In addition to information from sensory receptors, the ELL receives a signal from the area of the brain responsible for initiating the electrical discharges, known as the EOD command nucleus. This efference copy diverges, transmitted through two separate pathways before the signals converge, along with electrosensory input, on Purkinje-like Medium Ganglion cells in the ELL. These cells receive information through extensive apical dendritic projections from parallel fibers that signal the transmission of an order to release an EOD. These cells also receive information from neurons conveying electrosensory information.
Important to anti-Hebbian learning, the synapses between the parallel fibers and the apical dendrites of Medium Ganglion cells show a specific pattern of synaptic plasticity. Should activation of the dendrites by parallel fibers occur in a short time period preceding the initiation of a dendritic broad spike (an action potential which travels through the dendrites), the strength of the connection between the neurons at these synapses will be reduced. Activation by the parallel fibers in all other circumstances – including activation significantly preceding as well as any activation following the broad spike – will result in the strengthening of the synaptic connections
Since the neurons of the ELL receive both a corollary discharge (another term for an efference copy) of the motor output commands sent to the EOD, and afferent input from the electrosensory receptors, the animal is able to eliminate predictable inputs produced by its own motor output. The system is able to filter the expected input from the EOD, while signals which are unexpected, arriving at odd intervals with regard to the motor command are effectively strengthened by the learning rule. This allows the extraction of information about objects which cause an alteration in the flow of the electric field around the fish, highlighting changes while discarding uninformative sensory inputs.
The adaptation of these synapses, though, will only increase the strength of a synaptic connection until the resulting excitation aids in activation of a broad-spike wave. As a result, if changes in external environment are consistent, the connections between the neurons previously described will reach a level of at which excitation, similar to the initial state, is once again held at a threshold, so that slight changes in the incoming sensory information will result in contribution to broad-spike initiation. In this manner, the organism is able to learn to ignore redundant sensory information in the environment. The eventual desensitization to these consistencies is essential to prevent excessive noise from masking important sensory information. Numerous potential causes which could result in a consistent alteration in the reception of EOD signals include: growth, changes in water conductance (salinity), low water levels (where the shallow bottom of the body of water would interfere with electrical currents), and possibly injuries.
Synaptic plasticity operating under the control of an anti-Hebbian learning rule is thought to occur in the cerebellum. Understanding the operation of neural learning could provide valuable insights for the treatment of cerebellar-related disorders. The knowledge could also serve a significant function in the computer-based collection of data, repeatedly adjusting to redundant inputs while emphasizing the appearance of alterations.
Recent Findings from University of Southern California, Department of Biomedical Engineering Highlight Research in Signature Recognition.
Mar 15, 2011; Researchers detail in 'Noise-robust acoustic signature recognition using nonlinear Hebbian learning,' new data in Signature...