Methane hydrate emergence from Lake Baikal: direct observations, modelling, and hydrate footprints in seasonal ice cover.

This paper provides a novel report of methane hydrates rising from bottom sediments to the surface of Lake Baikal, validated by photo and video records. The ascent of hydrates in the water column was confirmed by hydroacoustic data showing rising objects with velocities significantly exceeding the typical speeds (18-25 cm s-1) of gas bubbles. Mathematical modelling along with velocity and depth estimates of the presumed methane hydrates coincided with values observed from echograms. Modelling results also showed that a methane hydrate fragment with initial radius of 2.5 cm or greater could reach the surface of Lake Baikal given summer water column temperature conditions. Results further show that while methane bubbles released from the deep sedimentary reservoir would dissolve in the Lake Baikal water column, transport in hydrate form is not only viable but may represent a previously overlooked source of surface methane with subsequent emissions to the atmosphere. Methane hydrates captured within the ice cover may also cause the formation of unique ice structures and morphologies observed around Lake Baikal. Sampling of these ice structures detected methane content that exceeded concentrations measured in surrounding ice and from the atmosphere demonstrating a link with the methane transport processes described here.

Fibrin formation and proteolysis during ancrod treatment. Evidence for des-A-profibrin formation and thrombin independent factor XIII activity.

Ancrod is a purified fraction of venom from the Malayan pit viper Calloselasma rhodostoma, containing a serine protease that cleaves fibrinopeptides A from fibrinogen. We report on a study that involved intravenous and subcutaneous application of ancrod in healthy subjects in which it was shown that ancrod induces the formation of desAA-fibrin complexes that are partially crosslinked by factor XIII proenzyme, and act as cofactor in tPA induced plasminogen activation. The plasmin generated degrades fibrin, as well as fibrinogen, leading to the appearance of large amounts of fibrinogen and fibrin degradation products in the circulation, including fragment D-dimer. At low concentrations of ancrod, formation of desAA-fibrin is preceded by production of desA-profibrin, lacking only one fibrinopeptide A.

Plasminogen activation without changes in tPA and PAI-1 in response to subcutaneous administration of ancrod.

Ancrod is a purified fraction of venom from the Malayan pit viper, Calloselasma rhodostoma, currently under investigation for treatment of ischemic stroke. The therapeutic effect is ascribed to a lowering of plasma fibrinogen. Thirty-two healthy volunteers received subcutaneous ancrod at doses of 1.0, 1.5 and 2.0 IU/kg body weight or placebo. Blood samples were drawn before the injection and at various time points until 96 h after the injection. Ancrod leads to the formation of desAA-fibrin, which serves as cofactor in tissue plasminogen activator activity (tPA)-induced plasminogen activation. Unchanged concentrations of prothrombin fragment F1.2 and thrombin-antithrombin complex (TAT) indicate that fibrin formation occurs independent of thrombin. Plasmin generation is independent of an increase in tPA activity or changes in plasminogen activator inhibitor-1 (PAI-1) concentration in plasma. Subcutaneous injection of ancrod leads to a generalized fibrino(geno)lytic response caused solely by providing tPA with soluble fibrin as its cofactor in plasminogen activation. Maximal plasmin activity is present 12 h after subcutaneous injection.

Analysis of fibrin formation and proteolysis during intravenous administration of ancrod.

