Overview

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"From Images to Brain Function"

Neurons are the basic computational subunits of the brain. Being single cells, they are of small physical dimension and thus difficult to study. Typical cell body diameters are approximately 10 μm, with dendritic branches on the order of 1 micron or less. However, their small stature is in strong contrast to their computational power. Neurons are complex electrochemical compartments capable of integrating hundreds of thousands of input signals on the millisecond time scale.

In spite of the technical challenges, fully elucidating single neuron function is crucial to understanding the brain. We are developing tools that will enable Neuroscientists to explore single neuron function via sophisticated image analysis. Advanced optical imaging can produce both structural and functional data and is at the forefront of experimentally exploring the fast, small-scale dynamics of living neurons. Further, compartmental modeling of neuronal function enables rapid testing of hypotheses and estimating experimentally inaccessible parameters. Combining these two techniques will afford unprecedented capabilities in the study of single neuron function. Our software utility bridges the two Neuroscience techniques by rapidly, accurately, and robustly generating from structural image data a cylindrical morphology model suitable for simulating neuronal function.

Motivation

One can reasonably argue that the brain is the most complex system known to man. The mammalian brain is composed of 100 billion cells, with up to 100,000 intracellular connections between each of those cells. This high interconnectivity supports complex interactions between each of these subunits to form sophisticated processing networks. The ensemble network activity gives rise to the familiar behavioral results of the higher organisms: sensory responses, motor activity, and, in humans, cognition. Further underscoring the great need for increasing our knowledge of brain function is the potential for medical advances: successfully treating cognitive dysfunction, injury, and neural diseases would have a substantial societal impact.

The very complexity that allows these high-level capabilities also makes the brain difficult to study and understand. It is therefore necessary to take a more focused approach. The basic subunit of the brain is the single cell, called a "neuron." Neurons are unique from other cells in that they possess branching processes called "dendrites," conduct electrochemical impulses, and have dynamic sensitivity.

It is also important to note that neurons are extremely heterogeneous. Throughout the nervous system, one observes a wide range of dendritic morphologies (Figure 1) in addition to a wide range of electrical behavior. This heterogenity in both features suggests a structure-function relationship.

Goal

The goal of this project is to develop a computational and experimental framework to allow real-time mapping of functional imaging data (e.g., spatio-temporal patterns of dendritic voltages or intracellularions) to neuronal structure, during the very limited duration of an acute experiment.

Objectives

• To develop the theoretical and computational framework for accurate and robust morphological reconstruction of living, fluorescently-labeled dendrites from optical serial sectioning data.
• To constrain a compartmental neuron model with data from the reconstructed morphology.
• To use the simulation results in combination with the functional imaging data to increase our understanding of single-neuron computation.

The current state-of-the-art for translating structural images of neurons to cylinder models requires laborious manual dendrite tracing by a human. This tedious process takes many hours for typical morphology complexity and suffers from:
1. An inability to reconstruct live neurons under experimental investigation
2. Tissue fixation problems
3. Imaging resolution limitations
4. Operator subjectivity.

These drawbacks are problematic for two reasons. First, the reconstruction results--and thus the simulation results--are not available at the time of the experiment, eliminating the possibility of tight integration of experiments and simulations. Second, the accuracy of simulation results is dependent on the fidelity of the reconstructed morphology to the real neuron: the physical dimensions of the neuron dictate the cable properties assigned to the model.

We address these problems by avoiding them altogether. Our software suite generates cylinder models from 3D fluorescence images. This has the advantages that the output cylinder model is rapidly-done, accurate, and robust.
1. Rapid: minimal to no human intervention; doesn't require tissue fixation
2. Accurate: algorithms are objective, relative to human subjectivity; uses high-resolution fluorescence data
3. Robust: algorithms are objective, relative to human subjectivity

With the accurate morphological model in hand, we can integrate multi-site functional imaging results and model simulation results to increase our understanding of single neuron function.

Technical Challenges & Solutions

Studying single neuron function with imaging methods requires high optical resolution (<1 μm) and high speed (acquisition rates >1kHz). With commercially-available imaging systems one encounters a speed-resolution tradeoff between high speed/low resolution or high resolution/low speed. To eliminate this problem, we are concurrently developing a high-speed, multi-photon laser-scanning microscope. Multi-photon laser has the useful characteristics that its long excitation wavelength results in low light-scattering (improving depth-penetration) and also provides intrinsic optical sectioning. Both of these characteristics enable resolving neuronal structures down to the micron level. The fast laser scanner, based on the acousto-optic deflection principle, allows the precise direction of the multi-photon laser beam to user-selected, non-contiguous sites at rates of up to 60 kHz.