Neural Circuits For Active Vision In The Primate Cerebral Cortex
Funder
National Health and Medical Research Council
Funding Amount
$632,938.00
Summary
This project will try to understand how we use visual information to identify objects by their shape and motion, in natural situations in which the eyes are moving all the time. This will be accomplished by recording the electrical activity of brain cells while a trained animal is performing different types of tasks, such as tracking a moving object or exploring a scene with its eyes.
How Are Axons Guided To Their Targets In The Developing Nervous System?
Funder
National Health and Medical Research Council
Funding Amount
$329,644.00
Summary
Many neurodevelopmental disorders are probably the result of wiring defects. In this project we will use new technologies to study how growing nerve fibres are steered to their targets during development, and use this data to create new mathematical models which can predict which way nerve fibres should grow in different situations. This will advance our understanding of the mechanisms underlying both normal and abnormal brain development.
Combining Timelapse Imaging And Computational Modelling To Understand The Mechanisms Of Axon Guidance In The Developing Retinotectal System
Funder
National Health and Medical Research Council
Funding Amount
$438,793.00
Summary
Understanding how patterns of brain wiring develop is crucial for understanding many cognitive disorders. One of the commonest types of connection pattern in the brain is a topographic map, where nearby neurons in one structure connect to nearby neurons in another structure. Using the transgenic tools available in the zebrafish as a model system, we will combine novel experiments with computational modelling to understand the rules which govern the formation of topographic maps in the brain.
Neuronal Linking Of Attention, Perception And Action
Funder
National Health and Medical Research Council
Funding Amount
$586,469.00
Summary
We are able to perceive and interact with the environment around us primarily because a filter of attention selects just the objects or features of relevance in the world and helps to make appropriate motor responses. This project will study how attentional networks of the brain operate to link our perception and action. An understanding of this process is fundamental to revealing the underlying pathology in many neurological conditions where attention is impaired.
Neural Circuits For Residual Vision After Damage To Striate Cortex
Funder
National Health and Medical Research Council
Funding Amount
$662,220.00
Summary
Brain cells have the ability to rearrange their connections to create alternate pathways, which compensate for loss of function following brain damage. To understand why some people become blind after damage to the visual cortex, and some don't, we will determine how neural connections change following lesions in different stages of life. The project will provide important information that may allow future development of treatments for blindness due to stroke or traumatic brain injury.
Normal And Abnormal Development Of Brain Wiring And Its Impact On Brain Function
Funder
National Health and Medical Research Council
Funding Amount
$763,845.00
Summary
My laboratory is striving to understand how the patterns of neuronal connections form in the developing brain and how these underpin the functions of the brain throughout life. We use high-field magnetic resonance imaging to measure brain wiring and we investigate the genetic and environmental mechanisms causing developmental brain disorders that result in intellectual disability, autism, epilepsy and some mental illnesses.
Molecular And Activity Dependent Mechanisms Regulating The Targeting Of Corpus Callosum Axons In The Contralateral Hemisphere.
Funder
National Health and Medical Research Council
Funding Amount
$413,266.00
Summary
The brain is made up of circuits of neurons that process specific information. For example, the somatosensory cortex receives and sends connections to other somatosensory areas, including the contralateral cortex, but how these systems are wired up is not known. We will investigate whether information about the size and position of the cortical areas and activity-matching of the somatosensory information received by each hemisphere are used to guide callosal axons to their targets.
Knowledge, Identification And Exploitation Of Dopaminergic Axon Guidance Cues Will Improve Cell Replacement Therapy For ParkinsonÍs Disease.
Funder
National Health and Medical Research Council
Funding Amount
$481,797.00
Summary
Many obstacles exist for cell transplantation in ParkinsonÍs Disease; namely poor graft survival, restoration of appropriate circuitry and adequate nerve fiber growth from new cells. Using knowledge of how neural circuits are established during fetal development, we will attempt to recapitulate these events following transplantation. Further, we will identify new and novel cues in regulating the connectivity and growth of these nerve fibers.
Computational Analysis Of The Influence Of Growth Cone Shape Dynamics On Axon Guidance
Funder
National Health and Medical Research Council
Funding Amount
$346,406.00
Summary
For the brain to function correctly its neurons must be connected correctly. This project will use a novel mathematical approach to understand how growing nerve fibres find where to go in the developing brain. In particular we will use both experiments and computational analysis to understand how the shape of the tip of a growing nerve fibre helps the fibre navigate. This may help us understand the biological cause of many different types of mental disorders.