Monitoring the purity of pharmaceutical heparin preparations by high-field 1H-nuclear magnetic resonance spectroscopy

Polymeric nano-shielded islets with heparin-polyethylene glycol in a non-human primate model

Intraportal pancreatic islet transplantation incurs huge cell losses during its early stages due to instant blood-mediated inflammatory reactions (IBMIRs), which may also drive regulation of the adaptive immune system. Therefore, a method that evades IBMIR will improve clinical islet transplantation. We used a layer-by-layer approach to shield non-human primate (NHP) islets with polyethylene glycol (nano-shielded islets, NSIs) and polyethylene glycol plus heparin (heparin nano-shielded islets; HNSIs). Islets ranging from 10,000 to 20,000 IEQ/kg body weight were transplanted into 19 cynomolgus monkeys (n = 4, control; n = 5, NSI; and n = 10, HNSI). The mean C-peptide positive graft survival times were 68.5, 64 and 108 days for the control, NSI and HNSI groups, respectively (P = 0.012). HNSI also reduced the factors responsible for IBMIR in vitro. Based on these data, HNSIs in conjunction with clinically established immunosuppressive drug regimens will result in superior outcomes compared to those achieved with the current protocol for clinical islet transplantation.

The US regulatory and pharmacopeia response to the global heparin contamination crisis

The contamination of the widely used lifesaving anticoagulant drug heparin in 2007 has drawn renewed attention to the challenges that are associated with the characterization, quality control and standardization of complex biological medicines from natural sources. Heparin is a linear, highly sulfated polysaccharide consisting of alternating glucosamine and uronic acid monosaccharide residues. Heparin has been used successfully as an injectable antithrombotic medicine since the 1930s, and its isolation from animal sources (primarily porcine intestine) as well as its manufacturing processes have not changed substantially since its introduction. The 2007 heparin contamination crisis resulted in several deaths in the United States and hundreds of adverse reactions worldwide, revealing the vulnerability of a complex global supply chain to sophisticated adulteration. This Perspective discusses how the US Food and Drug Administration (FDA), the United States Pharmacopeial Convention (USP) and international stakeholders collaborated to redefine quality expectations for heparin, thus making an important natural product better controlled and less susceptible to economically motivated adulteration.

Pharmacology of Heparin and Related Drugs

Heparin has been recognized as a valuable anticoagulant and antithrombotic for several decades and is still widely used in clinical practice for a variety of indications. The anticoagulant activity of heparin is mainly attributable to the action of a specific pentasaccharide sequence that acts in concert with antithrombin, a plasma coagulation factor inhibitor. This observation has led to the development of synthetic heparin mimetics for clinical use. However, it is increasingly recognized that heparin has many other pharmacological properties, including but not limited to antiviral, anti-inflammatory, and antimetastatic actions. Many of these activities are independent of its anticoagulant activity, although the mechanisms of these other activities are currently less well defined. Nonetheless, heparin is being exploited for clinical uses beyond anticoagulation and developed for a wide range of clinical disorders. This article provides a "state of the art" review of our current understanding of the pharmacology of heparin and related drugs and an overview of the status of development of such drugs.

A KISS (keep it simple, sensor) array for glycosaminoglycans

We demonstrate that it is possible to design a sensor array with one unique receptor and indicator, allowing not only the blind identification of pure GAGs with a level of accuracy of 100%, but also the differentiation of mixtures.

Pharmaceutical impurities and degradation products: uses and applications of NMR techniques

Current standards and regulations demand the pharmaceutical industry not only to produce highly pure drug substances, but to achieve a thorough understanding of the impurities accompanying their manufactured drug substances and products. These challenges have become important goals of process chemistry and have steadily stimulated the search of impurities after accelerated or forced degradation procedures. As a result, impurity profiling is one of the most attractive, active and relevant fields of modern pharmaceutical analysis. This activity includes the identification, structural elucidation and quantitative determination of impurities and degradation products in bulk drugs and their pharmaceutical formulations. Nuclear magnetic resonance (NMR) spectroscopy has evolved into an irreplaceable approach for pharmaceutical quality assessment, currently playing a critical role in unequivocal structure identification as well as structural confirmation (qualitative detection), enabling the understanding of the underlying mechanisms of the formation of process and/or degradation impurities. NMR is able to provide qualitative information without the need of standards of the unknown compounds and multiple components can be quantified in a complex sample without previous separation. When coupled to separative techniques, the resulting hyphenated methodologies enhance the analytical power of this spectroscopy to previously unknown levels. As a result, and by enabling the implementation of rational decisions regarding the identity and level of impurities, NMR contributes to the goal of making better and safer medicines. Herein are discussed the applications of NMR spectroscopy and its hyphenated derivate techniques to the study of a wide range pharmaceutical impurities. Details on the advantages and disadvantages of the methodology and well as specific challenges with regards to the different analytical problems are also presented.

