 |
|
Overbearing colored light may reveal a second mechanism by which birds interpret magnetic signals
August 23, 2005Magnetic orientation is critical to the migratory success of many bird species. By studying the influence of light on the ability of migratory birds to orient to magnetic signals, researchers have found clues to suggest that birds' orientation abilities may be more complex than previously thought and that birds may be able to interpret magnetic signals by more than one mechanism. The work is reported in Current Biology by a team including Thorsten Ritz, of the University of California, Irvine, and Wolfgang and Roswitha Wiltschko, of the University of Frankfurt, Germany.
It has been known for many years that birds possess a magnetic "inclination compass," which essentially allows birds to obtain directional information from the magnetic field by interpreting the angle of magnetic-field lines with regard to the horizon rather than by interpreting the magnetic field's polarity. Previous work by Dr. Ritz had suggested that in interpreting magnetic signals, birds employed a so-called chemical compass that worked by way of chemical reactions in specialized photopigments in their eyes. The chemical-compass idea implied that magnetoreception was light dependent, and this possibility was subsequently given support by work from the Wiltschko team showing that the orientation of European robins, a night-migrating species, was influenced by the intensity of light in the blue-green spectrum.
In the present study, the Ritz and Wiltschko groups teamed up to analyze the orientation behavior under turquoise light in detail and revealed an unexpected phenomenon: Increasing the intensity of turquoise light changes the birds' orientation significantly, in comparison to dimmer light levels. The researchers found that in dim turquoise light, similar to that found about 33 minutes after sunset, the birds show normal migratory orientation, with the seasonal shift between southerly directions in autumn and northerly directions in spring. Tests under specific magnetic conditions clearly showed that this orientation involved the inclination compass and suggested that it is based on the type of "chemical compass" processes predicted by the Ritz model.
However, the researchers also found that under brighter turquoise light, corresponding to light levels found 20 min after sunset, the birds still orient by the magnetic field, but they no longer show the seasonal change between spring and autumn and instead head north in both seasons. This behavior did not appear to involve the normal inclination-compass and chemical-compass mechanisms.
The new findings show that bright-colored light interferes with magnetoreception such that migratory birds can no longer obtain the information required to head into their migratory direction. The findings point to the existence of two distinct mechanisms of mechanoreception in the birds-an inclination compass and a polarity-driven compass. It is especially intriguing that under some conditions, birds appear to switch to the polarity-type magnetic response, which is based on a mechanism of a very different nature than that thought to contribute to the inclination mechanism.
Cell Press
However, the researchers also found that under brighter turquoise light, corresponding to light levels found 20 min after sunset, the birds still orient by the magnetic field, but they no longer show the seasonal change between spring and autumn and instead head north in both seasons. This behavior did not appear to involve the normal inclination-compass and chemical-compass mechanisms.
The new findings show that bright-colored light interferes with magnetoreception such that migratory birds can no longer obtain the information required to head into their migratory direction. The findings point to the existence of two distinct mechanisms of mechanoreception in the birds-an inclination compass and a polarity-driven compass. It is especially intriguing that under some conditions, birds appear to switch to the polarity-type magnetic response, which is based on a mechanism of a very different nature than that thought to contribute to the inclination mechanism.
Cell Press
Magnetic Signals Current Events and Magnetic Signals News RSSBrain's magnetic fields reveal language delays in autism
Faint magnetic signals from brain activity in children with autism show that those children process sound and language differently from non-autistic children.
UD researchers show that plants can accumulate nanoparticles in tissues
Researchers at the University of Delaware have provided what is believed to be the first experimental evidence that plants can take up nanoparticles and accumulate them in their tissues.
Zooming way in, technique offers close-ups of electrons, nuclei
Providing a glimpse into the infinitesimal, physicists have found a novel way of spying on some of the universe's tiniest building blocks.
3-D imaging -- first insights into magnetic fields
3-D images are not only useful in medicine; the observation of internal structures is also invaluable in many other fields of scientific investigation.
'NMR on a chip' features NIST magnetic mini-sensor
A super-sensitive mini-sensor developed at the National Institute of Standards and Technology (NIST) can detect nuclear magnetic resonance (NMR) in tiny samples of fluids flowing through a novel microchip.
