Determining The Pathomechanics Of Muscle Weakness In Older Individuals With Toe Deformities In Order To Develop Evidence-based Intervention Strategies To Restore Foot Function
Funder
National Health and Medical Research Council
Funding Amount
$316,251.00
Summary
Hallux valgus and lesser toe deformities are highly prevalent foot problems in older people that can cause foot disfigurement, physical discomfort, and increase the risk of falling. This study will investigate how toe muscle weakness is affected by these toe deformities as the basis upon which to develop interventions that can restore foot function in older individuals, in order to reduce falls risk, foot pain and, in turn, improve independence and quality of life throughout ageing.
Pain changes movement. Although undisputed, there is a surprising lack of agreement regarding the underlying mechanisms. This project involves an innovative mix of neurophysiological methods to investigate the drive to muscle cells from the nervous system and changes in the mechanics of contraction. These studies will resolve the perplexing problem of how pain changes our ability to activate muscle. Clear understanding of the underlying mechanisms can guide rehabilitation.
Pain And Trunk Muscle Control: Effects, Mechanisms And Consequences
Funder
National Health and Medical Research Council
Funding Amount
$296,452.00
Summary
Twenty-one percent of Australians report long-term back problems. This makes back pain the most common chronic pain in Australia and most prevalent disorder among the National Health Priority Areas. For the majority with recurrent and chronic problems, the cause is unknown but changes in control of the spine are thought to be important. It is well accepted that pain and injury to the low back affect the way that we control the back muscles and this leads to changes in spinal function. However, d ....Twenty-one percent of Australians report long-term back problems. This makes back pain the most common chronic pain in Australia and most prevalent disorder among the National Health Priority Areas. For the majority with recurrent and chronic problems, the cause is unknown but changes in control of the spine are thought to be important. It is well accepted that pain and injury to the low back affect the way that we control the back muscles and this leads to changes in spinal function. However, despite considerable investigation of this problem, there is a distinct lack of consensus for how the control of movement is changed during pain, why it changes, and whether these changes lead to further problems in the long term. The objective of this series of studies is to determine how the adaptation to pain changes the control of the spine. We will use a range of techniques that include tests of the strategies used by the brain to control the spine and mathematical models to estimate the effect that these changes have on the spine when people are given back pain by injecting sterile salty water into the back muscles. These studies will be backed up by measures of mechanical properties of the spine and by comparison to people with clinical pain. This combination of methods has not been used previously and is likely to help resolve the problem of how muscle control is chaged in back pain. We will also test a range of hypotheses regarding how pain has its effect on muscle activity. A final series of studies aims to determine whether the failure of these changes in muscle control to resolve after an epiosde of back pain leads to increased recurrence of pain in the long-term. The importance of this project is highlighted by the significance of back pain as a major health issue, the lack of consensus regarding the effect and mechanisms of pain on trunk muscle control (despite extensive investigation), and the potential for the findings to guide rehabilitation and management.Read moreRead less
Reconsideration Of The Mechanisms Underlying Movement Changes With Pain
Funder
National Health and Medical Research Council
Funding Amount
$401,361.00
Summary
Pain changes the way we move. Although undisputed, there is a surprising lack of agreement regarding the underlying mechanisms. This project involves an innovative mix of neurophysiological methods to investigate how the drive to muscle cells from the nervous system is altered during pain. We aim to resolve the perplexing problem of how pain changes our ability to activate muscle. Our findings are likely to provide a clear understanding of the underlying mechanisms and guide rehabilitation.
Temporomandibular Disorders (TMD) are characterised by pain and limited jaw movement and are a significant issue. Current management is influenced by the view of a simple association between pain and limited movement. This study will test a new theory that an individual's motor response to pain is influenced by the complexity of the jaw motor system as well as the individual's pain experience. This project will point towards individualised recommendations for effective management of TMD.
