The goal was finally achieved after four years of research. Scientists from Graz University of Technology and their colleagues in Graz and Vienna finally concluded the development stage of the BRIC – Bio Resorbable Implants for Children project. Bioresorbable implants are implants that are resorbed by the body over time. In contrast to traditional implants, such as plates, screws or pins, which have to be surgically removed after a certain time, bioresorbable implants do not have to be surgically removed. The BRICs are to be used in children, who suffer particularly from each surgical intervention.
Detailed work over many years was necessary for the success of this development. The project was co-ordinated by Dr Annelie Weinberg at the Department of Paediatric Surgery in Graz. Apart from the Medical University of Graz, the project consortium on the academic side consisted of two working groups made up by Graz University of Technology, Vienna University of Technology, and even the University of Natural Resources and Life Sciences, Vienna. The participation of partners AT&S and Heraeus demonstrates the great interest shown by industry in the results.
No negative affects on the body
The two Graz University of Technology teams led by Martin Koller, responsible for the biotechnology part, and Franz Stelzer, whose team processed the biopolymers into implants, managed to develop microbial biopolyesters – so-called polyhydroxyalkanoates, known as PHAs, which can be processed into implants. “The production is completely independent of fossil resources, so there are no negative affects on the body. The implant is produced by bacteria and can be absorbed by the human body after it has fulfilled its task,” said Martin Koller. Alternative biopolymers, such as polylactic acid, in contrast to PHAs, lead to a hyperacidity of the organism and bring about chronic inflammation. PHAs, on the other hand, are high-grade materials whose biotechnological production is based on renewable raw materials.
Another advantage of the new implants is that they are more biocompatible than the previously used steel or titanium materials and thus promote the bone healing process. Furthermore, the speed of their breakdown by the body can be controlled by means of the implant’s precise composition. The breakdown of the implant should take place at the same speed as the bone heals.
The materials are in the development stage and their material properties and biodegradation rates are currently being tested.
Dipl.-Ing. Dr.techn. Martin Koller
Institute of Biotechnology and Biochemical Engineering
Tel.: +43 (316) 873 8409
TU Graz – Mitglied der TU Austria