The NanoNautilus : A Breakthrough In The Successful Treatment Of Strokes And Other Cerebrovascular Diseases
Funder
National Health and Medical Research Council
Funding Amount
$187,212.00
Summary
Strokes are one of the biggest killers of Australians and are becoming increasingly so every year. Bleeding from the brain involves extremely delicate and dangerous medical treatments. The development of NanoNautilus [TM]---a remote-controlled steerable microcatheterusing world-first miniaturization technology---will revolutionise current practises and greatly reduce the current risk with medical intervention.
Mechanical Mobility Of The Thorax For Continuous Determination Of Lung Gas Volume
Funder
National Health and Medical Research Council
Funding Amount
$165,000.00
Summary
Percussion is a valuable clinical method for physical examination of parts of the body. A sharp tap (impulsive force) is applied to the body wall and the sound radiated in response is observed. This sound may be dull (over liver) or stony dull (pleural effusion), or resonant (over normal lung) or hyper-resonant (over bowel). While the variation in radiated sound is not fully understood, it is apparent that the presence of gas, which is highly compliant, increases mobility of the overlying tissue ....Percussion is a valuable clinical method for physical examination of parts of the body. A sharp tap (impulsive force) is applied to the body wall and the sound radiated in response is observed. This sound may be dull (over liver) or stony dull (pleural effusion), or resonant (over normal lung) or hyper-resonant (over bowel). While the variation in radiated sound is not fully understood, it is apparent that the presence of gas, which is highly compliant, increases mobility of the overlying tissue and allows it to resonate; where the sub-tissue is largely fluid, tissue mobility is low and the percussive sound is dull. Percussion is useful for examining the adult chest and lung, but cannot for example be applied in infant intensive care as only limited impulsive force can be used, and the adult finger, which is both a coupling device and sounding board, is too large. As well, percussion requires skill and quiet conditions. Accordingly, we developed a device to measure mobility of the chest and other tissues in real time. The VibroPulse applies a known low-level force to the body surface and records the resultant velocity induced in the surface. The force is generated by a vibrating mass set in motion by an electromagnetic motor driven by pseudo-random noise. Tissue mobility, defined as velocity-force, is derived simultaneously across the frequency range, providing an easily interpreted quantitative output unaffected by ambient noise. This proposal has two aims we can achieve in 1 year: (1) to continue evaluating VibroPulse sensitivity to tissue composition, using symmetrical percussive sites on the human chest and abdomen that are dull on one side and resonant on the other, and the chest of anaesthetised animals with experimentally induced pneumothorax and lung collapse, two life-threatening conditions for which percussion is a key diagnostic method, and (2) to engineer a small device from our bulky prototype that is suitable for clinical use, in infants and adults.Read moreRead less
Therapeutic Development Of A Novel EphA4 Antagonist For Spinal Cord Injuries
Funder
National Health and Medical Research Council
Funding Amount
$687,105.00
Summary
Spinal cord injuries impose a significant burden on patients and their carers. At present, there are no treatments for spinal cord injury that provide functional improvement. This research program will develop a novel therapeutic molecule, EphA4-Fc, which promotes axonal regeneration and delivers significant functional improvement. We will determine the most effective protocol for EphA4-Fc administration and the physiological and functional outcomes of these treatment regimes.
Commercial Testing Of A Physiologically Based Theory Of Oscillatory Brain Electrical Activity In Anaesthesia Monitoring
Funder
National Health and Medical Research Council
Funding Amount
$191,165.00
Summary
While the mechanisms of local anaesthesia are comparatively well known, the mechanisms whereby anaesthetics impair consciousness remain unresolved. This lack of understanding has implications in our ability to monitor the level of anaesthesia while anaesthetic consumption and side effects are minimized. Despite this a number of devices have been developed that attempt to monitor the depth of anaesthesia by quantifying the brains electrical activity. All monitors analyse the activity using a set ....While the mechanisms of local anaesthesia are comparatively well known, the mechanisms whereby anaesthetics impair consciousness remain unresolved. This lack of understanding has implications in our ability to monitor the level of anaesthesia while anaesthetic consumption and side effects are minimized. Despite this a number of devices have been developed that attempt to monitor the depth of anaesthesia by quantifying the brains electrical activity. All monitors analyse the activity using a set of criteria that have been developed by trial and error. The research of Dr David Liley and his team, at Swinburne University of Technology, has resulted in a detailed understanding of the physiological mechanisms that generate brain electrical activity. The outcome is a practical means to carry out a System Based Analysis of Brain Electrical Response (SABER). In 2004, Dr Liley began working with Cortical Dynamics, a company involved in the commercialisation of medical devices. This collaboration incorporated the SABER system into a new prototype device called the Brain Anaesthesia Response (BAR) monitor. In 2004 Dr Liley and Associate Professor Kate Leslie collaborated in a trial, at the Royal Melbourne Hospital to test the sensitivity of the SABER system in quantifying the effect that various levels of nitrous oxide have on measures of anaesthetic depth. The Australian and New Zealand College of Anaesthetists supported this study. Initial results obtained with sevoflurane and 3 levels of nitrous oxide showed the ability to differentiate between conscious and unconscious states of patients based on two physiological characterizations of higher brain dynamic state. The next step requires commercial product validation (ie scale up) and further clinical efficacy in testing beta stage depth of anaesthesia BAR units. Completion of this will help the technology move away from a low volume prototype system into a commercially applicable device.Read moreRead less
Elastaderm: An Improved Human Skin Substitute For Treating Burns
Funder
National Health and Medical Research Council
Funding Amount
$326,316.00
Summary
We will focus on proof of concept needed for the commercialisation of improved dermal replacements designed to repair severe skin burns. These novel dermal replacements are a substantial development of and improvement beyond existing technology because they are intended to reduce wound contraction and increase elasticity.
