An electrophysiological study of the mechanism of fatigue in multiple sclerosis

Abstract

Fatigue is a common and disabling symptom in multiple sclerosis but is poorly understood. We investigated 'physiological' fatigue in 21 patients with multiple sclerosis who complained of disabling fatigue by measuring the decline in strength during a 45 s maximal contraction of the adductor pollicis muscle. The results were compared with those from a control group of 19 healthy subjects. The strength of control subjects declined by approximately 20% during the contraction; twitch interpolation showed central drive remained almost maximal throughout, and therefore that the fatigue was peripheral in origin. Patients had normal baseline strength, but developed greater fatigue (approximately 45%), which was central in origin. In both cases, the decline in strength followed a roughly linear time course suggesting that the patients, like the normals, were trying to maintain a maximum voluntary effort. Evidence for frequency-dependent conduction block (FDCB) in the patients' central motor pathways was sought by measuring the EMG responses to single and paired transcranial magnetic stimuli. Fatigue had no effect on the latency or size of EMG responses to transcranial magnetic stimulation, suggesting that FDCB was unlikely to have occurred. This was supported by measurements of the maximum speed of voluntary muscle contraction; although the patients showed relatively slow speeds before exercise, the decline in speed after fatigue was no greater than in normal subjects. We conclude that excessive 'physiological' fatigue contributes to the symptom of fatigue in multiple sclerosis and is central in origin. However, since the degree of exercise-induced fatigue did not correlate with the baseline complaint of fatigue, other factors must also be operating to produce the full range of clinical symptoms. We found no conclusive evidence that central fatigue is related to increased dysfunction in the primary central motor pathways and no evidence that FDCB is the pathophysiological mechanism. We postulate that central fatigue in multiple sclerosis is due to impaired drive to the primary motor cortex and several lines of evidence strongly suggest that this is not due to a lack of motivation.