Just a few fibres are enough for the two hemispheres of the brain to communicate with each other. This was shown by a new international study led by Professor Dr Michael Miller (University of California, Santa Barbara) and Professor Dr Lukas J. Volz (Department of Neurology at University Hospital Cologne and the University of Cologne's Faculty of Medicine) in close collaboration with Professor Dr Christian Bien's team at the Bethel Epilepsy Centre (University Hospital OWL at Bielefeld University). The results were published in the journal Proceedings of the National Academy of Sciences (PNAS) and underline the human brain's amazing ability to reorganize – even when the most important connection between the hemispheres, the corpus callosum, is partially severed.
Until recently, damage to the corpus callosum – the brain's largest fiber bundle – has been associated with impairments in speech, motor functions, or perception. However, the new study with so-called 'split-brain' patients shows that preserving around one centimetre of the corpus callosum's fibres is enough to largely maintain the exchange of information between the two brain hemispheres and thus prevent neurological symptoms.
Using functional magnetic resonance imaging (fMRI), the research team investigated how partial or complete transections of the corpus callosum affected neural synchronisation. While a complete transection largely prevented information exchange between the hemispheres, communication remained almost normal in patients with few residual connections.
These findings challenge long-held assumptions about the relationships between brain structure and function. "Our results underline the immense adaptability of the functional architecture of the human brain," explains Prof Volz. "Even a few fibres between the cerebral hemispheres appear to be sufficient to maintain a complex network architecture."
These findings offer valuable insights for rehabilitation research after brain injur with targeted therapeutic interventions aiming to exploit the brain's neuroplastic potential to facilitate the reorganization of impaired networks.
The study was carried out in close collaboration between the University Hospital Cologne and the University of Cologne's Faculty of Medicine, the Bethel Epilepsy Centre (University Hospital OWL, Bielefeld University), the University of California, Santa Barbara, and Indiana University Bloomington. The Cologne team was funded by the German Research Foundation (DFG) as part of Collaborative Research Centre 1451 "Key Mechanisms of Motor Control in Health and Disease".
