AI Article Synopsis
- The study introduces a new method that allows healthcare professionals to use sound to detect neonatal seizures through EEG analysis, making interactions with AI decision support more intuitive.
- Traditional EEG interpretation requires specialized expertise, which is often unavailable; this method enables faster analysis—turning an hour of data into just five seconds—while maintaining accuracy comparable to experienced neurophysiologists.
- By combining AI algorithms with human-centered approaches, the method allows less experienced healthcare providers to better understand seizure events through sound, demonstrating improved performance when AI is used alongside medical professionals.
Article Abstract
The study proposes a novel method to empower healthcare professionals to interact and leverage AI decision support in an intuitive manner using auditory senses. The method's suitability is assessed through acoustic detection of the presence of neonatal seizures in electroencephalography (EEG). Neurophysiologists use EEG recordings to identify seizures visually. However, neurophysiological expertise is expensive and not available 24/7, even in tertiary hospitals. Other neonatal and pediatric medical professionals (nurses, doctors, etc.) can make erroneous interpretations of highly complex EEG signals. While artificial intelligence (AI) has been widely used to provide objective decision support for EEG analysis, AI decisions are not always explainable. This work developed a solution to combine AI algorithms with a human-centric intuitive EEG interpretation method. Specifically, EEG is converted to sound using an AI-driven attention mechanism. The perceptual characteristics of seizure events can be heard using this method, and an hour of EEG can be analysed in five seconds. A survey that has been conducted among targeted end-users on a publicly available dataset has demonstrated that not only does it drastically reduce the burden of reviewing the EEG data, but also the obtained accuracy is on par with experienced neurophysiologists trained to interpret neonatal EEG. It is also shown that the proposed communion of a medical professional and AI outperforms AI alone by empowering the human with little or no experience to leverage AI attention mechanisms to enhance the perceptual characteristics of seizure events.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC9243143 | PMC |
| http://dx.doi.org/10.1038/s41598-022-14894-4 | DOI Listing |
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