Effect Of Prostaglandin E2 On The Periodontium And Alveolar Bone Formation
Funder
National Health and Medical Research Council
Funding Amount
$211,527.00
Summary
Dental disease affecting the supporting structures of teeth (the periodontium), is prevalent in our society. Periodontal disease results in destruction of bone around teeth, loosening of teeth, compromised chewing function, and tooth loss. Over the last twenty years reports into the effects of prostaglandin E2 (PGE2) on the skeleton have been divided and controversial. While historically PGE2 has been reported to promote bone resorption, more recently it has been demonstrated that when PGE is pl ....Dental disease affecting the supporting structures of teeth (the periodontium), is prevalent in our society. Periodontal disease results in destruction of bone around teeth, loosening of teeth, compromised chewing function, and tooth loss. Over the last twenty years reports into the effects of prostaglandin E2 (PGE2) on the skeleton have been divided and controversial. While historically PGE2 has been reported to promote bone resorption, more recently it has been demonstrated that when PGE is placed in contact with mandibular bone, adjacent to erupted teeth, new bone and cementum formation occurs. The ability of PGE2 to induce new bone formation indicates a potential use for PGE2 in the management of bone loss associated with periodontal diseases, and the formation of new bone around dental implants, and around teeth following orthodontic movement. Growth factors are active in healing and have valuable applications in augmenting wound repair. Osseous and dental tissues are rich in growth factors, and these factors are involved with the regulation of bone metabolism as well as tissue repair, thus the action of PGE2 on the periodontium is most likely regulated via these factors. Since regeneration of the periodontium is a fundamental goal of dentistry, any treatment which leads to predictable formation of new connective tissues and their long term stability would be a major clinical advance.Read moreRead less
Epidermal Growth Control In Psoriasis And Normal Skin
Funder
National Health and Medical Research Council
Funding Amount
$451,980.00
Summary
Our skin protects us from damage, dehydration, infection and harmful UV radiation. At the same time, we expect it to remain healthy, smooth and looking good. How the skin, and more particularly its upper layer, the epidermis, adapts to all these requirements is a complex problem yet to be fully understood. This question forms the basis of our project proposal. The epidermis is a continuously self-renewing tissue, in which cells have an average life of 30 days before they are invisibly shed to th ....Our skin protects us from damage, dehydration, infection and harmful UV radiation. At the same time, we expect it to remain healthy, smooth and looking good. How the skin, and more particularly its upper layer, the epidermis, adapts to all these requirements is a complex problem yet to be fully understood. This question forms the basis of our project proposal. The epidermis is a continuously self-renewing tissue, in which cells have an average life of 30 days before they are invisibly shed to the outside. In normal states and when responding to injury or disease, this cell turnover speed can be finely tuned, for example accelerated in the case of a healing wound. In contrast, if damaged by the sun, epidermal cells undergo a form of cell suicide (apoptosis) to prevent tumours forming from cells with damaged genes. This changing turnover speed is controlled by a series of growth factors, or cytokines. Insulin-like growth factor-I (IGF-I) is a unique cytokine that can control both cell turnover rate, and cell death. We aim to uncover the complex biochemical interactions that allow the epidermal IGF-I system to achieve this seemingly contradictory task. This study is important because when the epidermis loses the ability to finely tune its turnover speed, ulcers, sun damage, the common skin disorder psoriasis, or worse still, skin tumours, arise. This project explores ways of manipulating the IGF-I system to prevent this, and builds on some technology developed by the research group that has already proven effective in the control of psoriasis. The project also promises to discover undiscovered growth regulators that could be used in new gene therapies for skin overgrowth diseases.Read moreRead less
Compared with normal-weight children, obese youth have a higher chance of developing diseases like Type 2 diabetes. With 1 in 4 Australian children now being overweight or obese, effective treatment programs need to be developed alongside those aimed at prevention. This program of research aims to identify which overweight/obese children are most likely to develop diabetes, with a particular focus on how infant nutrition regulates important growth factors to alter long-term diabetes risk.