Relationship between central and peripheral fatty acids in humans.

BACKGROUND: In recent years the physiological and pathological importance of fatty acids in both the periphery and central nervous system (CNS) has become increasingly apparent. However surprisingly limited research has been conducted comparing the fatty acid composition of central and peripheral lipid stores. METHODS: The present study compared the distribution of polyunsaturated (PUFA), as well as specific saturated (SFA) and monounsaturated (MUFA) fatty acids in the whole blood and cerebrospinal fluid (CSF) of humans. Gas chromatography with flame ionization detection was used to determine the fatty acid profiles of twenty-eight matched CSF and whole blood samples. Multiple linear regression modeling, controlling for age, was used to identify significant relationships. RESULTS: A significant positive relationship was seen between whole blood total omega-3 fatty acids and the CSF omega-3 subfractions, docosapentaenoic acid (DPA) (P = 0.019) and docosahexaenoic acid (DHA) (P = 0.015). A direct association was also observed between the whole blood and CSF omega-6 PUFA, arachidonic acid (AA) (P = 0.045). Interestingly an inverse association between central and peripheral oleic acid was also found (P = 0.045). CONCLUSIONS: These findings indicate a relationship between central and peripheral fatty acids of varying degrees of unsaturation and chain length and support the view that some systemic fatty acids are likely to cross the human blood brain barrier (BBB) and thereby influence central fatty acid concentrations.

Effects of probenecid on brain-cerebrospinal fluid-blood distribution kinetics of E-Delta 2-valproic acid in rabbits.

E-Delta 2-valproic acid (E-Delta 2-VPA), a major active metabolite of VPA, has been proposed as an alternative to VPA because it is less hepatotoxic and is nonteratogenic. In rodents, VPA and E-Delta 2-VPA have a brain tissue/free plasma concentration ratio less than unity, which suggests rapid removal of the alkanoate anticonvulsants from the central nervous system. This study in rabbits employed a simultaneous iv infusion-ventriculocisternal (VC) perfusion technique to investigate the steady-state kinetics of E-Delta 2-VPA transport at the blood-brain barrier, the blood-cerebrospinal fluid (CSF) barrier, and the neural cell membrane. Probenecid (PBD) was coadministered to probe the mediation of transport by organic anion transporter(s). Rabbits in the control group (N = 6) received an iv infusion of E-Delta 2-VPA to achieve a steady-state plasma concentration of 50 to 60 microg/ml. Blood and cisternal outflow of mock CSF perfusate were continuously sampled. Midway through the experiment, the VC perfusate was switched to one containing [3H]E-Delta 2-VPA. At 225 min, the rabbits were sacrificed, and each brain was removed and dissected into ten regions. Rabbits in the PBD group (N = 9) received an iv infusion and VC perfusion as in the control group as well as concomitant iv infusion of the inhibitor. The mean steady-state VC extraction ratio for [3H]E-Delta 2-VPA did not differ between the control and PBD groups (63.7 +/- 8.3% vs. 60. 6 +/- 9.6%), indicating the lack of a significant PBD-sensitive transport at the choroidal epithelium. Coadministration of PBD elevated brain concentration of cold E-Delta 2-VPA in the absence of a significant change in total or free steady-state plasma concentration. Mean E-Delta 2-VPA brain tissue/free plasma concentration ratios in the various brain regions were 3.5- to 5.2-fold higher in PBD-treated animals than in the controls. Significant increases (3.0- to 4.5-fold) in the mean brain tissue/cisternal perfusate concentration ratios were also observed. Compartmental modeling of the steady-state distribution data suggested that clearance of E-Delta 2-VPA from the brain parenchyma is governed jointly by efflux transporters at the neural cell membrane and brain capillary endothelium. Moreover, PBD-induced elevation of E-Delta 2-VPA tissue concentrations is attributed primarily to inhibition of E-Delta 2-VPA efflux transport at the neural cell membrane, resulting in both intracellular trapping and greater tissue retention of E-Delta 2-VPA.