Language is the most important tool for human communication and essential for life in our society. “Despite a great deal of neuroscientific research on the representation of language, little is known about the organisation of language in the human brain. Much of what we do know comes from single studies with small numbers of subjects and has not been confirmed in follow-up studies,” says Dr Sabrina Turker from the Max Planck Institute for Human Cognitive and Brain Sciences in Leipzig. This meta-analysis aims to help change that.
Based on more than 400 neuroscientific experiments using functional imaging and involving more than 7000 subjects, the analysis provides in-depth insights into how the brain organises language. A quantitative, coordinate-based meta-analysis was used to integrate the many findings from different studies in the most complete and objective way possible. This makes it possible to see where the brain is activated when particular language processes occur. This approach provides insights into fundamental principles of how the brain organises language processing. The researchers not only studied language as a process in general, but also explicitly addressed subordinate processes: the meaning of language at the level of words and sentences (semantics); the phonetic structure of language (phonology); grammar and the arrangement of linguistic elements (syntax); and the phonetic structure of language at sentence level, including melody, intonation and rhythm (prosody).
In addition to the classical language regions in the left hemisphere of the brain, the authors of the study found that structures in the brain regions below the cerebral cortex and the cerebellum play a key role in language processes.
“These regions have been rather neglected in previous neuroscientific research on language,” says Gesa Hartwigsen, Professor of Cognitive and Biological Psychology at Leipzig University. “In particular, the left and right cerebellum are involved in processes related to the meaning of language and the processing of sounds. Similarly, phonetic patterns that transcend individual words and also convey emotional meaning are associated with activation in the right amygdala, a paired core area of the brain.” She points out that this part influences emotion and memory.
Professor Gesa Hartwigsen adds: “Our findings may serve future studies involving language recovery after brain injury, for example caused by stroke. And they could help to refine models of language processing.”