An FMRI Analysis Of The Functional Organization Within The Brain Of Experimental Superficial And Deep Orofacial Pain
Funder
National Health and Medical Research Council
Funding Amount
$307,526.00
Summary
This project will investigate how the human brain processes a number of important aspects of human jaw muscle pain that are clinically relevant but poorly understood. For example, we do not understand why jaw muscle pain has such different behavioural effects to skin pain. Jaw muscle pain is associated with a significant emotional component not seen in with skin pains. Also, skin pain usually has a sharp or burning quality, is well-localized and is readily treated, while jaw muscle pain is a dee ....This project will investigate how the human brain processes a number of important aspects of human jaw muscle pain that are clinically relevant but poorly understood. For example, we do not understand why jaw muscle pain has such different behavioural effects to skin pain. Jaw muscle pain is associated with a significant emotional component not seen in with skin pains. Also, skin pain usually has a sharp or burning quality, is well-localized and is readily treated, while jaw muscle pain is a deep pain that has a dull, aching quality that may be referred to related sites of the face, head and neck. It is also not known why jaw muscle pain is more common in females in comparison to males. Chronic jaw muscle pain is a major symptom of patients with Temporomandibular Disorders, the most common form of non-dental orofacial pain and that involves pain in or about the jaw joint and-or jaw muscles, and often limitation of jaw movement. Chronic jaw muscle pain can have a severe effect on quality of life but its diagnosis and management is difficult. Despite the widespread prevalence of chronic orofacial pains, we have little information on the central processing of chronic human orofacial pain. This proposal will improve our fundamental understanding of how jaw muscle pain is processed in the brain. The way that the central nervous system processes and represents jaw muscle pain will help explain why these pains present differently in the clinic and should provide important information on the differences between females and males in the representation of jaw muscle pain. This information on the central processing of chronic orofacial pain is crucial to inform the direction of novel or specific management strategies. Our long-term goal is to improve the diagnosis and management of patients with Temporomandibular Disorders, and the present application represents a major new direction of research.Read moreRead less
This is a study of the senses which arise from our muscles and which tell us where our different body parts are, at any point in time. These senses, collectively called proprioception, are also involved in the automatic, unconscious control of our muscles. So, ultimately, they allow us to stand and to move freely with precision and confidence, even in the dark. One of these senses, the sense of effort or of heaviness, is believed to be generated within the brain. It intensifies when we become fa ....This is a study of the senses which arise from our muscles and which tell us where our different body parts are, at any point in time. These senses, collectively called proprioception, are also involved in the automatic, unconscious control of our muscles. So, ultimately, they allow us to stand and to move freely with precision and confidence, even in the dark. One of these senses, the sense of effort or of heaviness, is believed to be generated within the brain. It intensifies when we become fatigued. These experiments will be concerned with finding out more about how this works. We have a method that uses magnetic stimulation of the brain to change its control of our muscles. Using it we will learn how this sense is generated. When we close our eyes and move our limbs we realise that we know exactly where they are at any point in time. It remains uncertain exactly how this information is generated within the nervous system. One idea, arising from some recent experiments which we want to test, is that as we move the limb, the skin over the moving parts is stretched and stretch-sensitive nerve endings in the skin provide us with information about the movement. Alternatively, perhaps it is the effort we exert to maintain limb position against the force of gravity which tells us where the limb is. In another recent study we have found that when a muscle has become painful from excessive exercise or from some local strain injury, our ability to control the muscle and so move the limb is no longer as effective. We want to study the underlying nervous mechanisms responsible for the changes in movement control. Are they designed to spare the muscle while it recovers from injury? How are they brought about? All of this work is important for a better understanding of ourselves, for a better clinical diagnosis when something goes wrong and for improved treatment of diseased or injured muscles.Read moreRead less
The Effects Of Tonic Muscle Pain On The Sympathetic And Somatic Motor Systems In Human Subjects
Funder
National Health and Medical Research Council
Funding Amount
$462,948.00
Summary
The main objective of this proposal is to reveal the effects of nociceptive reflexes in humans, and thus identify their functional and clinical implications. By performing invasive recordings from the nerves that control blood vessels and muscles in healthy volunteers subjected to long-lasting (~1 hour) experimental pain, this work will increase our understanding of the adaptive changes that pain induces and improve treatments to prevent pain from becoming chronic.