Carina Sander1, Fenja Modes2, Hans-Peter Schlake3, Paul Eling4, Helmut Hildebrandt5. 1. Institute of Psychology, Carl von Ossietzy University of Oldenburg, Department VI - Medicine and Health Sciences, Ammerländer Heerstr. 114-11826129, Oldenburg, Germany; Median Klinik Wilhelmshaven, Department of Neurology, Bremer Straße 2, 26382 Wilhelmshaven, Germany. Electronic address: carina.sander@uni-oldenburg.de. 2. Institute of Psychology, Carl von Ossietzy University of Oldenburg, Department VI - Medicine and Health Sciences, Ammerländer Heerstr. 114-11826129, Oldenburg, Germany. Electronic address: fenja.modes@gmx.de. 3. Median Klinik Wilhelmshaven, Department of Neurology, Bremer Straße 2, 26382 Wilhelmshaven, Germany. Electronic address: HPSchlake@t-online.de. 4. Donders Institute for Brain, Cognition and Behavior, Radboud University Nijmegen, Montessorilaan 3, 6525 HR, Nijmegen, Netherlands. Electronic address: p.eling@donders.ru.nl. 5. Institute of Psychology, Carl von Ossietzy University of Oldenburg, Department VI - Medicine and Health Sciences, Ammerländer Heerstr. 114-11826129, Oldenburg, Germany; Klinikum Bremen-Ost, Department of Neurology, Züricher Str. 40, 28325 Bremen, Germany. Electronic address: helmut.hildebrandt@uni-oldenburg.de.
Abstract
BACKGROUND: Causes of fatigue in Multiple Sclerosis remain elusive. Recently, we developed a model linking cognitive fatigue to inflammatory processes based on a neuroinflammatory reflex-arc instantiated by the vagus nerve. The relation between experienced autonomic dysfunctions, based on vagal processing, and cognitive fatigue is well-known, but an examination of the association of objectively measured vagal activity and cognitive fatigue is missing. An attempt was made to collect behavioral and physiological evidence that can be associated with experienced autonomic dysfunctions and fatigue in Multiple Sclerosis patients. METHODS: Behavioral performance (response bias) and autonomic functioning (Heart rate variability and Skin conductance level) during an acoustic vigilance task were investigated in 53 Multiple Sclerosis patients. We assessed trait fatigue (independent from task), and time-on-task related increase of fatigue. Regression analysis was used to predict the fatigue status with physiological and behavioral scores. RESULTS: Response bias, indicating a reduced responsiveness, and high and very low frequency components of Heart rate variability, indicating an increased parasympathetic activity, contribute to the regression of trait fatigue. Reduced Heart rate variability (SDNN) and increased parasympathetic activity (pNN50) remained in the regression model predicting time-on-task fatigue. CONCLUSION: Cognitive fatigue in MS is related to parasympathetic activity and reduced responsiveness, supporting our model representing fatigue as inflammatory processes in the brain. Standardized subjective and objective autonomous dysfunction measures might be considered as additional assessments in MS.
BACKGROUND: Causes of fatigue in Multiple Sclerosis remain elusive. Recently, we developed a model linking cognitive fatigue to inflammatory processes based on a neuroinflammatory reflex-arc instantiated by the vagus nerve. The relation between experienced autonomic dysfunctions, based on vagal processing, and cognitive fatigue is well-known, but an examination of the association of objectively measured vagal activity and cognitive fatigue is missing. An attempt was made to collect behavioral and physiological evidence that can be associated with experienced autonomic dysfunctions and fatigue in Multiple Sclerosispatients. METHODS: Behavioral performance (response bias) and autonomic functioning (Heart rate variability and Skin conductance level) during an acoustic vigilance task were investigated in 53 Multiple Sclerosispatients. We assessed trait fatigue (independent from task), and time-on-task related increase of fatigue. Regression analysis was used to predict the fatigue status with physiological and behavioral scores. RESULTS: Response bias, indicating a reduced responsiveness, and high and very low frequency components of Heart rate variability, indicating an increased parasympathetic activity, contribute to the regression of trait fatigue. Reduced Heart rate variability (SDNN) and increased parasympathetic activity (pNN50) remained in the regression model predicting time-on-task fatigue. CONCLUSION:Cognitive fatigue in MS is related to parasympathetic activity and reduced responsiveness, supporting our model representing fatigue as inflammatory processes in the brain. Standardized subjective and objective autonomous dysfunction measures might be considered as additional assessments in MS.
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