Currently living with congenital heart defects are about 25,000 Danes.
Currently living with congenital heart defects are about 25,000 Danes. It has been a mystery until know about how exactly the various risk factors influence the development of the heart during pregnancy though it is known that heredity and environment play a role for these malformations. With the aid of a supercomputer, an international, interdisciplinary research team has analysed millions of data points. This has allowed the scientists to show that a huge number of different risk factors – for example in the form of genetic defects – influence the molecular biology of heart development.
– The discovery of a biological common denominator among many thousands of risk factors is an important step in health research, which in time can improve the prevention and diagnosis of congenital heart defects, explains Professor Lars Allan Larsen from the Department of Cellular and Molecular Medicine, University of Copenhagen.
Research results have recently been published in the well reputed scientific journal PNAS – Proceedings of the National Academy of Sciences USA. The project was supported by the Danish Heart Association, Novo Nordisk Foundation and Danish National Research Foundation, among others.
Tailored treatment in future
Scientists have analysed several thousand genetic mutations and environmental risk factors associated with heart malformations in the hope of finding a pattern or common factor.
– Our investigations show that many different genetic factors together with environmental factors can influence the same biological system and cause disease. The results are also interesting in a broader perspective, because it is probable that similar interactions are also valid for diseases such as schizophrenia, autism, diabetes and cancer, says Kasper Lage, Director of Bioinformatics at Harvard University, USA.
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Complex pattern creation provides new knowledge
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– Systems biology is a relatively new and holistic research field that uses bioinformatics and supercomputers to investigate highly complex biological problems. For example, we know of a number of genetic mutations that cause heart defects – but it is first now we have been able to show which biological systems in the heart are influenced by the mutations in question, explains Professor Lars Allan Larsen.
The research approach of systems biology can lead to surprising and pioneering conclusions, but the work is difficult and requires a great degree of interdisciplinary collaboration. In this case team members include genetic scientists, cardiac specialists and experts in bioinformatics from universities, hospitals and industry.
FACT BOX:
What is this all about?
In brief, systems biology involves making complete descriptions of biological systems such as a cell, a bacterium or an ecological system. The holistic approach comprises not only mapping all of the components (genes, proteins etc.) in a biological system, but uncovering the functions of the components as well – and their mutual relationships.
Systems biology arose as a research area thanks to the sophisticated methods and techniques developed in particular in the fields of gene technology and molecular biology, and because modern information technology allows statistical calculations to be made on massive amounts of data.
Source-Eurekalert