Prevalence of acute neurology: a 2-week snapshot in a district general hospital.

Neurological illnesses are a common cause of hospital admissions, yet most patients are not primarily managed by neurologists. Acute neurology service provision varies across the UK. This study aimed to establish the number of neurological admissions during a 2-week period in a district general hospital, as well as the proportion of those patients who were seen by the hyperacute neurology team. This was done by analysing the diagnostic codes. It was established that there was a total of 2,242 admissions during the study period and, of those, 491 (22%) had neurological codes. Analysis of the 491 hospital electronic records revealed that 229 (10%) were truly neurologically relevant and, of those, 14% of patients received an opinion from the neurology team. Therefore, it can be concluded that only a small proportion of acute neurology is currently being seen by neurologists.

Diuretic-sensitive electroneutral Na+ movement and temperature effects on central axons.

KEY POINTS: Optic nerve axons get less excitable with warming. F-fibre latency does not shorten at temperatures above 30°C. Action potential amplitude falls when the Na+ -pump is blocked, an effect speeded by warming. Diuretics reduce the rate of action potential fall in the presence of ouabain. Our data are consistent with electroneutral entry of Na+ occurring in axons and contributing to setting the resting potential. ABSTRACT: Raising the temperature of optic nerve from room temperature to near physiological has effects on the threshold, refractoriness and superexcitability of the shortest latency (fast, F) nerve fibres, consistent with hyperpolarization. The temperature dependence of peak impulse latency was weakened at temperatures above 30°C suggesting a temperature-sensitive process that slows impulse propagation. The amplitude of the supramaximal compound action potential gets larger on warming, whereas in the presence of bumetanide and amiloride (blockers of electroneutral Na+ movement), the action potential amplitude consistently falls. This suggests a warming-induced hyperpolarization that is reduced by blocking electroneutral Na+ movement. In the presence of ouabain, the action potential collapses. This collapse is speeded by warming, and exposure to bumetanide and amiloride slows the temperature-dependent amplitude decline, consistent with a warming-induced increase in electroneutral Na+ entry. Blocking electroneutral Na+ movement is predicted to be useful in the treatment of temperature-dependent symptoms under conditions with reduced safety factor (Uhthoff's phenomenon) and provide a route to neuroprotection.