A relationship between bruxism and orofacial-dystonia? A trigeminal electrophysiological approach in a case report of pineal cavernoma.

BACKGROUND: In some clinical cases, bruxism may be correlated to central nervous system hyperexcitability, suggesting that bruxism may represent a subclinical form of dystonia. To examine this hypothesis, we performed an electrophysiological evaluation of the excitability of the trigeminal nervous system in a patient affected by pineal cavernoma with pain symptoms in the orofacial region and pronounced bruxism. METHODS: Electrophysiological studies included bilateral electrical transcranial stimulation of the trigeminal roots, analysis of the jaw jerk reflex, recovery cycle of masseter inhibitory reflex, and a magnetic resonance imaging study of the brain. RESULTS: The neuromuscular responses of the left- and right-side bilateral trigeminal motor potentials showed a high degree of symmetry in latency (1.92 ms and 1.96 ms, respectively) and amplitude (11 mV and 11.4 mV, respectively), whereas the jaw jerk reflex amplitude of the right and left masseters was 5.1 mV and 8.9 mV, respectively. The test stimulus for the recovery cycle of masseter inhibitory reflex evoked both silent periods at an interstimulus interval of 150 ms. The duration of the second silent period evoked by the test stimulus was 61 ms and 54 ms on the right and left masseters, respectively, which was greater than that evoked by the conditioning stimulus (39 ms and 35 ms, respectively). CONCLUSIONS: We found evidence of activation and peripheral sensitization of the nociceptive fibers, the primary and secondary nociceptive neurons in the central nervous system, and the endogenous pain control systems (including both the inhibitory and facilitatory processes), in the tested subject. These data suggest that bruxism and central orofacial pain can coexist, but are two independent symptoms, which may explain why numerous experimental and clinical studies fail to reach unequivocal conclusions.

Primary motor cortex hyperexcitability in Fabry's disease.

OBJECTIVE: Involvement of pyramidal cells and/or changes in excitability of brain areas remote from an ischemic stroke has been demonstrated. Since in Fabry disease (FD), specific cerebrovascular lesions are present, we thought to investigate motor cortex excitability, using transcranial magnetic stimulation. METHODS: Resting (RMT) and active (AMT) motor threshold, input-output curve (IN-OUT), central motor conduction time (CMCT), cortical silent period (cSP), short and long interval intracortical inhibition (SICI and LICI), intracortical facilitation (ICF), short interval intracortical facilitation (SICF) and short afferent inhibition (SAI) were measured in the cortical representation of the right first dorsal interosseous muscle in 11 patients with FD and 11 sex- and age matched healthy subjects. RESULTS: FD patients showed a significant increase of steepness in IN-OUT, ICF and SICF curves. RMT, AMT, CMCT, SICI, LICI and SAI were normal. CONCLUSIONS: Our data documented an increased activity of motor cortex glutamatergic excitatory circuits in FD, evident also in patients without brain MRI lesions. Following enzyme replacement treatment, this abnormality was partly reversed. SIGNIFICANCE: We suggest that our findings are expression of subtle "biochemical brain lesions", due to an early involvement of neurons and/or astrocytes by the cascade of pathologic events leading to brain damage in FD.