Pain is a highly subjective and variable phenomenon. Different persons perceive objectively identical nociceptive stimuli differently. Moreover, the same person may perceive objectively identical stimuli differently in different situations, or even from one moment to another. In the brain, the processing of pain is associated with different neuronal responses originating from an extended network of brain areas. These responses include evoked activity as well as neuronal oscillations at alpha (8-13 Hz), beta (14-30 Hz) and gamma (30-100 Hz) frequencies. All these responses covary with moment-to-moment variations of pain within subjects (intra-subject variability). However, only the gamma response correlates with variations of pain between subjects (inter-subject variability). To date, it has remained unknown whether these relationships remain stable and reproducible across longer periods of time (inter-session-variability). Thus, the current project aims to systematically characterize how different pain-associated brain responses encode intra-individual, inter-individual, and inter-session variations of pain perception. To this end, the investigators will record pain-associated brain responses of 155 healthy participants at two different points in time. Each time, short painful stimuli will be applied to the participants' hand and they will be asked to verbally rate the perceived pain intensity, while pain-associated brain responses will be recorded using electroencephalography (EEG). This will allow to investigate the relationships between pain-associated brain responses and intra-individual and inter-individual variations of pain and to compare these measures and their relationships between sessions. In order to quantify the influence of demographic and psychological factors, i.e. age, mood and sleep quality / quantity on pain variability, established questionnaires will be used. In order to compare the functional significance of brain responses to other pain-associated neuronal responses, pain-associated responses of the autonomic system will be recorded and related to pain variability. Results of the project promise to elucidate the neuronal mechanisms underlying intra-individual, inter-individual and inter-session variability of pain. Such knowledge provides the basis for the development of a biomarker for pain, which might reasonably complement the self-assessment of pain. Moreover, as pain perception and objective stimulation tend to dissociate in pathological pain, the current project promises insights into the neuronal mechanisms of chronic pain.
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Verbal pain rating (NRS; 0: 'no pain' to 100: 'maximal tolerable pain')
Timeframe: During procedure (15 min experimental paradigm in each session)
Pain-associated brain responses
Timeframe: During procedure (15 min experimental paradigm in each session)