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The mathematics of the human body

03/27/2018 | Planet research | FoE Human & Biotechnology | Young Talents

By Birgit Baustädter

Biomechanical engineer Justyna Niestrawska investigates the mechanical behaviour of the aorta at TU Graz and represents it using mathematical formulas. And wins the German Aorta Prize while doing so.

Biomechanical engineer Justyna Niestrawska in her laboratory, where she examines healthy and diseased aortic walls. © Lunghammer - TU Graz
What has mechanical engineering got in common with the human body? Can you explain biological processes like the operations of a machine? The biomechanical engineer Justyna Niestrawska can answer these questions – straight out of her daily work. Her special field is continuum mechanics, in which the operations of the human body are described, modelled and simulated using mathematical equations. German with Polish roots, she originally studied mechanical engineering at RWTH Aachen and specialised in plastics technology. She began to be interested in medical engineering during her master’s programme when she conducted research on heart valves. During a research stay at the University of Auckland, New Zealand, she came across the field of continuum mechanics. On one of the last snowy days of winter in the warm kitchen of the Institute of Biomechanics surrounded by plants, she explains: ‘I first came into contact with this research in New Zealand. It is known that heart muscle contracts less in certain diseases than in the healthy state. And the researchers in New Zealand were working on analysing the mechanics behind this using experiments, mathematically modelling them, and subsequently simulating the movements of the heart on computers.’

Thanks to Gerhard Holzapfel, Justyna Niestrawska moved to TU Graz to take up her place in his working group. He is head of the Institute of Biomechanics, has written several standard works on the topic of continuum mechanics, developed well-known material models, and has headed the TU Graz lead project Mechanics, Modeling and Simulation of Aortic Dissection since the beginning of 2018. 

Since 2014 she has been conducting research at TU Graz on the stress limits of the aorta abdominalis – the main artery supplying the organs in the abdominal area. A very serious disease of the aorta is aortic aneurysm, which occurs predominantly in persons aged 65 or older, and in the worst cases ends in an aortic rupture. Operations are high risk and a decision to operate must be taken on the basis of as much information as possible. ‘Currently operations are carried out with an aneurysm size of five centimetres in women and five and a half centimetres in men. But the size of an aneurysm is not the only factor which defines the risk of rupture,’ explains Niestrawska. In her doctoral thesis she has worked on being able to predict the course of the disease, which can be represented and observed using high-definition imaging techniques. ‘Some aneurysms under five centimetres have torn, and some have grown to ten centimetres without rupturing.’ Together with a team of researchers from TU Graz and the Medical University of Graz the young researcher wants to demonstrate the stress limits of the aorta walls using mechanical stress tests.

The ‘garden hose’ inside our body

In its healthy state, the aorta consists of three easily distinguishable layers which, together with their different structures, ensure that the aorta is flexible and stable and that it can withstand the pressure of pulsating blood without being damaged. The innermost layer is called the tunica intima, consists of endothelial cells and is mechanically negligibly thin in a young person. The tunica media – the middle layer – gives stability to the vessel wall with its straight fibres. ‘You can basically compare the structure of the aorta with a garden hose. As in a garden hose small fibres form a tissue which keeps it flexible and stable at the same time,’ explains Niestrawska. The outermost layer – the tunica adventitia – forms a kind of protection against excess pressure and its corrugated fibrous structure allows the artery wall to expand without damage in the case of a sudden severe stress.

Mechanical tests show the stress-bearing capacity of the artery wall

To obtain reference data, the team initially studied healthy blood vessels. Using a biaxial stretching device developed at the Institute, small pieces of tissue are subject to stress in two directions at different forces. ‘First of all we tested the complete wall, and then we separated the individual layers from each other and clamped them in the tension device,’ explains Niestrawska.
Two hands wearing blue gloves are preparing a sample with black string.
A sample is prepared for mechanical tests in the biaxial tractor using fishing hooks and yarn.
‘Finally we wanted to perform the same tests but with samples from diseased aortas.’ But this wasn’t possible because the first big changes in the diseased aortas became apparent in the first step: ‘Where we were able to separate the layers from each other easily in the healthy samples, the diseased samples had completely grown together and couldn’t be manually separated or even optically distinguished,’ explained the scientist.

For their research results on the aorta abdominalis, which is explained in the paper ‘Microstructure and mechanics of healthy aneurysmatic abdominal aortas: experimental analysis and modelling’ and published in the Journal of the Royal Society Interface, Justyna Niestrawska and the research team of TU Graz and Klinische Abteilung für Gefäßchirurgie, Universitätsklinik für Chirurgie and Diagnostik und Forschungsinstitut für Pathologie of the Medical University of Graz were awarded the Aorta Prize of the German Society of Vascular Surgery and Vascular Medicine.

The next significant differences became apparent under stress in the stretching device. ‘In the healthy media, the structuring collagen fibres are embedded in an elastic layer so that the aorta can expand without any problems. But in the course of disease, this layer is the first to be degraded, and the fibres lose their orientation. We saw more behaviours in the mechanical tests. With some samples, there was no resistance at the beginning but after some time the fibres very suddenly became completely stiff. In the case of other samples, the fibres were completely stiff right at the beginning. Under these conditions, of course, the risk of rupture to the artery wall strongly increases because the material cannot expand any more under increased pressure,’ explains Niestrawska.
Two pictures. The above one shoves clearly seperatable layers of green fibre. The second one shows green fibres in no structure at all.
The upper figure shows a healthy aortic wall with the three layers of intima, media and adventitia clearly visible from left to right. The second picture shows an already diseased aorta, whose layers grew together and are difficult to distinguish.
Additionally, small fat cells could be detected in the tissue in the diseased samples. ‘Our hypothesis is that these lipids are deposited from the outside of the wall to the inside, thus making it more fragile.’

Imaging techniques could show the course of the disease

Building on her basic research, Niestrawska would like to check her hypotheses in tests on living organisms in a next step. She has also got some ideas for a real application: ‘In our work we could find indications for a course of disease which could be recognised and observed by certain high-resolution imaging techniques.’ In any case she would like to continue research in her field and is already planning to submit a new project application after her doctoral thesis.

This project is anchored in the FoE ‘Human & Biotechnology’, one of five research foci of Graz University of Technology.
You can find more research news from this field in Planet research.


The paper ‘Microstructure and mechanics of healthy aneurysmatic abdominal aortas: experimental analysis and modelling’ was published in the Journal of the Royal Society Interface and can be looked at on the website of the Journal. 


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