New imaging technique reveals fatty hearts
A simple imaging technique developed by UT Southwestern Medical Center researchers has revealed fat buildup in the hearts of pre-diabetic people long before symptoms of heart disease or diabetes appear.
Wireless sensor networks offer high-tech assurance for a world wary of earthquakes
An earthquake strikes a large city, wrecking roads and bridges, stranding rush-hour commuters, trapping office workers inside high-rise buildings.
Earth's magnetic field really did reverse itself
NWO researchers have developed an improved method of identifying the magnetic signals in old geological strata. The researchers used the new method to show that the earth's magnetic field really did reverse itself ten million years ago. Particles of iron in sediments orient themselves in accordance with the local magnetic field of the earth. As the sediment consolidates and lithifies over the course of several decades, the particles of iron continue to lie in the direction of the original magnetic field. They thus preserve data on the state of the magnetic field when the sediment was being deposited. These data are used world-wide to date geological strata. The researchers developed a method
More Magnetic Signals Current Events and Magnetic Signals News Articles
 | Principles of Magnetic Resonance Imaging: A Signal Processing Perspective by Zhi-Pei Liang, Paul C. Lauterbur "In 1971 Dr. Paul C. Lauterbur pioneered spatial information encoding principles that made image formation possible by using magnetic resonance signals. Now Lauterbur, ""father of the MRI,"" and Dr. Zhi-Pei Liang have co-authored the first engineering textbook on magnetic resonance imaging. This long-awaited, definitive text will help undergraduate and graduate students of biomedical engineering,... |
 | Signal Processing for Magnetic Resonance Imaging and Spectroscopy (Signal Processing and Communications Series, 15) This reference/text contains the latest signal processing techniques in magnetic resonance imaging (MRI) and magnetic resonance spectroscopy (MRS) for more efficient clinical diagnoses-providing ready-to-use algorithms for image segmentation and analysis, reconstruction and visualization, and removal of distortions and artifacts for increased detection of disease. Detailing cost-effective... |
 | Advanced Image Processing in Magnetic Resonance Imaging (Signal Processing and Communications) The popularity of magnetic resonance (MR) imaging in medicine is no mystery: it is non-invasive, it produces high quality structural and functional image data, and it is very versatile and flexible. Research into MR technology is advancing at a blistering pace, and modern engineers must keep up with the latest developments. This is only possible with a firm grounding in the basic principles of... |
| Methods of Analysis of Brain Electrical and Magnetic Signals (Handbook of Electroencephalography and Clinical Neurophysiology, Rev Series) by A. S. Gevins | |
 | Coding and Signal Processing for Magnetic Recording Systems The last decade has seen an exponential growth in the number of Internet users, and networks rely on high performance storage devices for server and database applications. This handbook reviews advanced signal processing, modulation, coding techniques, and architectures for recording read channels. It is divided into four major areas that cover theoretical background, state-of-the-art read... |
| Handbook of Electroencephalography and Clinical Neurophysiology, Revised Series, Volume 1: Methods of Analysis of Brain Electrical and Magnetic Signals Since its inception in the 1930s, clinical electroencephalography has continued to be an indispensible diagnostic tool in the study of epilepsy. The past fifteen years have seen an explosion of knowledge in the basic neurosciences, paralleled by the development of sophisticated diagnostic tools for, and innovative therapeutic approaches to, the clinical problem of epilepsy. These include wider... | |
| Two-Dimensional Signal Processing For Magnetic Storage Syustems by Paul A. Voois | |
| Signal Processing in Magnetic Resonance Spectroscopy With Biomedical Applications by Dzevad Belkic | |
| Effects of line pressure stress, magnetic properties and test conditions on magnetic flux leakage signals: Annual report (May 1995-April 1996) by D. L Atherton | |
| Effect of crystallographical and geometrical changes of a ferrite head on magnetic signals during the sliding process with magnetic tape (SuDoc NAS 1.15:87277) by Kazuhisa Miyoshi |
| © 2008 BrightSurf.com |