XML Feed for RxPG News   Add RxPG News Headlines to My Yahoo!   Javascript Syndication for RxPG News

Research Health World General
 
  Home
 
 Latest Research
 Cancer
 Psychiatry
 Genetics
 Surgery
 Aging
 Ophthalmology
 Gynaecology
 Neurosciences
  Memory
   Intelligence
  Regeneration
  Stroke
  Brain Diseases
  Headache
  Spinal Cord Diseases
  Demyelinating Diseases
  Neurodegenerative Diseases
  Taste
  Trigeminal Neuralgia
 Pharmacology
 Cardiology
 Obstetrics
 Infectious Diseases
 Respiratory Medicine
 Pathology
 Endocrinology
 Immunology
 Nephrology
 Gastroenterology
 Biotechnology
 Radiology
 Dermatology
 Microbiology
 Haematology
 Dental
 ENT
 Environment
 Embryology
 Orthopedics
 Metabolism
 Anaethesia
 Paediatrics
 Public Health
 Urology
 Musculoskeletal
 Clinical Trials
 Physiology
 Biochemistry
 Cytology
 Traumatology
 Rheumatology
 
 Medical News
 Health
 Opinion
 Healthcare
 Professionals
 Launch
 Awards & Prizes
 
 Careers
 Medical
 Nursing
 Dental
 
 Special Topics
 Euthanasia
 Ethics
 Evolution
 Odd Medical News
 Feature
 
 World News
 Tsunami
 Epidemics
 Climate
 Business
Search

Last Updated: Aug 19th, 2006 - 22:18:38

Intelligence Channel
subscribe to Intelligence newsletter

Latest Research : Neurosciences : Memory : Intelligence

   DISCUSS   |   EMAIL   |   PRINT
Short term synaptic plasticity play a widespread role in information processing
Jun 23, 2006, 00:33, Reviewed by: Dr. Priya Saxena

Short-term plasticity may provide the mechanism by which animals' quickly changing brains help them navigate and comprehend the world.

 
Animals' neurons, and the synapses that connect them, are constantly changing. This plasticity is thought to underlie learning and memory. Take the rat in the maze. As he learns to navigate a new environment, familiarity with the space is reflected in the neuronal activity of a small almond-shaped brain structure called the hippocampus. Neurons in the hippocampus are generally quiescent. But when the rat meanders into a spot that a specific neuron prefers, called its �place field,� the neuron responds with high-frequency bursts of spikes. As the rat's familiarity with the maze increases over only a few minutes, so does the reliability by which hippocampal neurons respond to their preferred place. This short-term experience modifies the neurons' responses, and very likely the synapses, although the synaptic mechanisms of short-term plasticity in this context have not been fully described.

A new study takes a step forward in understanding the most basic level of this process: the short-term plasticity at hippocampal synapses that result from processing incoming signals resembling place-field responses. The researchers, Vitaly Klyachko and Charles Stevens, discovered a novel short-term plasticity mechanism by which excitatory and inhibitory synapses can selectively amplify high-frequency bursts.

For the study, the researchers used slices of the rat's hippocampus, focusing on cells from two particular regions, called CA1 and CA3, known for their role in encoding information about the animal's position. The researchers recorded long series of this firing activity, which they then used to stimulate two classes of hippocampal neurons: excitatory neurons, whose function is to spur neurons downstream to fire; and inhibitory neurons, which suppress neurons downstream.

In the hippocampus, these neurons form basic circuit elements, among which a �feed-forward loop� is one of the most common. In its simplest form, these loops feature an excitatory neuron connected to both an inhibitory neuron and an output neuron, and the inhibitory neuron is also connected to the output neuron. In this simple triangular network, incoming signals trigger both the excitatory and inhibitory neurons at once, and then the inhibitory neuron activates its synapses with a delay of a few milliseconds. From the output neuron's point of view, the incoming excitatory signals are closely followed by the inhibitory ones.

Several previous studies that tried to sort out how these neurons function during processing of incoming signals that resemble natural activity failed to produce coherent outputs from the neurons. These incoherent outputs may have resulted from the fact that the neurons were held at room temperature; as Klyachko and Stevens had shown before, short-term plasticity works differently at room temperature than at body temperature. To avoid the temperature problem in this study, Klyachko and Stevens held the brain slices at near body temperature.

With short-term plasticity, a synapse's response to any one signal depends on the signals it received in the previous few seconds. Synapses can sense when they're receiving a high number of impulses per second�that is, a high-frequency signal. Klyachko and Stevens found that, as long as the incoming signal was above a certain average rate, around 10 Hz, then the synapses would flip from a baseline state to an �active� state. The excitatory synapses became more excitatory, amplifying incoming signals. The inhibitory synapses responded oppositely, damping down their activity. Surprisingly, for any signals with higher frequency, these synapses' responses stayed constant even when the incoming signal rose to much higher frequencies, such as 100 Hz. The researchers also found that the excitatory and inhibitory synapses had mirror-image responses: when the excitatory synapses amplified a specific portion of a signal, the inhibitory synapses damped down their response at the same time.

When these two types of cells are wired together in a feed-forward loop, the researchers found that the excitatory and inhibitory synapses acted in concert, filtering out low-frequency signals while amplifying high-frequency signals. Thus, the study shows a function for the hippocampus's feed-forward loops not seen in earlier studies. It also shows a new role for inhibitory synapses: amplifying signals.

In this study, hippocampal neurons used short-term plasticity to filter neuronal signals for high-frequency events that encode important information for the animal. As the authors argue, this plasticity could also play a widespread role in information processing in the brain. Short-term plasticity may provide the mechanism by which animals' quickly changing brains help them navigate and comprehend the world.
 

- Inman M (2006) Neurons' Short-Term Plasticity Amplifies Signals. PLoS Biol 4(7): e240
 

Read Research Article

 
Subscribe to Intelligence Newsletter
E-mail Address:

 

Written by Mason Inman

DOI: 10.1371/journal.pbio.0040240

Published: June 20, 2006

Copyright: � 2006 Public Library of Science. This is an open-access article distributed under the terms of the Creative Commons Attribution License.

PLoS Biology is an open-access journal published by the nonprofit organization Public Library of Science.


Related Intelligence News

Music thought to enhance intelligence
Short term synaptic plasticity play a widespread role in information processing
Brain Rewards Curiosity with Shot of Natural Opiates
Dysbindin-1 gene (DTNBP1) - The Intelligence Gene
Brains of the smarter kids tend to change more dramatically
Brain size matters for intellectual ability


For any corrections of factual information, to contact the editors or to send any medical news or health news press releases, use feedback form

Top of Page

 

© Copyright 2004 onwards by RxPG Medical Solutions Private Limited
Contact Us