Affinity chromatography, two-dimensional electrophoresis, adapted immunodepletion and mass spectrometry used for detection of porcine and piscine heparin-binding human plasma proteins

Heparin-binding proteins in human plasma were studied using affinity chromatography columns with porcine (2mL, 10.7mg capacity) and piscine heparin (5mL, 2.7mg capacity). Two-dimensional electrophoresis (Bio-Rad Protean II gel system with 16cm×16cm gels using isoelectric focusing (IEF) and nonequilibrium pH-gradient gel electrophoresis (NEPHGE)), Bruker Ultraflex MALDI-TOF mass spectrometry and immunoblotting (NovaBlot semidry discontinuous blotting) were used for unfractionated plasma. This revealed electropherograms with differences between porcine and piscine heparin-binding and totally 17 different fibrinogen variants from all 3 chains. Immunodepletion was used to remove fibrinogen (42.1mg anti-human fibrinogen in 8.4mL resin) and serum albumin (0.42mg binding capacity in 14mL resin) and porcine and piscine heparin-binding proteins were identified using liquid chromatography-mass spectrometry (Ultimate 3000 NanoLC with Acclaim PepMap 100 column (50cm×75μm)-LTQ Orbitrap Mass XL). In total, the binding of 76 putative or acknowledged biomarkers are shown. Of the identified proteins, 14 are not previously shown to be heparin-binding, such as the low concentration proteins lipocalin-1 and tropomyosin and a hitherto not detected protein in plasma, zinc finger protein 483. The putative heparin-binding sequences were analyzed. The results suggest that the combination of group specific affinity and adapted immunodepletion chromatography could be useful in the study of the plasma proteome.

Non-covalent synthesis of metal oxide nanoparticle-heparin hybrid systems: a new approach to bioactive nanoparticles

Heparin has been conjugated to Fe3O4, Co3O4, and NiO nanoparticles (NPs) through electrostatic interactions, producing colloidal suspensions of hybrid metal oxide heparin NPs that are stable in water. Negative zeta potentials and retention of heparin's ability to capture toluidine blue indicate that heparin's negative charges are exposed on the surface of the coated NPs. IR results confirmed the formation of nanohybrids as did NMR experiments, which were also interpreted on the basis of toluidine blue tests. Transmission electron microscopy results revealed that the heparin coating does not modify the shape or dimension of the NPs. Dynamic light scattering and negative zeta potential measurements confirmed that heparin surface functionalisation is an effective strategy to prevent NP aggregation.

Review: Contaminants in Heparin: Review of the Literature, Molecular Profiling, and Clinical Implications

Background: The contaminant isolated from contaminated heparin was oversulfated chondroitin sulfate (OSCS). Other possible contaminants should be evaluated. Methods: Contaminants were isolated from recalled contaminated heparin and were compared to OSCS from animal sources and to heparin by-products synthetically persulfated. Results: A great variability in molecular weight was observed in the isolated contaminants. Dermatan sulfate with high-molecular-weight in addition to OSCS was detected. Oversulfated chondroitin sulfate from different sources as well as heparin by-products produced activation of prekallikrein to kallikrein at variable rates as measured by the generation of kallikrein. All agents produced activation of the complement system. All compounds formed complexes with platelet factor 4 (PF4) and all produced 14C serotonin release in the heparin-induced thrombocytopenia (HIT) analysis. The agents also exhibited variable anticoagulant responses that were mostly mediated via heparin cofactor II. Conclusion: These results suggest that heparin contaminants represent a heterogeneous group of oversulfated glycosaminoglycans (OSGAGs) which may mediate multiple pathophysiologic responses.

