News Release

A new EEG shows how brain tracts are formed

Finnish researchers break ground in neonatal brain research

Peer-Reviewed Publication

University of Helsinki

In the past few years, researchers at the University of Helsinki have made several breakthroughs in discovering how the brain of preterm babies work, in developing treatments to protect the brain, and in developing research methods suitable for hospital use.

Each year, the brains of hundreds of Finnish children, and therefore their future lives, are at risk due to premature birth or intrapartum asphyxia. The brain is a sensitive organ, and merely keeping the baby alive is not enough to save the brain. The latest scientific achievements offer significant improvements in the brain health and lives of infants.

"When developing brain treatment, a key challenge is to find ways to study and monitor the well-being of the brain in the neonatal intensive care unit environment," says Sampsa Vanhatalo, Docent of Pediatric Clinical Neurophysiology.

The R & D work carried out in the basic neurobiology laboratory in the University of Helsinki has provided a whole new level of insight into the electrical activity of the brain in newborns. Now we know that many previously unexplained brain events seen in an EEG are essential for the development and maturation of the brain in premature babies, Dr. Vanhatalo states.

These findings have provided an opportunity to develop monitoring devices to monitor the well-being of infant brains during ICU treatment. The University of Helsinki and the Neonatal Intensive Care Unit of the Children's Hospital, Helsinki University Central Hospital (HUCH) have attracted considerable international attention for their novel EEG techniques that enable exceptionally precise measurement of EEG in premature infants.

"These dense array EEG caps and the related full-band EEG (FbEEG) that we have developed have disclosed crucial forms of newborn brain activity that have so far been overlooked. We have also developed a method to study sensory functions of premature babies when the tracts are still in the process of forming in the brain and the yield of a traditional neurological examination is still negligible," explains Dr. Vanhatalo.

The research work carried out in Helsinki has been adapted elsewhere in the world with exceptional speed: the largest device manufacturers are already offering FbEEG devices, and dense array EEG caps are already being manufactured industrially. These devices have been clinically approved in the EU (CE certificate) and in the USA (FDA).

"Multi-modal EEG analysis of newborns may help us to recognize the children in need of immediate care or neurological rehabilitation early on, as preterm babies. Today, often the diagnosis cannot be made until the child is a toddler. It is critical for the development and quality of a child's life that appropriate treatment and rehabilitation is started as soon as possible," says Dr. Vanhatalo.

In the Journal of Visualized Experiments (JoVE), Finnish researchers demonstrate the developed method and show how it can be applied safely and without disturbing other treatments in an NICU. JoVE is the only scientific journal in the world that publishes all its articles in both text and video format.

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Researchers at the HUCH Children's Hospital are participating in the European Union funded NEMO project (www.nemo-europe.com). The aim of the project is to develop a treatment for epileptic seizures in newborn babies. In relation to this project, Dr. Vanhatalo's research team has developed several ways to measure EEG in full-term neonates. In connection with the project, a multimedia package has also been produced for international use to teach NICUs several different ways to record neonatal EEG and to show how problems can be solved to ensure high quality of EEG recordings.


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