Motor cortex fatigue in sports measured by transcranial magnetic double stimulation.

PURPOSE: Besides peripheral mechanisms, central fatigue is an important factor limiting the performance of exhausting exercise in sport. The mechanisms responsible are still in discussion. Using noninvasive transcranial magnetic stimulation (TMS) in a double-pulse technique, we sought to assess fatigue of the motor cortex after exhaustive anaerobic strain. METHODS: 23 male subjects (22-52 yr) taking part in the study were requested to accomplish as many pull-ups as possible until exhaustion. The amount of physical lifting work was recorded. Before and immediately after the task, intracortical inhibition (ICI) and facilitation (ICF) were measured by a conditioned-test double-pulse TMS method for the right brachioradialis (BR) and abductor pollicis brevis muscle (APB). RESULTS: After exercise, ICF was significantly reduced in the BR but not in the APB. ICI was not altered. Changes tended to normalize within 8 min after the task. The amount of lifting work accomplished showed significant correlation to the values of ICF reduction (r = 0.73). Moreover, the baseline values of ICF before exercise were also significantly correlated to the lifting work (r = 0.63). CONCLUSIONS: Because double-pulse TMS gives access to the motor cortex independently of spinal or peripheral mechanisms, reduced ICF reflects decreased excitability of interneuronal circuits within the motor cortex. We suggest that ICF measures motor cortex fatigue after exhausting strain specifically for the muscles performing the task. Gamma-aminobutyric acid (GABA)-ergic neurotransmission is possibly involved in the mechanisms mediating central fatigue. Double-pulse TMS may be a useful tool in the control of training in sports as well as in the detection of pathological central fatigue in overreaching and in the prevention of overtraining.

Boxing and running lead to a rise in serum levels of S-100B protein.

Permanent neurological dysfunction is the primary medical concern of boxing. Recently it was reported that patients presenting elevated levels of the glial protein S-100B in serum after minor head injuries are more prone to develop neuropsychological deficits than patients with lower levels of S-100B protein. We assessed this protein before and after amateur boxing competitions (n = 10) and sparring bouts (n = 15). In several control groups, we investigated S-100B levels of participants before and after a 25 km race (n = 11), jogging (10 km, n = 12), short-term running (n = 12), and heading footballs (n = 12). There was an increase in S-100B protein after boxing and the running disciplines but not after ergometer cycling or soft heading of footballs. The increase in S-100B protein concentrations due to competitive boxing and after the 25 km race was significantly higher than that after performing other disciplines (p < 0.001). There was no significant difference between the increases caused by sparring and the running disciplines (p = 0.21). The number and severity of the strikes to the head correlated significantly with the increase in the S-100B protein levels. Levels of S-100B protein known to be associated with neuropsychological deficits were not reached in our study. In professional boxing, much higher levels are to be expected and would be worthy of investigation.

Central fatigue in sports and daily exercises. A magnetic stimulation study.

Previous transcranial magnetic stimulation (TMS) studies showed exercise-induced depression of motor evoked potentials (MEP). The purpose of the present study was to evaluate changes in MEP size and central motor conduction time (CMCT) after various kinds of exercise of daily life and sports. Changes of both central and peripheral motor conduction were recorded immediately after predominantly aerobic (climbing stairs and jogging) and anaerobic (press-ups, dumb-bell holding, and 400 m-run) exercise. Strength exercise resulted in a significant decrease of MEP amplitudes. Exhausting press-ups reduced the mean MEP amplitude by 33% as compared to pre-exercise value, exhausting dumb-bell holding reduced the mean MEP amplitude by 66%. Aerobic exercises (climbing 600 steps and jogging 50 minutes) did not significantly change MEP amplitudes. The compound motor action potentials (registered after supramaximal peripheral electrical stimulation) remained unchanged after each paradigm. CMCT was not significantly altered by any of the exercises under investigation. Peripheral motor conduction time (PMCT) was slightly lengthened by 4% after isometric dumb-bell holding. PMCT and total motor conduction time were decreased after aerobic exercises, probably due to an increase of temperature of the lower extremities. In conclusion, TMS is a suitable technique for objective evaluation of central fatigue. The present study is the first to show its possible use in sports medicine, indicating that only exhaustive or strength exercises result in reduced MEPs.