Comparison of established and novel purity tests for the quality control of heparin by means of a set of 177 heparin samples

The widespread occurrence of heparin contaminated with oversulfated chrondroitin sulfate (OSCS) in 2008 initiated a comprehensive revision process of the Pharmacopoeial heparin monographs and stimulated research in analytical techniques for the quality control of heparin. Here, a set of 177 heparin samples from the market in 2008 as well as pure heparin sodium spiked with defined amounts of OSCS and DS were used to evaluate established and novel methods for the quality control of heparin. Besides (1)H nuclear magnetic resonance spectroscopy (NMR), the assessment included two further spectroscopic methods, i.e., attenuated total reflection-infrared spectroscopy (ATR-IR) and Raman spectroscopy, three coagulation assays, i.e., activated partial thromboplastin time (aPTT) performed with both sheep and human plasma and the prothrombin time (PT), and finally two novel purity assays, each consisting of an incubation step with heparinase I followed by either a fluorescence measurement (Inc-PolyH-assay) or by a chromogenic aXa-assay (Inc-aXa-assay). NMR was shown to allow not only sensitive detection, but also quantification of OSCS by using the peak-height method and a response factor determined by calibration. Chemometric evaluation of the NMR, ATR-IR, and Raman spectra by statistical classification techniques turned out to be best with NMR spectra concerning the detection of OSCS. The validity of the aPTT, the current EP assay, could be considerably improved by replacing the sheep plasma by human plasma. In this way, most of the contaminated heparin samples did not meet the novel potency limit of 180 IU/mg. However, also more than 50% of the uncontaminated samples had <180 IU/MG. In contrast to the aPTT, the PT specifically detects OSCS and other heparin mimetics (LOD 3%). About ten times more sensitive are both the Inc-PolyH-assay and the Inc-aXa-assay, two rapid and simple quantification assays for heparin mimetics. The determined OSCS contents of the heparin samples excellently correlated with those calculated from the NMR spectra. In conclusion, NMR proved to be the current spectroscopic method of choice. The two two-step-assays represent options to supplement NMR, especially as tests for the initial screening, since they detect any heparin mimetic without requiring special expertise for interpretation of the results.

Analysis and characterization of heparin impurities

This review discusses recent developments in analytical methods available for the sensitive separation, detection and structural characterization of heparin contaminants. The adulteration of raw heparin with oversulfated chondroitin sulfate (OSCS) in 2007–2008 spawned a global crisis resulting in extensive revisions to the pharmacopeia monographs on heparin and prompting the FDA to recommend the development of additional physicochemical methods for the analysis of heparin purity. The analytical chemistry community quickly responded to this challenge, developing a wide variety of innovative approaches, several of which are reported in this special issue. This review provides an overview of methods of heparin isolation and digestion, discusses known heparin contaminants, including OSCS, and summarizes recent publications on heparin impurity analysis using sensors, near-IR, Raman, and NMR spectroscopy, as well as electrophoretic and chromatographic separations.

Figure

An assessment of polydispersed species in unfractionated and low molecular weight heparins by diffusion ordered nuclear magnetic resonance spectroscopy method

The primary goal of this project is to extend a (1)H NMR based method, which combines elements of separation on the basis of molecular size with the information specific to (1)H-1D NMR, to the assessment of the heparin contaminant oversulfated chondroitin sulfate (OSCS) and process related impurity dermatan sulfate (DS), and their polydisperse degradation products in samples of unfractionated heparins (UFHs) and low molecular weight heparins (LMWHs) used as the active pharmaceutical ingredients (APIs) in finished pharmaceutical products. The method has been briefly introduced by us in a recent contribution (vide infra). We propose a labelling of the N-acetyl peaks in the (1)H NMR spectra of the UFHs and LMWHs with the parameter D(i), the translational diffusion coefficient available from DOSY NMR. It is shown how DOSY can be applied for screening lots of unfractionated and depolymerised heparins for obtaining molecular size information for heparins and any impurities when using (1)H NMR. The evidence has been presented that title method can be applied as a routine means for assessment of the OSCS and DS contaminants and the polydisperse chemical entities present in the UFHs and LMWHs used as the APIs in heparin pharmaceuticals.

