The Olivary Hypothesis of Essential Tremor: Time to Lay this Model to Rest?

Essential tremor (ET) is among the more prevalent neurological disorders, yet prevalence estimates have varied enormously, making it difficult to establish prevalence with precision. We: (1) reviewed the worldwide prevalence of ET in population-based epidemiological studies, (2) derived as precisely as possible an estimate of disease prevalence, and (3) examined trends and important differences across studies. We identified 28 population-based prevalence studies (19 countries). In a meta-analysis, pooled prevalence (all ages) = 0.9%, with statistically significant heterogeneity across studies (I(2) = 99%, P or= 65 years) = 4.6%, and in additional descriptive analyses, median crude prevalence (age >or= 60-65) = 6.3%. In one study of those age >or= 95 years, crude prevalence = 21.7%. Several studies reported ethnic differences in prevalence, although more studies are needed. Greater than one-third of studies show a gender difference, with most demonstrating a higher prevalence among men. This possible gender preference is interesting given clinical, epidemiological, and pathological associations between ET and Parkinson's disease. Precise prevalence estimates such as those we provide are important because they form the numerical basis for planned public health initiatives, provide data on the background occurrence of disease for family studies, and offer clues about the existence of environmental or underlying biological factors of possible mechanistic importance. (c) 2010 Movement Disorder Society.

The oscillatory properties of the membrane potential in inferior olivary neurones were studied in guinea-pig brain-stem slices maintained in vitro. Intracellular double-ramp current injection at frequencies of 1-20 Hz revealed that inferior olivary neurones tend to fire at two preferred frequencies: 3-6 Hz when the cells were actively depolarized (resting potential less than -50 mV), and 9-12 Hz when they were actively hyperpolarized (resting potential more than -75 mV). In 10% of the experiments spontaneous subthreshold oscillations of the membrane potential were observed. These oscillations, which resembled sinusoidal wave forms and had a frequency of 4-6 Hz and an amplitude of 5-10 mV, occurred synchronously in all cells tested within the slice. These oscillations persisted in the presence of 10(-4) M-tetrodotoxin and were blocked by Ca2+ conductance blockers or by the removal of Ca2+ from the bathing solution. The oscillations were affected by gross extracellular stimulation of the slice but not by intracellular activation of any given neurone. The data indicate that these oscillations reflect the properties of neuronal ensembles comprised of a large number of coupled elements. Similar ensemble oscillation could be induced, in most experiments, by adding harmaline (0.1 mg/ml) and serotonin (10(-4) M) to the bath and could be blocked by bath addition of noradrenaline. Harmaline was found to increase cell excitability by hyperpolarizing the neurones and shifting the inactivation curve for the somatic Ca2+ spike to a more positive membrane potential level. The role inferior olivary oscillations play in the organization of motor coordination is discussed.