Redundant Input Cancellation by a Bursting Neural Network

Bol, Kieran G.

20 June 2011

One of the most powerful and important applications that the brain accomplishes is solving the sensory "cocktail party problem:" to adaptively suppress extraneous signals in an environment. Theoretical studies suggest that the solution to the problem involves an adaptive filter, which learns to remove the redundant noise. However, neural learning is also in its infancy and there are still many questions about the stability and application of synaptic learning rules for neural computation. In this thesis, the implementation of an adaptive filter in the brain of a weakly electric fish, A. Leptorhynchus, was studied. It was found to require a cerebellar architecture that could supply independent frequency channels of delayed feedback and multiple burst learning rules that could shape this feedback. This unifies two ideas about the function of the cerebellum that were previously separate: the cerebellum as an adaptive filter and as a generator of precise temporal inputs.

neural computation

neural learning

plasticity

adaptive filter

noise cancellation

LIF

neural modeling

neural network

burst learning

neuroscience

neurophysics

weakly electric fish

neural circuits

sensory processing

feedback

spike-timing dependent plasticity

burst induced depression

leaky integrate-and-fire model

stochastic modeling

Redundant Input Cancellation by a Bursting Neural Network

Bol, Kieran G.

20 June 2011

One of the most powerful and important applications that the brain accomplishes is solving the sensory "cocktail party problem:" to adaptively suppress extraneous signals in an environment. Theoretical studies suggest that the solution to the problem involves an adaptive filter, which learns to remove the redundant noise. However, neural learning is also in its infancy and there are still many questions about the stability and application of synaptic learning rules for neural computation. In this thesis, the implementation of an adaptive filter in the brain of a weakly electric fish, A. Leptorhynchus, was studied. It was found to require a cerebellar architecture that could supply independent frequency channels of delayed feedback and multiple burst learning rules that could shape this feedback. This unifies two ideas about the function of the cerebellum that were previously separate: the cerebellum as an adaptive filter and as a generator of precise temporal inputs.

neural computation

neural learning

plasticity

adaptive filter

noise cancellation

LIF

neural modeling

neural network

burst learning

neuroscience

neurophysics

weakly electric fish

neural circuits

sensory processing

feedback

spike-timing dependent plasticity

burst induced depression

leaky integrate-and-fire model

stochastic modeling

Redundant Input Cancellation by a Bursting Neural Network

Bol, Kieran G.

20 June 2011

One of the most powerful and important applications that the brain accomplishes is solving the sensory "cocktail party problem:" to adaptively suppress extraneous signals in an environment. Theoretical studies suggest that the solution to the problem involves an adaptive filter, which learns to remove the redundant noise. However, neural learning is also in its infancy and there are still many questions about the stability and application of synaptic learning rules for neural computation. In this thesis, the implementation of an adaptive filter in the brain of a weakly electric fish, A. Leptorhynchus, was studied. It was found to require a cerebellar architecture that could supply independent frequency channels of delayed feedback and multiple burst learning rules that could shape this feedback. This unifies two ideas about the function of the cerebellum that were previously separate: the cerebellum as an adaptive filter and as a generator of precise temporal inputs.

neural computation

neural learning

plasticity

adaptive filter

noise cancellation

LIF

neural modeling

neural network

burst learning

neuroscience

neurophysics

weakly electric fish

neural circuits

sensory processing

feedback

spike-timing dependent plasticity

burst induced depression

leaky integrate-and-fire model

stochastic modeling

Optogenetic feedback control of neural activity

Newman, Jonathan P.

12 January 2015

Optogenetics is a set of technologies that enable optically triggered gain or loss of function in genetically specified populations of cells. Optogenetic methods have revolutionized experimental neuroscience by allowing precise excitation or inhibition of firing in specified neuronal populations embedded within complex, heterogeneous tissue. Although optogenetic tools have greatly improved our ability manipulate neural activity, they do not offer control of neural firing in the face of ongoing changes in network activity, plasticity, or sensory input. In this thesis, I develop a feedback control technology that automatically adjusts optical stimulation in real-time to precisely control network activity levels. I describe hardware and software tools, modes of optogenetic stimulation, and control algorithms required to achieve robust neural control over timescales ranging from seconds to days. I then demonstrate the scientific utility of these technologies in several experimental contexts. First, I investigate the role of connectivity in shaping the network encoding process using continuously-varying optical stimulation. I show that synaptic connectivity linearizes the neuronal response, verifying previous theoretical predictions. Next, I use long-term optogenetic feedback control to show that reductions in excitatory neurotransmission directly trigger homeostatic increases in synaptic strength. This result opposes a large body of literature on the subject and has significant implications for memory formation and maintenance. The technology presented in this thesis greatly enhances the precision with which optical stimulation can control neural activity, and allows causally related variables within neural circuits to be studied independently.

Neuroscience

Neuroengineering

Optogenetics

Controls

Electrophysiology

Plasticity

Synaptic-scaling

Feedback

Neural computation

Neural control

Real-time feedback

Neuroscience methods

Multichannel electrophysiology

Microelectrode arrays

Firing-rate control

Network-level processing

Neural encoding

Redundant Input Cancellation by a Bursting Neural Network

Bol, Kieran G.

January 2011

One of the most powerful and important applications that the brain accomplishes is solving the sensory "cocktail party problem:" to adaptively suppress extraneous signals in an environment. Theoretical studies suggest that the solution to the problem involves an adaptive filter, which learns to remove the redundant noise. However, neural learning is also in its infancy and there are still many questions about the stability and application of synaptic learning rules for neural computation. In this thesis, the implementation of an adaptive filter in the brain of a weakly electric fish, A. Leptorhynchus, was studied. It was found to require a cerebellar architecture that could supply independent frequency channels of delayed feedback and multiple burst learning rules that could shape this feedback. This unifies two ideas about the function of the cerebellum that were previously separate: the cerebellum as an adaptive filter and as a generator of precise temporal inputs.

neural computation

neural learning

plasticity

adaptive filter

noise cancellation

LIF

neural modeling

neural network

burst learning

neuroscience

neurophysics

weakly electric fish

neural circuits

sensory processing

feedback

spike-timing dependent plasticity

burst induced depression

leaky integrate-and-fire model

stochastic modeling