[Capillary electrophoresis analysis of contaminants in heparin sodium for the Japanese pharmacopoeia purity test]

Heparin is widely used as an anticoagulant for the treatment and prevention of thrombotic disorders. Recently, hundreds of cases of anaphylactic reaction as adverse effects were reported by the presence of contaminating oversulfated chondroitin sulfate (OSCS) in some heparin preparations. In addition, these heparin preparations often contaminated dermatan sulfate (DS). Unfortunately, the Japanese Pharmacopoeia (JP) does not include appropriate purity tests. In the present paper, we show that capillary electrophoresis (CE) is a powerful tool for the analysis of OSCS and DS in heparin preparations. CE method shows high resolution and good quantification of OSCS in heparin preparations. This method (OSCS method) was evaluated for accuracy (93.7 %), repeatability (R.S.D.=2.11), linearity (R(2)=0.9996), detection limit (0.1% OSCS) and specificity. In contrast, DS was not able to be detected in high sensitivity by OSCS method. However, a modified CE method (DS method) using the buffer at lower pHs showed good parameters for accuracy (88.1%), repeatability (R.S.D.=1.99), linearity (R(2)=0.9998), detection limit (0.25% DS) and specificity. In conclusion, CE will be an alternative to the NMR method which is being adopted for purification test of heparin sodium in the present version of JP.

Quantitative capillary electrophoresis determination of oversulfated chondroitin sulfate as a contaminant in heparin preparations

A simple, accurate, and robust quantitative capillary electrophoresis (CE) method for the determination of oversulfated chondroitin sulfate (OSCS) as a contaminant in heparin (Hep) preparations is described. After degradation of the polysaccharides by acidic hydrolysis, the hexosamines produced (i.e., GlcN from Hep and GalN from OSCS) were derivatized with anthranilic acid (AA) and separated by means of CE in approximately 10 min with high sensitivity detection at 214 nm (limit of detection [LOD] of approximately 200 pg). Furthermore, AA-derivatized GlcN and GalN showed quite similar molar absorptivity, allowing direct and simple quantification of OSCS in Hep samples. Moreover, a preliminary step of specific enzymatic treatment by using chondroitin ABC lyase may be applied for the specific elimination of interference in the analysis due to the possible presence in Hep samples of natural chondroitin sulfate and dermatan sulfate impurities, making this analytical approach highly specific for OSCS contamination given that chondroitin ABC lyase is unable to act on this semisynthetic polymer. The CE method was validated for specificity, linearity, accuracy, precision, LOD, and limit of quantification (LOQ). Due to the very high sensitivity of CE, as little as 1% OSCS contaminant in Hep sample could be detected and quantified. Finally, a contaminated raw Hep sample was found to contain 38.9% OSCS, whereas a formulated contaminated Hep was calculated to have 39.7% OSCS.

Lessons learned from the contamination of heparin

Heparin is unique as one of the oldest drugs currently still in widespread clinical use as an anticoagulant, a natural product, one of the first biopolymeric drugs, and one of the few carbohydrate drugs. Recently, certain batches of heparin have been associated with anaphylactoid-type reactions, some leading to hypotension and death. These reactions were traced to contamination with a semi-synthetic oversulfated chondroitin sulfate (OSCS). This Highlight reviews the heparin contamination crisis, its resolution, and the lessons learned. Pharmaceutical scientists now must consider dozens of natural and synthetic heparinoids as potential heparin contaminants. Effective assays, which can detect both known and unknown contaminants, are required to monitor the quality of heparin. Safer and better-regulated processes are needed for heparin production.

Characterization of di- and monosulfated, unsaturated heparin disaccharides with terminal N-sulfated 1,6-anhydro-β-d-glucosamine or N-sulfated 1,6-anhydro-β-d-mannosamine residues

Modified heparin disaccharides were obtained by the alkaline treatment of a solution containing the disulfated heparin disaccharide DeltaHexA-alpha-(1-->4)-D-GlcNSO(3),6SO(3). Their structures were characterized by one- and two-dimensional NMR spectroscopy: DeltaHexA-alpha-(1-->4)-1,6-anhydro-GlcNSO(3), DeltaHexA-alpha-(1-->4)-1,6-anhydro-ManNSO(3) and DeltaHexA-alpha-(1-->4)-ManNSO(3),6OSO(3). NMR spectroscopy, in combination with HPLC, provided the composition of the mixture. Characteristic NMR signals of the disaccharides were identified, even at low levels, in a high field of (1)H-(13)C correlation NMR spectra (HSQC) of a low molecular weight heparin (LMWH) obtained by beta-elimination (alkaline hydrolysis) of heparin benzyl ester, providing a more complete structural profile of this class of compounds.

