Neural Basis Of The Functions Of The Primary Visual Cortex: Roles Of Feedforward And Intracortical Inputs
Funder
National Health and Medical Research Council
Funding Amount
$486,280.00
Summary
Signals from the eyes undergo extensive processing at the level of the primary visual cortex so that basic features in the scene such as lines, edges, colours and movement are coded in the activity of individual neurones. This project aims to further our understanding of this process at the basic cellular level. This will not only enable interventions that would help those with poor sight but also give us an insight into basic brain circuitry and its derangement in many neurological disorders.
Mechanisms Underlying Efferent Feedback In The Vestibular System
Funder
National Health and Medical Research Council
Funding Amount
$491,475.00
Summary
The balance system has a remarkable, but poorly understood capacity for self-repair. An intrinsic feedback mechanism, the Efferent Vestibular System or EVS is thought to play a major role in this self-repair. Surprisingly, we know little about EVS function in animals or humans. We will study the EVS in mice and humans to gain a better understanding of how it works. This information will then drive the design of therapies that improve and restore balance in disease, injury, or ageing.
Synaptic Environment Of Nociceptive Inputs To The Spinal Cord
Funder
National Health and Medical Research Council
Funding Amount
$499,860.00
Summary
Pain affects everyone at some stage in their life. Usually, the pain subsides by itself as the underlying cause is resolved. Thus, the damaged tissue heals or we move away from a potentially injurious stimulus and we become free of pain. However, pain can persist for two main reasons: the underlying cause cannot be treated adequately and the painful stimulus continues; or the pain is maintained long after the primary stimulus has resolved. This ongoing pain often is resistant to alleviation by c ....Pain affects everyone at some stage in their life. Usually, the pain subsides by itself as the underlying cause is resolved. Thus, the damaged tissue heals or we move away from a potentially injurious stimulus and we become free of pain. However, pain can persist for two main reasons: the underlying cause cannot be treated adequately and the painful stimulus continues; or the pain is maintained long after the primary stimulus has resolved. This ongoing pain often is resistant to alleviation by common analgesics. Therefore, a major aim of the pharmaceutical industry is the development of new drugs to target persistent pain. This requires a thorough understanding of how the nerves that detect painful stimuli transmit that information into the spinal cord, and then on to the brain, where we construct a conscious perception of the pain. Various kinds of painful stimuli, such as tissue damage, noxious chemicals, or extreme temperatures, are detected by different types of nerves. Each nerve type can be identified by its characteristic chemical profile. Recently, we found that some of these nerves probably do not transmit their messages to the spinal cord in the way everyone had thought. This means that there must be an alternative way for many types of painful stimuli to be transmitted into the spinal cord. In this project, we will use a sophisticated suite of modern microscopic and electrical recording techniques to find out what this alternative mechanism is. Our central idea is that most types of painful stimuli simultaneously activate two types of sensory nerves. These nerves then connect with specific nerve cells in the spinal cord before painful information is relayed to the brain. Our proposal suggests a new mechanism for understanding how pain can develop from being an acute defensive reaction to a chronic problem. In turn, this should lead to improved strategies for developing and testing new analgesic drugs.Read moreRead less
The superior colliculus is a brain centre which uses visual information from the eyes and other sensory information, such as sound, to direct the head and eyes towards objects of interest. This project will use current advancements in optogenetics to activate connections to this brain region in order to understand its role in coordinating head and eye movements. This will advance our understanding of how the brain collects and processes visual information to subserve behavioural functions.