Researchers at the University of Helsinki and Helsinki University Hospital (HUH), Finland, have developed software based on machine learning, which can independently interpret EEG signals from a premature infant and generate an estimate of the brain’s functional maturity.
The method is the first EEG-based brain maturity evaluation system in the world. It is more precise than other currently understood methods of evaluating the development of an infant’s brain and enables the automatic and objective monitoring of a premature infant’s brain development.
"We currently track the development of an infant's weight, height and head circumference with growth charts. EEG monitoring combined with automatic analysis provides a practical tool for the monitoring of the neurological development of preterm infants and generates information which will help plan the best possible care for the individual child," said Professor Sampsa Vanhatalo from the University of Helsinki, who led the research, "This method gives us a first-time opportunity to track the most crucial development of a preterm infant, the functional maturation of the brain, both during and after intensive care."
One in 10 live births is a premature one and approximately half of all the patients in neonatal intensive care are there because of preterm births. Late pregnancy is a time of rapid brain development for the fetus. The brain’s electrical activity changes almost every week. The brain must function in order to develop correctly.
The health impediments associated with preterm birth can hinder brain development. Researchers found in the 1980s that early health problems in preterm infants also resulted in slower brain development during the first months. In order to provide the best possible care and develop new forms of treatment, we should know how the brain functions of infants develop but no objective and sufficiently precise methods for evaluating the early-stage maturity of the brain have been available.
The most tempting option for evaluating the maturation of the brain is to use EEG sensors placed on the scalp. This is a non-invasive, low-cost and risk-free method which has been popular in the past few years in monitoring brain activity at neonatal intensive care units.
"The practical problem with EEG monitoring is that analyzing the EEG data has been slow and required special expertise from the doctor performing it. This problem may be solved reliably and globally by using automatic analysis as part of the EEG device," said Vanhatalo.
The new EEG analysis software was primarily developed by Nathan Stevenson, an Australian engineer from Professor Vanhatalo’s research group as an EU-funded Marie Curie Fellow. The research uses an extensive and well-controlled set of EEG measurement data from preterm infants.
The analysis software is based on machine learning. A large amount of EEG data on preterm infants was fed into a computer and the software calculated hundreds of computational features from each measurement without intervention from a doctor. With the help of a support vector machine algorithm, these features were combined to generate a reliable estimate of the EEG maturational age of the infant.
At the end of the study, the software was tested by comparing EEG maturational age estimated by the software with the clinically known true age of the infant. In more than 80 percent of the cases, the true age of the infant and the computer-generated estimate were within two weeks of one another. The maturation estimate was so reliable and precise that each of the 39 preterm infants in the study, the functional development of the brain could be tracked when the measurements were repeated every few weeks.
A paper on this research was published in Scientific Reports.