A novel computational approach to integrate NMR spectroscopy and capillary electrophoresis for structure assignment of heparin and heparan sulfate oligosaccharides

Heparin and heparan sulfate (HS) glycosaminoglycans (GAGs) are cell surface polysaccharides that bind to a multitude of signaling molecules, enzymes, and pathogens and modulate critical biological processes ranging from cell growth and development to anticoagulation and viral invasion. Heparin has been widely used as an anticoagulant in a variety of clinical applications for several decades. The heterogeneity and complexity of HS GAGs pose significant challenges to their purification and characterization of structure-function relationships. Nuclear magnetic resonance (NMR) spectroscopy is a promising tool that provides abundant sequence and structure information for characterization of HS GAGs. However, complex NMR spectra and low sensitivity often make analysis of HS GAGs a daunting task. We report the development of a novel methodology that incorporates distinct linkage information between adjacent monosaccharides obtained from NMR and capillary electrophoresis (CE) data using a property encoded nomenclature (PEN) computational framework to facilitate a rapid and unbiased procedure for sequencing HS GAG oligosaccharides. We demonstrate that the integration of NMR and CE data sets with the help of the PEN framework dramatically reduces the number of experimental constraints required to arrive at an HS GAG oligosaccharide sequence.

Short heparin sequences spaced by glycol-split uronate residues are antagonists of fibroblast growth factor 2 and angiogenesis inhibitors

Fibroblast Growth Factor-2 (FGF2) is a major inducer of neovascularization (angiogenesis). Heparin activates FGF2 by favoring formation of ternary complexes with its cellular receptors (FGFRs). Controlled 2-O-desulfation followed by exhaustive periodate oxidation/borohydride reduction has been used to generate sulfation gaps within the prevalent heparin sequences, building-up arrays of pentasulfated trisaccharides (PST, consisting of a 2-O-sulfated iduronic acid flanked by two N,6-disulfated glucosamines) spaced by reduced, glycol-split uronic acid (sU) residues. The structure of the prevalent sequences of the novel heparin derivative has been confirmed by mono- and two-dimensional NMR analysis. NMR spin-lattice relaxation times (T2) and nuclear Overhauser effects suggest that the sU residues act as flexible joints between the PST sequences and cause a marked distortion of the chain conformation of heparin required for formation of ternary complexes. Since the splitting reaction also occurs at the level of the essential glucuronic acid residue of the active site for antithrombin, the heparin derivative has no anticoagulant activity. However, it fully retains the FGF2-binding ability of the original heparin, as shown by its capacity to protect FGF2 from trypsin cleavage and to prevent the formation of heparan sulfate proteoglycan (HSPG)/FGF2/FGFR1 ternary complexes. However, when compared to heparin it showed a reduced capacity to induce FGF2 dimerization and to favor the interaction of [125I]FGF2 with FGFR1 in HSPG-deficient, FGFR1-transfected CHO cells. Accordingly, it was more effective than heparin in inhibiting the mitogenic activity exerted by FGF2 in cultured endothelial cells. Finally, it inhibited angiogenesis in a chick embrio chorioallantoic membrane (CAM) assay in which heparin is inactive.

Analysis of glycosaminoglycan monosaccharides by capillary electrophoresis using indirect laser-induced fluorescence detection

Two methods for monosaccharide analysis by capillary electrophoresis (CE) using counterelectroosmotic and coelectroosmotic modes with indirect laser-induced fluorescence detection were optimised and compared. A mixture of seven glycosaminoglycan-derived hexoses was separated in alkaline fluorescein-based electrolytes and detected in both counterelectroosmotic and coelectroosmotic conditions. The fluorescein concentration and pH of the background electrolyte, and the influence of the reversal of electroosmotic flow by addition of hexadimethrine bromide on the separation were studied. Coelectroosmotic CE conditions provided better resolution and limits of detection. A 10(-6) M fluorescein solution at pH 12.25 containing 0.0005% (w/v) hexadimethrine bromide was used as background electrolyte. Quality parameters such as run-to-run, day-to-day precision and limits of detection were calculated, and better figures of merit were obtained for the coelectrooosmotic conditions than for the counterelectroosmotic mode. The coelectroosmotic method was applied to the quantitation of the hexosamine contents in glycosaminoglycans after acid hydrolysis. The method proved to be suitable for the determination of dermatan sulfate in heparin down to 2% (w/w).

