RT Journal Article
SR Electronic
T1 Quantitative assessment of blood-brain barrier damage during microdialysis.
JF Journal of Pharmacology and Experimental Therapeutics
JO J Pharmacol Exp Ther
FD American Society for Pharmacology and Experimental Therapeutics
SP 1167
OP 1176
VO 277
IS 2
A1 M E Morgan
A1 D Singhal
A1 B D Anderson
YR 1996
UL http://jpet.aspetjournals.org/content/277/2/1167.abstract
AB In view of the increasing use of microdialysis for monitoring drug uptake into the brain, the consequences of tissue/blood-brain barrier (BBB) damage that occurs on microdialysis probe insertion on the extent and rate of solute uptake need to be more carefully examined. In this study, both microdialysis and a classic method were used to compare the apparent brain uptake of two polar permeants, [3H]sucrose and [14C]urea. The blood-to-brain transfer constants of these compounds differ significantly, with the value of urea exceeding that of sucrose by a factor of approximately 20 when compared by the classic one-point-per-animal method. The BBB selectivity to these nonmetabolized permeants as assessed by microdialysis provides a sensitive measure of the integrity of the BBB to polar nonelectrolytes within the molecular size range of most drugs. The following evidence for blood-brain barrier damage during microdialysis sampling was obtained: (1) the loss of [3H]sucrose from the extracellular fluid in brain on termination of an intravenous infusion is biphasic, with the initial phase evident immediately on termination by the infusion, suggesting that a fraction of the microdialysis probe resides in a region in rapid equilibrium with plasma; (2) complete loss of selectivity in the rate constants for CNS entry of sucrose vs. urea and (3) there were substantially higher area under the concentration vs. time curve AUCECF/AUCplasma ratios for both sucrose and urea generated by microdialysis than the corresponding ratios (AUCCSF/AUCplasma or AUCbrain/AUCplasma) obtained by classic methods. These results suggest that the BBB to small molecule transport likely remains compromised for some time after microdialysis probe insertion.