A Novel Treatment For Ischemic Stroke: Preclinical Assessment In The Nonhuman Primate
Funder
National Health and Medical Research Council
Funding Amount
$762,246.00
Summary
A major source of repair inhibition after brain injury is debris from dying cells, which contains proteins that hinder repair. This project will examine the expression of these proteins in a clinically-relevant model of ischemic stroke and determine if blocking the effect of these proteins neutralises their repair-inhibiting properties. If successful, there is likelihood that this drug, and method of delivery, could be translated into the human for treatment following an ischemic stroke.
Associate Professor Bourne’s research will involve learning how the infant brain has an enhanced capacity to repair its own neocortex following an injury and to translate these findings into the development of brain regenerative therapies.
Visuomotor Integration In The Medial Parietal Cortical Areas
Funder
National Health and Medical Research Council
Funding Amount
$665,163.00
Summary
This project will find out how the electrical activity of brain cells is used to direct the arms to a specific position in the space around a person's body. By understanding the code used by brain cells to perform this control of the arms, we will be able to "read" the brain activity directly, and use it to allow control of artificial arms by people who have been paralysed or had amputations.
Functional Neurogenesis In The Injured Neocortex Of The Nonhuman Primate
Funder
National Health and Medical Research Council
Funding Amount
$966,048.00
Summary
Research over the past couple of decades has revolutionised our understanding of the capacity of the brain to generate new cells, especially following an injury. However, what does remain controversial is whether this phenomenon occurs in all areas of the brain, especially following a severe traumatic brain injury or stroke. This project will examine whether the outer surface of the brain has the potential to generate new cells following a brain injury and whether they become functional.
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.
Understanding The Role Of Caudal Auditory Belt Areas In Perception Of Complex Sounds
Funder
National Health and Medical Research Council
Funding Amount
$773,518.00
Summary
Although the auditory cortex is key to our understanding of several neurological conditions, including language impairments, the functions of many of its areas are still unknown. Using an animal model, we will examine the roles of different auditory areas in separating important sounds from noise. This is a critical role in coordinating our body’s responses to acoustic stimuli. This study will help clarify how these areas contribute to how we normally process sounds, and what deficits are likely ....Although the auditory cortex is key to our understanding of several neurological conditions, including language impairments, the functions of many of its areas are still unknown. Using an animal model, we will examine the roles of different auditory areas in separating important sounds from noise. This is a critical role in coordinating our body’s responses to acoustic stimuli. This study will help clarify how these areas contribute to how we normally process sounds, and what deficits are likely to occur if they are damaged.Read moreRead less
Molecular And Cellular Changes Following A Cortical Injury: What Role Do They Play In Regeneration?
Funder
National Health and Medical Research Council
Funding Amount
$499,625.00
Summary
Damage to the visual areas of the brain is common after, for example stroke, neurotrauma or hypoxia. The injury often manifests in the form of a scar caused by a specific type of brain cell (astrocyte). This scar acts as a barrier to the cells which transmit information (neurones), preventing re-establishment of connectivity, thus functional recovery. We will see if we can reduce this scar and enhance re-connectivity after injury by blocking some of the molecules that brain cells express.
Developmental Plasticity In The Nonhuman Primate Visual Cortex
Funder
National Health and Medical Research Council
Funding Amount
$464,417.00
Summary
A phenomenon that has puzzled many for a number of years is why damage to the visual brain during infancy has far less of an impact on visual capacity than the same lesion suffered later in life. This project hopes to uncover this mystery and see how brain 'wiring' is altered to compensate.