Molecular mass determination of low-molecular-mass heparins. Application of wide collection angle measurements of light scattering using a high-performance gel permeation chromatographic system equipped with a low-angle laser light-scattering photometer

Molecular weight determination of low molecular weight hyaluronic acid and chondroitin sulfate by gel permeation chromatography

Low molecular weight (LWM) hyaluronic acid (HA) and chondroitin sulfate (CS) have a wide range of applications. To determine their molecular weight (MW), we developed a gel permeation chromatography (GPC) method, which is calibrated based on serrated peaks in the chromatograms. MW calibrants were obtained from the enzymolysis of HA and CS using hyaluronidase. The identical structure of calibrants and samples ensured the soundness of the method. The highest confidence MWs were up to 14,454 and 14,605 for HA and CS, respectively, and the standard curves showed very high correlation coefficients. Thanks to the changeless relationship between MW and its contribution to the GPC integral, the second calibration curves could be derived via one GPC column, also embodied correlation coefficients of >0.9999. The discrepancies of MW values were minuscule, and the measurement of a sample could be conducted in <30 min. The accuracy of the method was verified using LWM heparins, and the measured Mw values showed a 1.2 %-2.0 % error relative to pharmacopeia results. The MW results obtained for LWM-HA and LWM-CS samples were also consistent with the results obtained by multiangle laser light scattering. The method was also verified be able to measure the very low MWs.

Determination of the molecular weight of low-molecular-weight heparins by using high-pressure size exclusion chromatography on line with a triple detector array and conventional methods

The evaluation of weight average molecular weight (Mw) and molecular weight distribution represents one of the most controversial aspects concerning the characterization of low molecular weight heparins (LMWHs). As the most commonly used method for the measurement of such parameters is high performance size exclusion chromatography (HP-SEC), the soundness of results mainly depends on the appropriate calibration of the chromatographic columns used. With the aim of meeting the requirement of proper Mw standards for LMWHs, in the present work the determination of molecular weight parameters (Mw and Mn) by HP-SEC combined with a triple detector array (TDA) was performed. The HP-SEC/TDA technique permits the evaluation of polymeric samples by exploiting the combined and simultaneous action of three on-line detectors: light scattering detectors (LALLS/RALLS); refractometer and viscometer. Three commercial LMWH samples, enoxaparin, tinzaparin and dalteparin, a γ-ray depolymerized heparin (γ-Hep) and its chromatographic fractions, and a synthetic pentasaccharide were analysed by HP-SEC/TDA. The same samples were analysed also with a conventional HP-SEC method employing refractive index (RI) and UV detectors and two different chromatographic column set, silica gel and polymeric gel columns. In both chromatographic systems, two different calibration curves were built up by using (i) γ-Hep chromatographic fractions and the corresponding Mw parameters obtained via HP-SEC/TDA; (ii) the whole γ-Hep preparation with broad Mw dispersion and the corresponding cumulative distribution function calculated via HP-SEC/TDA. In addition, also a chromatographic column calibration according to European Pharmacopoeia indication was built up. By comparing all the obtained results, some important differences among Mw and size distribution values of the three LMWHs were found with the five different calibration methods and with HP-SEC/TDA method. In particular, the detection of the lower molecular weight components turned out to be the most critical aspect. Whereas HP-SEC/TDA may underestimate species under 2 KDa when present in low concentration, other methods appeared to emphasize their content.

Low-molecular-weight heparins: differential characterization/physical characterization

Low-molecular-weight heparins (LMWHs), derived from unfractionated heparin (UFH) through different depolymerization processes, have advantages with respect to the parent heparin in terms of pharmacokinetics, convenience of administration, and reduced side effects. Each LMWH can be considered as an independent drug with its own activity profile, placing significance on their biophysical characterization, which will also enable a better understanding of their structure-function relationship. Several chemical and physical methods, some involving sample modification, are now available and are reviewed.

Some potentialities and drawbacks of contemporary size-exclusion chromatography

The present state of the chromatographic techniques based on differentiation of solutes according to their molecular sizes is briefly surveyed. Attention is centred on high-performance techniques applied to purification and characterization of natural macromolecules, and on discussion of the chromatographic approaches to the determination of the molecular masses and molecular mass distributions of both natural and synthetic polymers. The basic requirements on the selection of the separation system and the experimental conditions are summarized, demonstrated on a few examples and critically evaluated.

