love Songs" - an album that was afforded "classic" status by many almost as soon as it was released. LD Beghtol's book is chatty, incestuous, funny, dark, digressive, sexy, maddening, and delightful in equal measures. It documents a vital and influential scene from the inside, involving ukuleles and tears, citations and footnotes, analogue drum machines, floods of cognac, and a family tree, and, oh, a crossword puzzle too. The centre of the book is the secret history of these tuneful, acerbic, and sometimes heartbreaking songs of old love, new love, lost love, punk rock love, gay love, straight love, experimental music love, true love, blue love, and the utter lack of love that fill the album - as told... |
| © 2009 BrightSurf.com |