Single-dose pharmacokinetics, pharmacodynamics and safety of AZD0837, a novel oral direct thrombin inhibitor, in young healthy male subjects.

OBJECTIVE: The novel oral anticoagulant AZD0837 is currently in clinical development for the prevention of stroke and systemic embolic events in patients with atrial fibrillation. AZD0837 is bioconverted to AR-H067637, a selective and reversible direct thrombin inhibitor. This first-time-in-man study (study code D1250C00001) investigated the safety, tolerability, pharmacokinetics (PK) and pharmacodynamics (PD) of AZD0837. METHODS: Healthy Caucasian male volunteers (n = 44, age 20 - 39 y) were enrolled into this study of single oral escalating doses of AZD0837 given in solution (15 - 750 mg, n = 4 per dose). PD was assessed by ex vivo measurements of activated partial thromboplastin time (APTT), ecarin coagulation time (ECT), thrombin time (TT) and thrombin generation in plasma. RESULTS: AZD0837 was rapidly absorbed, with a mean oral bioavailability of 22 - 52%, and bioconverted to the active form, AR-H067637. In fasting subjects, maximum plasma concentrations (Cmax) for AR-H067637 occurred approximately 1 h post-dosing and declined with a mean half-life of 9.3 h. The Cmax and area under the curve for AR-H067637 showed a low to moderate inter-individual variability of 16% and 28%, respectively, and exhibited a slight deviation from dose-proportionality. AZD0837 produced a dose-dependent prolongation of APTT, ECT and TT, and decreased maximum free thrombin activity. AZD0837 was generally well tolerated. CONCLUSIONS: AZD0837 single oral doses (15 - 750 mg) are well tolerated in healthy male subjects and exhibit favorable PK properties and reproducible effects on ex vivo coagulation time variables that support further clinical development.

Structure-microbicidal activity relationship of synthetic fragments derived from the antibacterial alpha-helix of human lactoferrin.

There is a need for new microbicidal agents with therapeutic potential due to antibiotic resistance in bacteria and fungi. In this study, the structure-microbicidal activity relationship of amino acid residues 14 to 31 (sequence 14-31) from the N-terminal end, corresponding to the antibacterial alpha-helix of human lactoferrin (LF), was investigated by downsizing, alanine scanning, and substitution of amino acids. Microbicidal analysis (99% killing) was performed by a microplate assay using Escherichia coli, Staphylococcus aureus, and Candida albicans as test organisms. Starting from the N-terminal end, downsizing of peptide sequence 14-31 showed that the peptide sequence 19-31 (KCFQWQRNMRKVR, HL9) was the optimal length for antimicrobial activity. Furthermore, HL9 bound to lipid A/lipopolysaccharide, as shown by neutralizing endotoxic activity in a Limulus assay. Alanine scanning of peptide sequence 20-31 showed that Cys20, Trp23, Arg28, Lys29, or Arg31 was important for expressing full killing activity, particularly against C. albicans. Substituting the neutral hydrophilic amino acids Gln24 and Asn26 for Lys and Ala (HLopt2), respectively, enhanced microbicidal activity significantly against all test organisms compared to the amino acids natural counterpart, also, in comparison with HL9, HLopt2 had more than 10-fold-stronger fungicidal activity. Furthermore, HLopt2 was less affected by metallic salts than HL9. The microbicidal activity of HLopt2 was slightly reduced only at pH 7.0, as tested in the pH range of 4.5 to 7.5. The results showed that the microbicidal activity of synthetic peptide sequences, based on the antimicrobial alpha-helix region of LF, can be significantly enhanced by optimizing the length and substitution of neutral amino acids at specific positions, thus suggesting a sequence lead with therapeutic potential.

The importance of the quality of water in Limulus Amebocyte Lysate tests.

Commercial pharmaceutical waters were evaluated regarding their interference in the chromogenic Limulus Amebocyte Lysate (LAL) test. Two of the four tested waters strongly inhibited the U.S. Reference Standard Endotoxin, while a Control Standard Endotoxin was less affected. The inhibitory effect could be mimiced by adding trace amounts of certain metal ions to a non-interfering water. In conclusion, the water used in the LAL test must be chosen with great care.

A new kinetic single-stage Limulus amoebocyte lysate method for the detection of endotoxin in water and plasma.

A convenient kinetic chromogenic Limulus amoebocyte lysate (LAL) method, based on components originally intended for a two-stage end-point method, has been developed. The components (LAL and chromogenic substrate) can be pooled and subsequently used in a single-stage kinetic procedure adapted to microplates. With the help of a kinetic software, it is possible to measure over the three log range 0.005-12 EU/ml in one test run--a range considerably wider than the range of the end-point procedure. A good linearity of the log-log standard curve, reflected by coefficients of regression between 0.997 and 1.0, is shown as well as a high-resolution (> 700 s) between the negative control and the lowest standard point. Moreover a good precision (C.V. < 10%) is obtained in both water and plasma, showing the usefulness of the method in different applications. Finally, a strong correlation (r = 0.95-0.99) to other LAL methods is demonstrated.