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Brain delivery buffers

T. Murakami, E. Shek, E. Pop, N. Bodor, Improved Anticonvulsant Activity of Pheny-toin by a Redox Brain Delivery System II Stability in Buffers and Biological Materials ,. /. Pharm. Sci. 1989, 78,132-131. [Pg.549]

Sodium uptake assay. Assays using mouse brain synaptosomes were performed as described previously (6., ), except that insecticides were introduced to resuspended synaptosomes in 0.2-0.4 yl of ethanol rather than as a residue in the incubation tube. This amount of ethanol improved the delivery of insecticides, thereby increasing the reproducibility of the assay, and had no measurable effect on veratridine-dependent sodium channel activation. These methods were also used for assays with fish brain membranes, except that all buffers were augmented with sucrose to give osmolarities equivalent to the 0 7 M sucrose used for membrane isolation. [Pg.256]

Figure 2.3 IgG levels after administration of drug delivery systems in rats. Controlled-delivery systems for antibody class IgG. The insert figures show the release of antibody from the delivery system during incubation in buffered saline. The panel (a) inset shows release from poly(lactic acid) microspheres these spherical particles were 10-100/rm in diameter. The panel (b) inset shows release from a poly[ethylene-co-(vinyl acetate)] matrix these disk-shaped matrices were 1 cm in diameter and 1 mm thick. In both cases, molecules of IgG were dispersed throughout the solid polymer phase. Although the amount of IgG released during the initial 1-2 days is greater for the matrix, the delivery systems have released comparable amounts after day 5. (a) Comparison of plasma IgG levels after direct injection of IgG (open circles) or subcutaneous injection of the IgG-releasing polymeric microspheres characterized in the inset (filled circles). The delivery system produces sustained IgG concentrations in the blood [3]. (b) Comparison of plasma IgG levels after direct intracranial injection of IgG (open squares) or implantation of an IgG-releasing matrix (filled squares) [4]. The influence of the delivery is less dramatic in this situation, probably because the rate of IgG movement from the brain into the plasma controls the kinetics of the overall process. Figure 2.3 IgG levels after administration of drug delivery systems in rats. Controlled-delivery systems for antibody class IgG. The insert figures show the release of antibody from the delivery system during incubation in buffered saline. The panel (a) inset shows release from poly(lactic acid) microspheres these spherical particles were 10-100/rm in diameter. The panel (b) inset shows release from a poly[ethylene-co-(vinyl acetate)] matrix these disk-shaped matrices were 1 cm in diameter and 1 mm thick. In both cases, molecules of IgG were dispersed throughout the solid polymer phase. Although the amount of IgG released during the initial 1-2 days is greater for the matrix, the delivery systems have released comparable amounts after day 5. (a) Comparison of plasma IgG levels after direct injection of IgG (open circles) or subcutaneous injection of the IgG-releasing polymeric microspheres characterized in the inset (filled circles). The delivery system produces sustained IgG concentrations in the blood [3]. (b) Comparison of plasma IgG levels after direct intracranial injection of IgG (open squares) or implantation of an IgG-releasing matrix (filled squares) [4]. The influence of the delivery is less dramatic in this situation, probably because the rate of IgG movement from the brain into the plasma controls the kinetics of the overall process.
See other pages where Brain delivery buffers is mentioned: [Pg.449]    [Pg.33]    [Pg.40]    [Pg.730]    [Pg.730]    [Pg.290]    [Pg.1477]    [Pg.440]    [Pg.254]    [Pg.91]    [Pg.171]    [Pg.485]    [Pg.35]    [Pg.267]    [Pg.289]   
See also in sourсe #XX -- [ Pg.3317 ]



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