Isoamyl nitrite depolymerized heparin as a universal calibrator for heparins and low molecular weight heparins

Because the subcutaneous absorption of heparin depends on its molecular weight, high performance size exclusion chromatography methods, among others, have been developed for its determination. Because heparin consists of polymer chains of varying lengths, a large number of calibrators, 19 in our work, are required for these molecular weight analyses. Because the preparation of that many calibrants is both time-consuming and expensive, other methods requiring fewer calibrants are being sought. In pursuit of these aims, a heparinase-degraded heparin has been accepted as the first international reference preparation low molecular weight heparin for molecular weight calibration. We have previously proposed another calibrant, the Heparin Mass Calibrator. In this article, we introduce another calibrant, called the Heparin Molecular Mass Calibrant. It offers the advantage of a much wider availability because it is a commercial product. In addition to having a superior refractive index chromatography run profile, when used in combination with two Narrow Range Calibrators with molecular weights of 34.4 and 18.4 kDa, this new calibrant covers both the higher and the lower molecular weight ranges. Besides, ultraviolet detection is not needed for molecular weight calculations. Therefore, it is proposed that its feasibility as a universal reference calibrator for both heparins and low molecular weight heparins be considered.

Preparation and characterization of 'heparinocytes': erythrocytes with covalently bound low molecular weight heparin

In an attempt to create the possibility of stable, long acting, intravascular anticoagulation, low molecular weight heparin was modified by introducing a sulfhydryl group into the molecule (LMWH-SH). Human erythrocytes were covalently grafted with LMWH-SH by the use of a heterobifunctional coupling reagent which reacts with the SH group of LMWH-SH and surface exposed amino groups of erythrocytes now called 'heparinocytes' (HC). HC were morphologically indistinguishable from untreated erythrocytes and displayed identical osmotic resistance. The functionality of HC was analyzed by classical coagulation tests in which they dose dependently inhibited clot formation. HC were also functional in recalcified whole blood inhibiting thrombin formation as assessed by the cleavage of the chromogenic substrate S-2238. The system appears applicable as a potential autologous, long-term anticoagulant treatment or prophylaxis.

Absolute molecular weight distribution of low-molecular-weight heparins by size-exclusion chromatography with multiangle laser light scattering detection

The absolute molecular weight (M(r)) distribution of seven low-molecular-weight (LMW) heparin products was determined by size-exclusion chromatography (SEC) coupled with multiangle laser light scattering (MALLS) detection. The SEC/MALLS technique does not rely on relative M(r) standards for column calibration and yields absolute M(r) estimates directly from the angular dependence of scattered light intensity as a function of concentration, as formulated by light scattering theory. The SEC/MALLS method we describe is rapid, precise, and accurate. In 1 h it yields results from triplicate injections that agree well with the manufacturers' own independent analyses and that exhibit coefficients of variation of approximately 1%. By eliminating the requirement for finite quantities of highly purified, well-characterized M(r) standards derived from heparin, the present procedure represents a clear improvement over relative methods of M(r) determination. Thus, it is concluded that the SEC/MALLS method is ideally suited to routine quality control of commercial LMW-heparin products.

Carbohydrate chromatography: towards yoctomole sensitivity

In attempting to analyse complex carbohydrates by HPLC or capillary electrophoresis (CE) the chromatographer is faced with many challenges. The diversity of oligosaccharide structures described the date and their poor resolution on many chromatographic systems present a significant challenge to the chromatographer. In addition to this, the non-chromogenic nature of most carbohydrates greatly decreases the sensitivity of UV detection and refractive index is not an option for sensitive analysis. Over the last five years there have been significant advances in separation and detection methods for carbohydrates, and in this paper we will attempt to describe the most significant advances and highlight potential future developments. The detection of 200-300 fmol (2-3 x 10(-3) mol) of oligosaccharides can now be readily achieved using electrochemical detection or fluorescence detection (after labelling) with conventional HPLC columns and detectors. Miniaturized separation systems have greatly increased sensitivities with a CE-laser induced fluorescence instrument detecting as little as 100 yoctomoles (1 x 10(-22) mol).