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Attractor Limited system state that pulls nearby system states into this stable basic state,
e.g. health (immune system can cope with slight infections or pulse, returns to normal after
exertion; however, if the disturbances are too great, then the stable system state changes
and one becomes ill; again a new attractor that can last longer until one becomes
healthy again).
Babbage Test Test for artificial intelligence in which outside people are asked to distin
guish between a human and a computer (both undercover). If the computer succeeds in
deceiving people into thinking it is human, then the computer has artificial intelligence.
Big Data Refers to the flood of large amounts of data generated in the course of modern
experimental methods, which, for example, have to be analysed bioinformatically in order
to gain new and exciting insights.
BiNGO Cytoscape plugin that identifies overrepresented biological functions (with
p-value and corresponding genes) using Gene Ontology grouping in a network (see also
Gene Ontology, GO).
Bioinformatics Bioinformatics, or computational biology, is the study of biological
questions using computers. In this process, information (“data”) and findings (“models”)
about organisms are collected (in databases), analysed (by experts, the bioinformaticians,
who use various computer programs for these analyses) and reproduced in models (“simu
lations”). Essential properties (system properties) for the biological phenomenon under
investigation are worked out (“systems biology”). Biologists often focus on plants and
animals, fungi or lower organisms (bacteria, viruses). The latter are easier to understand
and thus to reproduce in the computer, e.g. the metabolism of bacteria or the reproduction
of viruses. For doctors, other medical professions (human geneticists, molecular physi
cians) and many interested biologists, however, the focus is on humans. Both health
(“physiology”) and disease are described in detail. The starting point of many bioinfor
matic studies is the flow of genetic information from DNA (the genome) through tran
scription (in higher cells in the cell nucleus) to RNA and after translation in the ribosome
via the genetic code to proteins. Programs and software are used to study biological func
tion. This is done, for example, by means of sequence analyses in order to obtain informa
tion about a pathogen, but also, for example, to obtain differences between the organisms
involved (e.g. humans and parasites) by genome comparisons. In the case of proteins, but
also regulatory and catalytic RNA, the analysis of the structure helps to better decipher
their function (protein structure analysis, RNA analysis). It is also possible to create meta
bolic networks and compare them with each other, and finally, for example, to calculate
drugs for important proteins in the parasite that optimally block the parasitic protein but
are tolerated by humans. Signalling networks can also be modelled and studied to better
understand cell maturation (differentiation, embryology) and to better combat or prevent
diseases such as cancer, heart failure and stroke (together over 75% of all causes of death).
Predictions are verified with the help of experimental data. In the meantime, other mole
cules can also be measured intensively (more complex), such as metabolites (e.g. lipids,
sugars, vitamins, cofactors), proteins, nucleotides. Also new is an increasing amount of
18 Glossary