Scientists get closer to understanding how brain’s ‘hearing center’ works
October 19th, 2010 - 5:50 pm ICT by ANIWashington, Oct 19 (ANI): Scientists have taken a step closer in unravelling the mystery-how our aural world is based on the frequencies of sounds.
A team of scientists led by Anthony Zador of the Cold Spring Harbor Laboratory (CSHL) probed how the functional connectivity among neurons within the auditory cortex gives rise to a ‘map’ of acoustic space.
“What we learned from this approach has put us in a position to investigate and understand how sound responsiveness arises from the underlying circuitry of the auditory cortex,” Zador said.
Neuronal organization within the auditory cortex fundamentally differs from the organization within brain regions that process sensory inputs such as sight and sensation.
In the auditory system, the organization of sound receptors in the cochlea - the snail-like structure in the ear - is one-dimensional. Cochlear receptors near the outer edge recognize low-frequency sounds whereas those whereas those near the inside of the cochlea are tuned to higher frequencies.
“Because sound is intrinsically a one-dimensional signal, unlike signals for other senses such as sight and sensation which are intrinsically two-dimensional, the map of sound in the auditory cortex is also intrinsically one-dimensional,” explained Zador.
Hysell Oviedo compared neuronal activity in mouse brain slices that were cut to preserve the connectivity along the tonotopic axis vs. activity in slices that were cut perpendicular to it.
To precisely stimulate a single neuron within a slice and record from it, scientists used a powerful tool called laser-scanning photostimulation.
“If you did this experiment in the visual cortex, you would see that the connectivity is the same regardless of which way you cut the slice.
“But in our experiments in the auditory cortex slices, we found that there was a qualitative difference in the connectivity between slices cut along the tonotopic axis vs. those cut perpendicular to it,” said Oviedo.
Analogously, in the auditory cortex, neurons within a column get tuned to the same frequency.
“It comes from neurons that we think are tuned to higher frequencies. This is the first example of the neuronal organizing principle not following the columnar pattern, but rather an out-of-column pattern,” elaborated Zador.
The findings appeared in the journal Nature Neuroscience. (ANI)
- Neural mechanism of how music originated in the brain revealed - Oct 21, 2009
- Nerve stimulation may thwart tinnitus: Study - Jan 13, 2011
- Inner ear can 'store' recent sounds: Study - Apr 06, 2011
- Imaging techniques reveal new picture of sound processing - Feb 02, 2010
- How brain hears the sound of silence - Feb 11, 2010
- Nasal stem cells could tackle childhood hearing problems - Feb 10, 2011
- Brain wiring lets us differentiate our speech from that of others' - Dec 10, 2010
- How does brain catch up with sound of silence? - Feb 11, 2010
- Technique 'poised to untangle brain's complexity' developed - Apr 11, 2011
- How does brain hear quietest sounds, notice head motions? - Feb 15, 2010
- Why babies' brains are flexible - Jun 23, 2010
- Brain circuits behind hearing develop without sensory experience - Jun 20, 2010
- How mums' brains screen for baby calls - Jun 11, 2009
- New clues on how normal and cancerous cells migrate within the body - Apr 25, 2011
- Our brains much more similar to birds' than we thought - Jul 03, 2010
Tags: acoustic space, auditory cortex, auditory system, aural world, brain regions, brain slices, cold spring harbor, cold spring harbor laboratory, cshl, dimensional signal, functional connectivity, hearing center, hysell, mouse brain, neuronal activity, qualitative difference, sensory inputs, spring harbor laboratory, visual cortex, zador