It is well established that, following adaptation, cells adjust their sensitivity to
reflect the global stimulus conditions. Two recent studies in guinea pig inferior colliculus
(IC, Dean, Harper & McAlpine 2005) and rat barrel cortex (Garcia-Lazaro, Ho, Nair &
Schnupp 2007) found that neural stimulus-response functions were displaced laterally in a
manner that was dependent on the mean adapting stimulus. However, the direction of gain
change, following adaptation to variance, was in contradiction to Information Theory,
which predicts a decrease in gain with increased stimulus variance.
On further analysis of the experimental data, presented within this thesis, it was
revealed that the adaptive gain changes to global stimulus variance were, in fact, in the
direction predicted by Information Theory. However, following adaptation to global mean
amplitude, neural threshold was displaced to centre the SRF on inputs that were located on
the edge of the stimulus distribution. It was found that adaptation scaled neural output such
that the relationship between firing rate and local, as opposed to global, differences in
stimulus amplitude was maintained; with the majority of cells responding to large
differences in stimulus amplitude, on the 40ms scale. A small majority of cells responded
to step-size differences, in amplitude, of either direction and were classed as novelty
preferring.
Adaptation to global mean was replicated in model neuron with spike-rate
adaptation and tonic inhibition, which increased with stimulus mean. Adaptation to
stimulus variance was replicated in three models 1: By increasing, in proportion to stimulus
variance, background, excitatory and inhibitory firing rates in a balanced manner (Chance,
Abbott & Reyes 2002), 2: A model of asymmetric synaptic depression (Chelaru & Dragoi
2008) and 3: a model combining non-linear input with synaptic depression.
The results presented, within this thesis, demonstrate that neurons change their
coding strategies depending upon the global levels of mean and variance within the sensory
input. Under low noise conditions, neurons act as deviation detectors, i.e. are primed to
respond to large changes in the stimulus on the tens of millisecond; however, under
conditions of increased noise switch their encoding strategy in order to compute the full
range of the stimulus distribution through adjusting neural gain.
Date of Award | 2011 |
---|
Original language | English |
---|
Awarding Institution | |
---|
Supervisor | Susan Denham (Other Supervisor) |
---|
- Computational Neuroscience
- Barrel cortex
- Information Theory
- Synaptic Depression
- Sensory Adaptation
Encoding strategies and mechanisms underpinning adaptation to stimulus statistics in the rat barrel cortex
Davies, L. A. (Author). 2011
Student thesis: PhD