The Neurovascular Territories Of The Human Body: Anatomic Study And Clinical Applications
Funder
National Health and Medical Research Council
Funding Amount
$186,650.00
Summary
A Melways Roadmap of the anatomy of the large and small nerves, arteries and veins of the human body is underway and will take a further three years to complete. The aim is to evolve or modify Reconstructive Plastic Surgery techniques taking tissue from a hidden site and, where possible, include a nerve supply with the transplant so that feeling can be restored to skin flaps and function to transferred muscle. The fundamental objective is to improve the quality of the patients life. We have alre ....A Melways Roadmap of the anatomy of the large and small nerves, arteries and veins of the human body is underway and will take a further three years to complete. The aim is to evolve or modify Reconstructive Plastic Surgery techniques taking tissue from a hidden site and, where possible, include a nerve supply with the transplant so that feeling can be restored to skin flaps and function to transferred muscle. The fundamental objective is to improve the quality of the patients life. We have already completed a thorough examination of the following regions: (i) head and neck (ii) forearm (iii) leg These have received international acclaim and awards. We are currently examining: (i) hand and foot (ii) thigh and buttock. Still to be commenced: (i) arm and shoulder (ii) torso (iii) back. Reconstructive surgery involves the treatment and the reconstruction of defects throughout the whole human body. These defects may arise in any member of the family. With modern reconstructive techniques a problem can often be solved in one operation thus avoiding multiple operations and long periods of hospitalisation which can be devastating to both patient and family. These new techniques nevertheless have demanded a reappraisal of the basic sciences, especially the anatomy of the blood and nerve supply to the potential transplant. This is essential so that they can be designed with not only precision and safety but in such a way that there is minimal disability at the donor site. As well as restoring shape and form, the patient can have tremendous improvement in quality of life and independence if function is also restored. In order to provide function (feeling and movement) a working nerve supply must be included in the reconstruction. Therefore our research must continue to investigate the complex patterns of nerve supply to tissues of the body and correlate this information with the blood supply which is needed to keep the tissue alive.Read moreRead less
Developing In Vivo Methods Of Adipose Tissue Engineering
Funder
National Health and Medical Research Council
Funding Amount
$374,703.00
Summary
Surgical repair and replacement of soft tissues after tumour removal or to repair existing damage requires fat tissue with a good blood supply. Tissue engineering allows us to create new fat grafts for replacement tissue without causing unnecessary pain or trauma to the patient. We have developed a method for growing fat tissue using a chamber to maintain a space for the tissue to grow into, a blood vessel to supply nutrients to the growing tissue, cells or tissue from the host to encourage cell ....Surgical repair and replacement of soft tissues after tumour removal or to repair existing damage requires fat tissue with a good blood supply. Tissue engineering allows us to create new fat grafts for replacement tissue without causing unnecessary pain or trauma to the patient. We have developed a method for growing fat tissue using a chamber to maintain a space for the tissue to grow into, a blood vessel to supply nutrients to the growing tissue, cells or tissue from the host to encourage cell growth and migration and a matrix or scaffold to support the developing tissue and guide it to form the type of tissue we want (fat, muscle etc). We have shown that the tissue graft may cause fat to grow due to causing an inflammatory reaction and confirmed this by adding a mild inflammatory compound to the chamber instead of a tissue graft. This compound caused the chamber to grow fat tissue. The aim of this project is to determine which of the growth factors or other signaling factors released by the inflammation process is responsible for causing fat tissue production and to identify what cells are being attracted to the chamber to help grow the fat, so that we can further improve our engineering of fat tissue. Understanding the pathways which mediate or stimulate fat growth will provide new opportunities for improving fat growth and allow the engineering of larger fat grafts in larger animals and eventually human clinical application. Beyond that, inflammation is involved in many disease processes (eg. obesity, metabolic syndrome, diabetes, cancer), and these fields of study will also benefit from our research.Read moreRead less
In Vivo Tissue Engineering Of Adipose Tissue For Reconstructive Surgery
Funder
National Health and Medical Research Council
Funding Amount
$713,545.00
Summary
We are able to grow vascularised tissue in implanted plastic chambers to a predetermined size and shape in the rat and mouse (NHMRC Project Grant 01-03; #145782; CIA Morrison). The basis of this growth is blood vessel sprouting from the surface of the vessel bundle or loop, followed by synthesis of structural molecules and the migration of surrounding cells into the vascularised network to form a stable tissue. Unlike other in vivo models of tissue engineering, the tissue grows spontaneously and ....We are able to grow vascularised tissue in implanted plastic chambers to a predetermined size and shape in the rat and mouse (NHMRC Project Grant 01-03; #145782; CIA Morrison). The basis of this growth is blood vessel sprouting from the surface of the vessel bundle or loop, followed by synthesis of structural molecules and the migration of surrounding cells into the vascularised network to form a stable tissue. Unlike other in vivo models of tissue engineering, the tissue grows spontaneously and is densely vascularised, enabling continuous growth and surgically transfer to another part of the body, or to another animal. In this renewal application of the above NHMRC grant, we propose to direct these findings towards the development of vascularised fat tissue which would be ideal for reconstructive surgery as a stable, inert tissue filler. Our efforts to grow fat tissue in vivo to date have identified 4 major requirements: a fat precursor cell source; an instructive basement membrane matrix (which may include growth-differentiation factors); space into which the tissue can grow; a stable blood supply. We will focus here on optimising the precursor cell source and instructive matrix to generate vascularised fat tissue around the blood supply we can engender in our tissue engineering chamber. We have found Matrigel, a mouse tumor-derived matrix rich in basement membrane components, to be instructive for growing fat, and will also build on preliminary observations that either muscle or fat tissue can provide the appropriate precursor cells for this process. Finally we propose to adapt and upsize the vascularised fat tissue chamber to the pig, in a step towards human use, and assess its transplantability and longevity. The clinical application of our work is to produce breast reconstruction tissue and lipo filling for contour deformities resulting from trauma, congenital deformity, ageing and cancer surgery, particularly breast reconstruction.Read moreRead less