Manganese Distribution across the Blood-Brain Barrier. I. Evidence for Carrier-Mediated Influx of Managanese Citrate as well as Manganese and Manganese Transferrin

Manganese (Mn) is an essential element and a neurotoxicant. Regulation of Mn movement across the blood–brain barrier (BBB) contributes to whether the brain Mn concentration is functional or toxic. In plasma, Mn associates with water, small molecular weight ligands and proteins. Mn speciation may influence the kinetics of its movement through the BBB. In the present work, the brain influx rates of 54Mn2+, 54Mn citrate and 54Mn transferrin (54Mn Tf) were determined using the in situ brain perfusion technique. The influx rates were compared to their predicted diffusion rates, which were determined from their octanol/aqueous partitioning coefficients and molecular weights. The in situ brain perfusion fluid contained 54Mn2+, 54Mn citrate or 54Mn Tf and a vascular volume/extracellular space marker, 14C-sucrose, which did not appreciably cross the BBB during these short experiments (15–180 s). The influx transfer coefficient (Kin) was determined from four perfusion durations for each Mn species in nine brain regions and the lateral ventricular choroid plexus. The brain Kin was (5–13)×10−5, (3–51)×10−5, and (2–13)×10−5 ml/s/g for 54Mn2+, 54Mn citrate, and 54Mn Tf, respectively. Brain Kin values for any one of the three Mn species generally did not significantly differ among the nine brain regions and the choroid plexus. However, the brain Kin for Mn citrate was greater than Mn2+ and Mn Tf Kin values in a number of brain regions. When compared to calculated diffusion rates, brain Kin values suggest carrier-mediated brain influx of 54Mn2+, 54Mn citrate and 54Mn Tf. 55Mn citrate inhibited 54Mn citrate uptake, and 55Mn2+ inhibited 54Mn2+ uptake, supporting the conclusion of carrier-mediated brain Mn influx. The greater Kin values for Mn citrate than Mn2+ and its presence as a major non-protein-bound Mn species in blood plasma suggest Mn citrate may be a major Mn species entering the brain

The effect of single-dose tramadol on oxycodone clearance.

We have noticed increased prescribing of tramadol by emergency physicians for breakthrough pain in patients chronically taking oxycodone. Both oxycodone and tramadol undergo oxidative metabolism by CYP2D6 and CYP3A4, suggesting the possibility that tramadol may compete with oxycodone for metabolism. A randomized controlled trial in 10 human volunteers was performed to determine if single-dose tramadol therapy would impair oxycodone clearance. Subjects were randomized whether to enter the control or experimental arm of the study first, with each subject serving as his or her own control. In the control arm, each subject received 10 mg immediate-release oxycodone orally and had serial plasma oxycodone and oxymorphone concentrations measured over 8 h. The experimental arm was identical except that 100 mg tramadol was ingested 1.5 h before oxycodone. Clearance divided by fraction absorbed (CL/f) was calculated using the dose and the area under the 8-h time-plasma oxycodone concentration curve. Peak plasma oxycodone concentrations (C(max)) and time until peak oxycodone concentrations (T(max)) were secondary outcome parameters. Group size was chosen to produce a power of 0.8 to detect a 20% difference in CL/f between study arms. Values for CL/f, C(max), and T(max) were compared between study arms using two-tailed, paired t-tests. No statistically significant difference between groups was demonstrated for any parameter. We failed to demonstrate that single doses of tramadol impaired oxycodone clearance

A Simple and Rapid Genotyping Assay for Simultaneous Detection of Two ADRB2 Allelic Variants Using Fluorescence Resonance Energy Transfer Probes and Melting Curve Analysis

Allelic variants at codons 16 and 27 of the β2-adrenergic receptor gene (ADRB2) have shown clinical and pharmacological implications in asthma, hypertension, ischemic heart failure, diabetes, obesity, and cystic fibrosis. We have developed a simultaneous genotyping assay for the c.46A>G and c.79C>G allelic variants using hybridization probes and melting curve analysis. The assay was optimized on a panel of 30 DNA samples of known ADRB2 genotype as determined by sequencing with 100% concordance between the two techniques. Melting temperature (Tm) ranges for the different genotypes were obtained using data from three independent experiments. Single peaks for p.Arg16Arg (Tm = 57.76°C ± 0.10°C) and p.Gly16Gly (Tm = 66.73°C ± 0.18°C) and two melting peaks for p.Arg16Gly were obtained. Similarly, single peaks for p.Gln27Gln (Tm = 53.98°C ± 0.19°C) and p.Glu27Glu (Tm = 64.93°C ± 0.16°C) and two peaks for p.Gln27Glu were detected. Independent operators easily assigned genotypes in a sample set of 385 asthmatic patients. Haplotype and allele frequencies were in concordance with previously published data: Arg allele frequencies in children/adults were 0.34/0.30 in Caucasians and 0.45/0.52 in African Americans, and Gln allele frequencies were 0.58/0.52 in Caucasians and 0.82/0.84 in African Americans. Thus, the ADRB2 genotyping assay represents a highly reliable and rapid technique for routine clinical use in the simultaneous detection of ADRB2 variants