Identification and dynamics of a heparin-binding site in hepatocyte growth factor

Hepatocyte growth factor (HGF) is a heparin-binding, multipotent growth factor that transduces a wide range of biological signals, including mitogenesis, motogenesis, and morphogenesis. Heparin or closely related heparan sulfate has profound effects on HGF signaling. A heparin-binding site in the N-terminal (N) domain of HGF was proposed on the basis of the clustering of surface positive charges [Zhou, H., Mazzulla, M. J., Kaufman, J. D., Stahl, S. J., Wingfield, P. T., Rubin, J. S., Bottaro, D. P., and Byrd, R. A. (1998) Structure 6, 109-116]. In the present study, we confirmed this binding site in a heparin titration experiment monitored by nuclear magnetic resonance spectroscopy, and we estimated the apparent dissociation constant (K(d)) of the heparin-protein complex by NMR and fluorescence techniques. The primary heparin-binding site is composed of Lys60, Lys62, and Arg73, with additional contributions from the adjacent Arg76, Lys78, and N-terminal basic residues. The K(d) of binding is in the micromolar range. A heparin disaccharide analogue, sucrose octasulfate, binds with similar affinity to the N domain and to a naturally occurring HGF isoform, NK1, at nearly the same region as in heparin binding. (15)N relaxation data indicate structural flexibility on a microsecond-to-millisecond time scale around the primary binding site in the N domain. This flexibility appears to be dramatically reduced by ligand binding. On the basis of the NK1 crystal structure, we propose a model in which heparin binds to the two primary binding sites and the N-terminal regions of the N domains and stabilizes an NK1 dimer.

NMR spectroscopy in pharmacy

Since drugs in clinical use are mostly synthetic or natural products, NMR spectroscopy has been mainly used for the elucidation and confirmation of structures. For the last decade, NMR methods have been introduced to quantitative analysis in order to determine the impurity profile of a drug, to characteristic the composition of drug products, and to investigate metabolites of drugs in body fluids. For pharmaceutical technologists, solid state measurements can provide information about polymorphism of drug powders, conformation of drugs in tablets etc. Micro-imaging can be used to study the dissolution of tablets, and whole-body imaging is a powerful tool in clinical diagnostics. Taken together, this review covers applications of NMR spectroscopy in drugs analysis, in particular, methods of international pharmacopoeiae, pharmaceutics and pharmacokinetics. The authors have repeated many of the methods describe in their own laboratories.

Purity of glycosaminoglycan-related compounds using capillary electrophoresis

High performance capillary electrophoresis was used to determine impurities in glycosaminoglycans. The counterion of glycosaminoglycans was analyzed with indirect UV-detection using a 40 mM 4-aminopyridine buffer. Calcium, lithium, potassium and sodium could be resolved. A linear correlation between the area under the curve and the concentration of sodium (r2 = 0.98) and calcium (r2 = 0.99) was found. Using enzymatic depolymerization, chondroitin sulfates were cleaved to disaccharides. The resulting disaccharides, with the structure 4-deoxy-alpha-L-threo-hex-4-enopyranosyl uronic acid (delta UA) 2 x (1-->3)-D-GalNY6X (X = H, sulfate and Y = acetyl, sulfate) for dermatan sulfate, were detected selectively at 230 nm using capillary electrophoresis. Dermatan sulfate disaccharides were analyzed using a 50 cm long fused silica capillary (75 microns ID). The buffer used was 10 mM sodium tetraborate and 50 mM SDS, pH 8.8. The detection was at 230 nm. Using the main peak delta UA (1-->3)-D-GalNAc4S as standard, between 1 and 80% dermatan sulfate in heparin preparations were analyzed. The disaccharide showed a linear correlation of the peak area versus the concentration with a correlation coefficient r2 = 0.98. The methods are useful in characterizing the identity and concentration of the counterion of glycosaminoglycans after chondroitinase degradation.

Structural analysis of heparin by raman spectroscopy

The Raman spectra of commercially available heparin disaccharide standards exhibit bands associated with the N-sulfate and the 6-O-sulfate groups of the glucosamine and the 2-O-sulfate of the iduronic acid. The N-sulfate has a strong band at 1039 cm-1. The 6-O-sulfate and the 2-O-sulfate exhibit bands at 1055 and 1065 cm-1, respectively. The pattern of these modes, which are assigned to the symmetric SO3 vibrations, was supported by semiempirical quantum mechanical calculations. The above bands were identified in the Raman spectrum of a commercial preparation of porcine mucosal heparin and were used to determine the relative proportion of the N-sulfate, 6-O-sulfate, and 2-O-sulfate groups in the heparin molecule. This information, which is complementary to that obtained by NMR spectroscopy, is of particular importance in relation to biological activity. This study also extends the usefulness of Raman spectroscopy to include structural details required for the quality assurance of pharmaceutical preparations of heparin.

