GENERATION OF VASCULARISED, BIOENGINEERED SOFT TISSUES
Funder
National Health and Medical Research Council
Funding Amount
$445,045.00
Summary
One of the most exciting areas in reconstructive surgery today is the tissue engineering of body parts, the process by which blood vessels are implanted into skin, muscle, bone, cartilage or even synthetic materials, to build composite living structures. Once a circulation becomes established, the engineered part can be transferred by joining the implanted blood vessels to corresponding ones at the recipient site. We have discovered that new tissue will grow out of a surgically created blood ves ....One of the most exciting areas in reconstructive surgery today is the tissue engineering of body parts, the process by which blood vessels are implanted into skin, muscle, bone, cartilage or even synthetic materials, to build composite living structures. Once a circulation becomes established, the engineered part can be transferred by joining the implanted blood vessels to corresponding ones at the recipient site. We have discovered that new tissue will grow out of a surgically created blood vessel loop placed in a cylindrical plastic chamber filled with a scaffold made of naturally occurring structural molecules. In Part 1 of this project, it is planned to optimise the rate of new vascularised tissue growth through the addition to the growth chamber of various biodegradable scaffolds. In Part 2, we aim to produce fat by 3 possible methods using: (a) cells from the rat scrotum, (b) skeletal muscle separated from its blood supply for 24 hours, or (c) bone marrow-derived stem cells, as well as bone from stem cells of the same source. In Part 3, vascularised bone, fat and connective tissue, as produced in Part 2, will be microsurgically transferred to another site in the body to study the short-term (4 weeks) and long-term (12 weeks) survival and changes (if any) in these tissues. These unique methods are currently being patented. This technology introduces the possibility of producing tailor-made tissues of specific composition to suit the repair of a particular tissue type, for example, (1) myocutaneous flaps to replace tissue loss following traumatic injury, (2) bone for nose, digit or joint repair, and (3) fat to provide a bulky flap as required in contour defects of the face and neck. The development of new growth chambers of appropriate body shapes (eg. ears, noses, etc) has significant commercial implications.Read moreRead less
Periodontal Mesenchymal Stem Cells For Periodontal Regeneration
Funder
National Health and Medical Research Council
Funding Amount
$358,000.00
Summary
Dental diseases affecting the gums (periodontal disease) are extremely prevalent in our society. The effects of periodontal disease can be particularly severe as loss of support for the teeth leads to loose teeth and severely compromised masticatory function. If left untreated, the associated pain and loss of function may necessitate extraction of the teeth. We have recently identified cells residing in the periodontal ligament which may be adult stem cells. This project will further characteriz ....Dental diseases affecting the gums (periodontal disease) are extremely prevalent in our society. The effects of periodontal disease can be particularly severe as loss of support for the teeth leads to loose teeth and severely compromised masticatory function. If left untreated, the associated pain and loss of function may necessitate extraction of the teeth. We have recently identified cells residing in the periodontal ligament which may be adult stem cells. This project will further characterize these cells and explore whether they can be used to restore periodontal tissues damaged by periodontal disease.Read moreRead less
Deciphering The Metabolic And Endocrine Profile Of Healthy Adipocytes
Funder
National Health and Medical Research Council
Funding Amount
$563,194.00
Summary
Obesity is associated with the development of metabolic diseases, however, it is becoming clear that it is where the excess fat is stored that is more important when predicting the health risks associated with obesity. This project aims to identify whether adipocyte progenitor cells, which eventually become fat cells, are ‘preprogrammed’ and whether differences in these cells explain the generation of either healthy or unhealthy fat in different locations of the body.
To Repair An Osteo-chondral Defect In An Experimental Rabbit Model Using A Structured 3D Nano-composite Scaffold Loaded With Mesenchymal Stem Cells (MSC)
Funder
National Health and Medical Research Council
Funding Amount
$92,314.00
Summary
The treatment of cartilage damage is a major problem in orthopaedic practice. The use of a 3D scaffold may overcome many challenges associated with cartilage and bone repair and regeneration. The aim of this research is to culture bone and cartilage cells into a prefabricated scaffold which may then be tested in an animal model. The results of this research may offer a new method of treating post-traumatic and osteoarthritic defects.