Ancrod is a purified fraction of venom from the Malayan pit viper, Calloselasma rhodostoma, currently under investigation for treatment of acute ischemic stroke. Treatment with ancrod leads to fibrinogen depletion. The present study investigated the mechanisms leading to the reduction of plasma fibrinogen concentration. Twelve healthy volunteers received an intravenous infusion of 0.17 U/kg body weight of ancrod for 6 hours. Blood samples were drawn and analyzed before and at various time points until 72 hours after start of infusion. Ancrod releases fibrinopeptide A from fibrinogen, leading to the formation of desAA-fibrin monomer. In addition, a considerable proportion of desA-profibrin is formed. Production of desA-profibrin is highest at low concentrations of ancrod, whereas desA-profibrin is rapidly converted to desAA-fibrin at higher concentrations of ancrod. Both desA-profibrin and desAA-fibrin monomers form fibrin complexes. A certain proportion of complexes carries exposed fibrin polymerization sites E(A), indicating that the terminal component of the protofibril is a desAA-fibrin monomer unit. Soluble fibrin complexes potentiate tissue-type plasminogen activator-induced plasminogen activation. Significant amounts of plasmin are formed when soluble fibrin in plasma reaches a threshold concentration, leading to the proteolytic degradation of fibrinogen and fibrin. In the present setting, high concentrations of soluble fibrin are detected after 1 hour of ancrod infusion, whereas a rise in fibrinogen and fibrin degradation products, and plasmin-alpha(2)-plasmin inhibitor complex levels is first detected after 2 hours of ancrod infusion. Ancrod treatment also results in the appearance of cross-inked fibrin degradation product D-dimer in plasma. (Blood. 2000;96:2793-2802)

Chronopharmacology of intravenous and oral modified release verapamil.

AIMS: Using a stable isotope technique which allows simultaneous and differential measuring of orally and intravenously administered drugs we compared the pharmacokinetics and pharmacodynamics of unlabelled modified release verapamil p.o. (steady state) and deuterated verapamil i.v. (single dose) following morning and evening administration. METHODS: Twelve female and 12 male healthy volunteers were studied in a randomized, crossover design. During the last day of each treatment period (day 6 and day 10) pharmacokinetics and pharmacodynamics (PR interval) of verapamil were assessed; 1 h before ingestion of a new R/S-verapamil 240 mg modified release formulation (08.00 h vs 20.00 h) a single dose of 10 mg d7-R/S-verapamil was administered intravenously. Serum levels of unlabelled and labelled R/S-verapamil were measured by gas chromatography/mass spectrometry. In selected samples of serum which were chosen at tmin,po and tmax,po the enantiomers were separated by chiral high-performance liquid chromatography in order to calculate R- to S-verapamil serum concentration ratios. RESULTS: We observed no significant differences in pharmacokinetics (AUCpo, Cmax, tmax, CLo, F and R/S enantiomer ratio) between morning and evening treatment with modified release verapamil and there was no influence of time of dosing on mean prolongation of PR interval. AUCiv, CL, Vss and d7-R/d7-S enantiomer ratio following verapamil i.v. did not show circadian variation. t1/2 was slightly but statistically significantly increased after the morning infusion. PR-prolongation was significantly greater after verapamil i.v. in the morning than in the evening. The 90% confidence intervals of the differences between morning and evening administration in AUCpo, Cmax and AUCiv were within the equivalence range of 0.8-1.25. CONCLUSIONS: Time of dosing has no significant influence on pharmacokinetics and pharmacodynamics of this new modified release formulation of verapamil. Circadian variation in presystemic metabolism of verapamil was not observed.

Role of cytochrome P4502D6 in the metabolism of brofaromine. A new selective MAO-A inhibitor.

The metabolic fate of brofaromine (CGP 11 305 A), a new, reversible, selective MAO-A inhibitor, has been assessed in poor (PM) and extensive (EM) metabolizers of debrisoquine. Compared to EM, PM had significantly longer t1/2 (136%) and larger AUC(0-infinity) (110%) of the parent compound brofaromine and a lower Cmax (69%) and AUC (0-72 h) (40%) of its O-desmethyl metabolite. The mean metabolite/substrate ratio (based on urine excretion) was about 6-times greater in EM than in PM. Treatment with quinidine converted all EM into phenocopies of PM. All pharmacokinetic parameters of brofaromine and O-desmethyl-brofaromine in EM treated with quinidine were similar to those of untreated PM, including the metabolite/substrate ratio. Quinidine treatment of PM did not alter the pharmacokinetics of brofaromine or of its metabolite, nor the metabolite/substrate ratio. The results indicate a role for the debrisoquine type of oxidation polymorphism in the O-demethylation and pharmacokinetics of brofaromine.