Good sleep is essential for our physical and mental health. And yet, sleep problems are widespread. According to the latest Swiss Health Survey, around one-third of the population report suffering from sleep disorders. Women and young people aged 15 to 39 are particularly affected.
Milestone for forensic research
Although sleep loss is widespread, it has not previously been possible to measure it directly and objectively in bodily fluids. A research team from the Institute of Forensic Medicine and the Institute of Pharmacology and Toxicology at UZH has now investigated whether sleep deprivation can be detected through metabolic changes in saliva. “Our study provides the first direct biomarkers of sleep deprivation in saliva under realistic conditions – a milestone for forensic research,” says Thomas Kraemer, professor of forensic pharmacology and toxicology at the UZH Institute of Forensic Medicine.
For the study, the researchers examined 20 healthy young men who normally sleep seven to nine hours. The participants completed three experimental conditions in random order: one night without any sleep, four consecutive nights of six hours’ sleep, and a control condition with the usual eight hours of sleep. The team then analyzed participants’ saliva using high-resolution mass spectrometry and employed machine-learning methods to identify molecular patterns associated with acute sleep deprivation.
Ten biomarkers of sleep deprivation
“We found that acute sleep deprivation affects about 10% of all biomolecules in saliva. The challenge was to identify, among tens of thousands of molecules, those that reliably indicate fatigue. Using state-of-the-art technology, we succeeded in identifying 10 biomarkers that do exactly that,” says first author Michael Scholz. As part of his doctoral research, he investigated in depth how fatigue can be measured in the body.
Toward a rapid test
The project is now entering its next phase. In a large-scale international field study, the patented biomarker set will be validated under realistic conditions. The researchers will investigate whether the method can reliably detect sleep deprivation in a range of everyday situations involving shift work, alcohol, medications and other factors.
In the long term, this research could lead to the development of a rapid test that can be used on-site to objectively detect fatigue. “Such a test could improve road safety and enhance safety in work environments where attention and concentration are critical,” says Scholz.
References
Michael Scholz, Andrea E. Steuer, Akos Dobay, Hans-Peter Landolt and Thomas Kraemer. Leveraging the Metabolic Fingerprint of Sleep Deprivation and Sleep Restriction for Forensic Applications: A Machine Learning Study in Oral Fluid Metabolomics. J Proteome Res. 2026 May 6. DOI: 10.1021/acs.jproteome.5c01064
Contacts
Michael Scholz
Institute of Forensic Medicine
University of Zurich
+41 44 635 56 41
E-mail: michael.scholz@irm.uzh.ch
Prof. Dr. rer. nat. Thomas Kraemer
Institute of Forensic Medicine
University of Zurich
+41 44 635 56 41
E-mail: thomas.kraemer@irm.uzh.ch
Journal of Proteome Research
Experimental study
People
Leveraging the Metabolic Fingerprint of Sleep Deprivation and Sleep Restriction for Forensic Applications: A Machine Learning Study in Oral Fluid Metabolomics.
6-May-2026