A Study Of Various Bone Scaffolds In A Maxillary Sinus Model
Funder
National Health and Medical Research Council
Funding Amount
$61,711.00
Summary
This project investigates using animal derived and artificial bone in regions of the mouth that are deficient and not suitable for replacing missing teeth using dental implants. Traditional techniques of bone replacement require the use of a patient's own bone. These procedures are associated with post-operative morbidity and this bone is present in limited quantity. The use of these bone replacements may overcome these challenges and eliminate the need for using patient's bone.
Comparison Of Periodontal Ligament Stem Cells And Induced Pluripotent Periodontal Ligament Stem Cells For Periodontal Regeneration
Funder
National Health and Medical Research Council
Funding Amount
$831,955.00
Summary
In the first part of this study we will determine whether induced pluripotent stem cells or adult stem cells from the periodontal ligament are better candidates for periodontal regeneration. Secondly, using CAD/CAM technology we will make tissue engineering scaffolds tailored to fit periodontal defects and seeded with stem cells to improve on current techniques used to regenerate damaged tissues around teeth affected by periodontal disease.
Dental diseases affecting the gums (periodontal diseases) are extremely prevalent in our society. The effects of periodontal disease can be particularly severe as loss of support for the teeth leads to loose teeth and severely compromised chewing function. If left untreated, the associated loss of function may necessitate extraction of the teeth. We have recently identified cells residing in the periodontal ligament which may be adult stem cells. This project will further characterize these cell ....Dental diseases affecting the gums (periodontal diseases) are extremely prevalent in our society. The effects of periodontal disease can be particularly severe as loss of support for the teeth leads to loose teeth and severely compromised chewing function. If left untreated, the associated loss of function may necessitate extraction of the teeth. We have recently identified cells residing in the periodontal ligament which may be adult stem cells. This project will further characterize these cells and explore whether they can be used to restore periodontal tissues damaged by periodontal disease.Read moreRead less
Development Of Targeted Therapies To Reverse The Effects Of Ageing And Disease On Wound Healing And Tissue Generation
Funder
National Health and Medical Research Council
Funding Amount
$391,228.00
Summary
Despite success with the production of new tissues and organs in laboratory animals, tissue engineering in humans remains elusive. Emerging evidence suggests that ageing and diseases such as diabetes can adversely affect human stem cell regenerative capacity. Characterizing the effects of ageing and disease on stem cells during tissue generation is the first step in reversing these effects, paving the way for the production of new tissues and organs for use in human clinical trials.
Investigating Human Keratinocyte Stem Cells And Their Microenvironmental Niche
Funder
National Health and Medical Research Council
Funding Amount
$570,928.00
Summary
The stem cells in the outer protective layers of the epithelium of the skin (keratinocyte stem cells), possess an intrinsically high capability to regenerate tissue. However, this tissue regenerative ability can be enhanced by interactions with microenvironmental elements i.e. connective tissue cells and proteins. This study seeks to investigate specific keratinocyte-microenvironment interactions which will ultimately be used to improve current methods for generating skin tissue for burns patien ....The stem cells in the outer protective layers of the epithelium of the skin (keratinocyte stem cells), possess an intrinsically high capability to regenerate tissue. However, this tissue regenerative ability can be enhanced by interactions with microenvironmental elements i.e. connective tissue cells and proteins. This study seeks to investigate specific keratinocyte-microenvironment interactions which will ultimately be used to improve current methods for generating skin tissue for burns patients.Read moreRead less
Smart Hybrid Material For Cartilage Tissue Engineering
Funder
National Health and Medical Research Council
Funding Amount
$299,564.00
Summary
Tissue engineering is a promising approach to repair damaged/degenerated cartilage caused by various diseases or injuries. Because of its limited capacity for self repair cartilage becomes a constriant to normal everyday life once degenerated. This project aims to develop composite polymers for cartilage repair. The potential of this newly developed material for cartilage tissue engineering will be investigated through the material and biological characterisation techniques.