Control Of Prosthetic Limbs From Decoded Brain Signals
Funder
National Health and Medical Research Council
Funding Amount
$895,832.00
Summary
This research will restore mobility to patients who suffer from paralysis. We aim to create a device, known as a brain-machine interface, which is an artificial communication path from the brain that bypasses an injury, such as a damaged spinal cord or stroke. The interface will decode a user’s intent and act upon it. Decoders will use physiological principals and state-of-the-art machine learning methods. We will test a user’s ability to control an artificial limb using decoded brain activity.
Preclinical Validation Of First In Man Endovascular Brain Machine Interface Device
Funder
National Health and Medical Research Council
Funding Amount
$870,000.00
Summary
The stentrode technology has been given significant public attention, following publication in the fourth highest impact factor journal 'Nature Biotechnology' and a public statement of endorsement by the President of the United States in 2016. The program now seeks to conduct a preclinical validation program to satisfy the FDA in its requirements to provide Investigational Device Exemption (IDE).
Roles Of Peripherally Derived BDNF In Regeneration Of Spinal Cord And The Mechanisms
Funder
National Health and Medical Research Council
Funding Amount
$472,770.00
Summary
Injury to the brain and spinal cord often leads to permanent disability due to lack of regeneration. The mechanism why central nerve does not regenerate is not known. Neurotrophic factors are powerful molecules which can overcome effects of inhibitory factors on regeneration. This project aims to investigate how neurotrophic factors override the effects of inhibitory factors and how to improve the regeneration by increasing the production of neurotrophic factors within nerves. Successful complet ....Injury to the brain and spinal cord often leads to permanent disability due to lack of regeneration. The mechanism why central nerve does not regenerate is not known. Neurotrophic factors are powerful molecules which can overcome effects of inhibitory factors on regeneration. This project aims to investigate how neurotrophic factors override the effects of inhibitory factors and how to improve the regeneration by increasing the production of neurotrophic factors within nerves. Successful completion of this project will help understanding the mechanism of how neurotrophic factors work on regeneration and developing the effective way to improve regeneration of the injured spinal cord.Read moreRead less
Regulation Of Extraocular Myosins In Craniofacial Muscles
Funder
National Health and Medical Research Council
Funding Amount
$196,018.00
Summary
Muscles which move the eyeball are highly complex and contain a special motor protein which enables them to contract with the highest speed of all muscles in the body. This protein is found also in muscles of the throat which open and close the airway during coughing, sneezing and swallowing. These muscles also make many other types of motor proteins, giving them a wide spectrum of properties. The functional advantage of having very fast muscles to move the eyes, and protect the airway by preven ....Muscles which move the eyeball are highly complex and contain a special motor protein which enables them to contract with the highest speed of all muscles in the body. This protein is found also in muscles of the throat which open and close the airway during coughing, sneezing and swallowing. These muscles also make many other types of motor proteins, giving them a wide spectrum of properties. The functional advantage of having very fast muscles to move the eyes, and protect the airway by preventing foreign bodies from entering the lungs, is obvious, but how the synthesis of this motor protein is restricted to these muscles is intriguing. Studies in limb muscles have established the principle that the type of motor protein in a muscle is determined by both the type of muscle cells and the type of innervation. Nerves can change the motor proteins in response to the pattern of use imposed by the brain via electrical impulses along its nerve supply. It is known that frequency of nerve impulses to eye muscles are exceptionally high. This project will use several approaches to test the hypothesis that the nerve impulse pattern delivered to these special muscles is involved in the regulation of this motor protein. In one approach, these muscles in rat will be subject to long-term paralysis by cutting their nerve or by the use of botulinum toxin to see if the motor protein is abolished or reduced. In another, the nerve to throat muscles which make this protein will be redirected to another throat muscle which does not normally make this motor protein. These experiments are expected to support the notion that eye and throat muscles are different from all other muscles in the body, and that the normal neural activity from nerves innervating these special muscles is necessary for inducing the synthesis of their motor proteins. These results will greatly help us understand how eye and throat muscles acquire their unique characteristics.Read moreRead less
The Role Of Ten-m3 In Patterning Ipsilateral Retinal Projections
Funder
National Health and Medical Research Council
Funding Amount
$453,042.00
Summary
The normal functioning of the brain depends on connections of billions of nerve cells or neurons. We have found that a protein called Ten_m3 plays a very important role in specifying the way that neurons from the eye connect to the brain. The role of this protein is so important that mice which lack the protein behave as if they are blind. The aim of this project is to understand how this protein controls the development of the visual system.
Novel Molecules Underlying The Development Of Corticopetal And Corticofugal Pathways
Funder
National Health and Medical Research Council
Funding Amount
$289,250.00
Summary
The mammalian brain consists of many discrete areas which perform specific functions. Each area has specific sets of connections with other brain areas. These sets of connections underlie the ability of the brain to execute functions critical to our daily lives, such as sight, hearing, touch and movement, as well as more complex functions such as memory, motivation and reasoning. We currently know little about how the sets of connections which underlie these functions are formed. The aim of this ....The mammalian brain consists of many discrete areas which perform specific functions. Each area has specific sets of connections with other brain areas. These sets of connections underlie the ability of the brain to execute functions critical to our daily lives, such as sight, hearing, touch and movement, as well as more complex functions such as memory, motivation and reasoning. We currently know little about how the sets of connections which underlie these functions are formed. The aim of this project is to understand how some of the connections between the cortex and other brain areas are formed during development. To do this the project will combine modern molecular techniques with neuroanatomy to identify molecules that are expressed by specific populations of neurons during critical developmental stages. These molecules will then be misexpressed in order to determine whether they are important for the development of appropriate connectivity in the brain. A knowledge of the molecules that regulate the development of neuronal pathways is critical to understanding brain development. In the long term, it will also lead to the development of therapies for cases when the brain is damaged or does not develop appropriately due to disease or injury.Read moreRead less