Sodium-dependent transport of sugars and iodide from the cerebral venticles of the rabbit.

1. The objective was to discover whether the extraction of sugars and iodide from the perfused cerebral ventricles is Na(+)-dependent.2. In the ventriculo-aqueductal and ventriculo-cisternal perfusion systems in the rabbit the extraction of (14)C-labelled D-hexoses (glucose, 3-O-methyl-glucose, alpha-methyl-glucoside and galactose), (131)I(-) and (24)Na was inhibited when 82% of the Na(+) in the perfusion fluid was replaced by choline. The extraction returned to control levels when the Na(+) concentration in the perfusion fluid was returned to normal.3. Ouabain, 5 x 10(-5)M in the perfusion fluid inhibited the extraction of the above (14)C sugars and (131)I(-), but hardly affected that of [(3)H]2-deoxy-D-glucose. It enhanced the extraction of (24)Na. C.s.f. production was usually totally inhibited.4. The extraction of [(14)C]urea remained unchanged during perfusion with low Na(+) fluid or ouabain.5. Recovery from brain of [(14)C]3-O-methyl-glucose, [(3)H]2-deoxy-glucose and (131)I(-) was low while recovery of [(14)C]alpha-methyl-glucoside and (24)Na was high. On an equal weight basis recovery of [(14)C]3-O-methyl-glucose was about twelve times higher from the choroid plexus than from the brain.6. Part of the movement of (14)C sugars may be explained on basis of a Na(+)-gradient hypothesis with involvement of the Na(+) pump at the blood-c.s.f. or blood-brain barriers.7. The rate of c.s.f. production from the first three ventricles comprised about 40% of the rate from all four ventricles. The extraction of sugars, urea and cations was similar in both perfusion systems while the extraction of (131)I(-) was higher in the ventriculo-cisternal system than in the ventriculo-aqueductal system.