Development Of Monoclonal Antibody Therapy For Treating Wounds
Funder
National Health and Medical Research Council
Funding Amount
$573,354.00
Summary
Chronic wounds, diabetic ulcers, injuries in response to trauma, burns and scalds form a medical need which will only expand as the population ages and the diabetic epidemic grows. In our studies, we have shown that Flightless I (Flii), an actin-remodelling protein, is a negative regulator of wound healing. We are developing monoclonal antibodies as a new therapy for reducing Flii levels in wounds which leads to improved wound repair outcomes.
Se015: A Developmental Drug For The Treatment Of Brain Tumours
Funder
National Health and Medical Research Council
Funding Amount
$304,206.00
Summary
Primary malignant brain tumors are amongst the most lethal forms of human cancers with median survival for these patients being only around 1 year. In spite of the advent of new targeted therapies for some cancers the prognosis for these patients remains dismal. Worldwide, more than 95% of all people who contract the disease will die of it. This is because there are no effective therapies and all current treatments are only palliative, seeking to lesson the distressing suffering associated with ....Primary malignant brain tumors are amongst the most lethal forms of human cancers with median survival for these patients being only around 1 year. In spite of the advent of new targeted therapies for some cancers the prognosis for these patients remains dismal. Worldwide, more than 95% of all people who contract the disease will die of it. This is because there are no effective therapies and all current treatments are only palliative, seeking to lesson the distressing suffering associated with disease progression. Nearly all therapies that have shown some efficacy in treating cancer, such as chemotherapy and radiation have a mode of action whereby they attempt to kill cancer cells by inflicting enough damage to the cancer cells that they induce them to commit cell suicide, a process called apoptosis. Unfortunately, cancer cells can become resistant to these therapies by activating the cells' own signaling pathways that normally block apoptosis. One of the key pathways that has been implicated in resistance to apoptosis in human cancers is the PI3K-Akt pathway. This pathway is overactivated in many advanced human tumors, particularly in glioblastoma. We have discovered a compound, Se015, which can effecitively block this pathway in brain cancer cells and is able to dramatically improve the effectiveness of both chemotherapy and radiation in killing these cells. We have confirmed the efectiveness of Se015 in preliminary animal models of brain cancer, where we have shown that Se015 demonstrated no noticeable toxicity and was active when taken orally. We now need to explore further the molecular mode of action of Se015, as well as complete our animal studies with the eventual aim of initiating a small trial of Se015 in glioblastoma patients in the forseeable future.Read moreRead less
Neuropathic Pain Drugs Based On The Endogenous Opioid Peptide Endomorphin 1.
Funder
National Health and Medical Research Council
Funding Amount
$209,470.00
Summary
We have developed a new pain drug based on the natural pain killing opioid peptide, Endomorhin 1. The new drug exhibits activity similar to morphine and gabapentin against neuropathic pain in animals but seems to act through a different mechanism. We will complete our preclinical investigation of this compound by assessing its side effect profile and tolerence inducing properties in animals. We will also continue our development of an orally active analogue of this important peptide.
Newborn babies are at risk of becoming short of oxygen during delivery and sustaining brain damage. Seizures may cause further damage to the brain because they release damaging chemicals or make extra energy demands on the brain that cannot be met. To detect seizures, it is necessary to measure the EEG, the tiny electrical signals from the brain. We are proposing to automatically detect and count seizures, building upon 8 years of fundamental EEG signal processing research work we have undertake ....Newborn babies are at risk of becoming short of oxygen during delivery and sustaining brain damage. Seizures may cause further damage to the brain because they release damaging chemicals or make extra energy demands on the brain that cannot be met. To detect seizures, it is necessary to measure the EEG, the tiny electrical signals from the brain. We are proposing to automatically detect and count seizures, building upon 8 years of fundamental EEG signal processing research work we have undertaken. We anticipate that the product will be of major commercial interest. We will further explore what is a rapidly expanding marketplace and ensure we maximize the commercial return on this product.Read moreRead less
Development Of Flightless Antibody Therapy For Treating Wounds
Funder
National Health and Medical Research Council
Funding Amount
$194,071.00
Summary
Chronic wounds, diabetic ulcers, injuries in response to trauma, burns and scalds form a medical need which will only expand as the population ages and the diabetic epidemic grows. In our studies, we have shown that Flightless I (FliI), an actin-remodelling protein, is a negative regulator of incisional wound healing. We are now developing a new antibody therapy to reduce FliI levels in wounds thereby leading to improved wound repair outcomes.