A common standard is inappropriate for determining the potency of ultra low molecular weight heparins such as semuloparin and bemiparin.

INTRODUCTION: Lower low-molecular-weight heparins are being developed to improve on the safety and efficacy of antithrombotic therapy. Semuloparin and bemiparin are two depolymerized heparins produced by distinct manufacturing processes. The objective of this investigation was to determine whether a common standard could be used to define their potency. MATERIALS AND METHODS: Activities were compared using typical clinical coagulation assays and pharmacological assays required for potency assessment. RESULTS: The activity of semuloparin and bemiparin was comparable in FXa-based assays (anti-FXa, Heptest). However, bemiparin produced a stronger effect in the aPTT, ACT and anti-thrombin assays. Assessment of the parallelism of the concentration-response curves indicated that bemiparin and semuloparin are not equivalent in terms of anti-FIIa activity. Bemiparin had a stronger inhibitory effect on thrombin induced platelet aggregation, and a stronger interaction with HIT antibodies. CONCLUSIONS: These data demonstrate that depolymerized heparins can exhibit a range of biologic activities making them unique agents. Pharmacopoeial parameters such as anti-IIa and anti-Xa potency and molecular weight are insufficient to characterize such agents.

Stabilization of rasburicase and physico-chemical characterization of the resulting injectable formulation.

Rasburicase (Fasturtec/Elitek) is a new generation of recombinant urate oxidase administred therapeutically by intravenous infusion for the prevention or treatment of hyperuricemia during chemotherapy. To ensure a long storage period, a freeze-dried formulation was developed to guarantee the molecular integrity and enzyme activity. Screening of potential excipients was the first stage of the preformulation study. The selection was based on stability results (rasburicase solution with excipient) obtained with the isoelectric focusing profiles and residual enzyme activity. The different excipients were classified as stabilising, neutral or destabilising. A stability study was then carried out on different freeze-dried formulations containing the usual bulking agents for freeze-drying, excipients with a high glass transition temperature or competitive enzyme inhibitors having a stabilising effect. A mannitol/alanine mixture in phosphate buffer was selected from these preliminary results. Finally, the optimal content of mannitol and alanine in the freeze-dried powder was determined by an experimental design study. The water content and the appearance of the "cake", the osmolality, pH, clarity, and enzyme activity of the reconstituted solution were assessed. The formula with a mannitol/alanine ratio of 0.7 was found to be the best composition. Differential scanning calorimetry and ThermoStimulated Current technique experiments were carried out to study the amorphous phase. A glass transition temperature of about 45-500 degrees C was found. Glassy state is known to preserve stability, which was verified by the real stability data. X-ray diffraction studies have shown that alanine is in a crystallised state and that mannitol remains amorphous. Crystallised excipients participate in forming the structure of the powder and therefore help to prevent any collapse. Amorphous mannitol creates a surrounding medium favourable to the stability of the protein.

A colorimetric 96-well microtiter plate assay for the determination of urate oxidase activity and its kinetic parameters.

Urate oxidase (E.C.1.7.3.3; uricase, urate oxygen oxidoreductase) is an enzyme of the purine breakdown pathway that catalyzes the oxidation of uric acid in the presence of oxygen to allantoin and hydrogen peroxide. A 96-well plate assay measurement of urate oxidase activity based on hydrogen peroxide quantitation was developed. The 96-well plate method included two steps: an incubation step for the urate oxidase reaction followed by a step in which the urate oxidase activity is stopped in the presence of 8-azaxanthine, a competitive inhibitor. Hydrogen peroxide is quantified during the second step by a horseradish peroxidase-dependent system. Under the defined conditions, uric acid, known as a radical scavenger, did not interfere with hydrogen peroxide quantification. The general advantages of such a colorimetric assay performed in microtiter plates, compared to other methods and in particular the classical UV method performed with cuvettes, are easy handling of large amounts of samples at the same time, the possibility of automation, and the need for less material. The method has been applied to the determination of the kinetic parameters of rasburicase, a recombinant therapeutic enzyme.

Modification of a reactive cysteine explains differences between rasburicase and Uricozyme, a natural Aspergillus flavus uricase.

Urate oxidase is used in humans for the control of uric acid in patients receiving chemotherapy. Rasburicase (Fasturtec/Elitek), a recombinant urate oxidase expressed in Saccharomyces cerevisiae, was compared with Uricozyme, the natural enzyme produced by Aspergillus flavus. Rasburicase has a higher purity as demonstrated by SDS/PAGE and chromatographic analysis and a better specific activity. The differences observed for Uricozyme are likely attributable to the previously used purification process, which modifies the enzyme. The production process of rasburicase, on the other hand, preserves the structure of the molecule. MS analysis shows that Uricozyme contains a cysteine adduct on Cys(103). In the crystal structure, the sulphur atom of the cysteine residue in position 103 is orientated to the external surface of the tetramer, whereas the sulphur atom of two other cysteine residues (Cys(35) and Cys(290)) is orientated to the centre of the canal formed by the tetramer. The same adduct is produced by simple incubation of the rasburicase with cysteine.