Physiochemical characterization of low molecular weight heparin

Nuclear magnetic resonance spectroscopy (NMR), Raman spectroscopy, dynamic light scattering (DLS), and high performance exclusion chromatography (HPEC) were used to characterize two different commercial preparations of low molecular weight (LMW) heparin, produced either by peroxide cleavage or deaminative cleavage using nitrous acid. Proton NMR showed < 2% contamination by dermatan sulfate in the material produced by deaminative cleavage using nitrous acid and < 4% for the material produced by peroxide cleavage. The Raman spectra of the nitrous acid produced material showed an equivalent amount of O-sulfation to that in the material produced by peroxide, but about a 10% reduction in the content of N-sulfated glucosamine, as expected from the deamination reaction. DLS and HPEC indicated the presence of < 0.2% of very high molecular weight/aggregate material for the peroxide preparation compared to 1% for the nitrous acid-prepared material. The weight average molecular weight (Mw) determined from HPEC was 5900 Da for the nitrous acid-prepared material and 6850 Da for the peroxide-produced material. The number average molecular weight (Mn) calculated from this data was 5200 Da for the nitrous acid preparation and 5300 Da for the peroxide-produced material. In addition, the nitrous acid-prepared material exhibited a much narrower size distribution of oligomeric species, as evidenced by the polydispersity (Mw/Mn) of 1.1 for the nitrous acid-prepared material, as compared with a value of 1.3 for the peroxide-prepared material. These studies demonstrate that significant differences between preparations of LMW heparin can be resolved using these techniques. This is of critical importance in the design of quality assurance methods.

Dermatan sulfate from beef mucosa: structure, physicochemical and biological properties of fractions prepared by chemical depolymerization and anion-exchange chromatography

Dermatan sulfate was extracted and purified from beef intestinal mucosa. The structure and physicochemical properties were evaluated by different techniques, such as, disaccharide pattern, relative molecular mass, sulfate-to-carboxyl ratio, and electrophoretic profile in agarose electrophoresis. The biological activity was evaluated as heparin cofactor II activity (HCII activity). The purity of dermatan sulfate was carefully evaluated by specific enzymatic cleavage, agarose electrophoresis, and HPLC. Different relative molecular masses of dermatan sulfate, from 25,000 to 2000, were prepared by chemical degradation. The structures and physicochemical properties were checked to exclude a possible desulfation process. The HCII activities were evaluated for different relative molecular mass of dermatan sulfate. The capacity of chondroitinase ABC to cleave different relative molecular masses of dermatan sulfate was also studied. Native dermatan sulfate was fractionated according to charge density. Different fractions were obtained and analysed for disaccharide pattern, relative molecular mass, sulfate-to-carboxyl ratio, and HCII activities.

"Fast moving" and "slow moving" heparins, dermatan sulfate, and chondroitin sulfate: qualitative and quantitative analysis by agarose-gel electrophoresis

Heparin from beef intestinal mucosa, dermatan sulfate from beef intestinal mucosa, and chondroitin sulfate from bovine trachea were extracted and purified, and their structures and physico-chemical properties were evaluated by different techniques (disaccharide patterns by specific enzymatic cleavage, relative molecular mass by high-performance size-exclusion chromatography, sulfate-to-carboxyl ratio by potentiometric determination). Heparin was fractionated into "slow moving" and "fast moving" fractions by selective precipitation as the barium salt at different temperatures. The "fast moving" and "slow moving" components of heparin, dermatan sulfate, and chondroitin sulfate were utilized to run calibration curves in agarose-gel electrophoresis. Mixtures containing different amounts of these glycosaminoglycans were made and separated by agarose-gel electrophoresis, and these were analyzed quantitatively. For analysis of relative amounts, the area of each individual component of mixtures, obtained by photodensitometric readings, was divided by the sum of the areas of all glycosaminoglycans and expressed as a percentage. For analysis of absolute amounts, the area under the curve for each component of mixtures was fitted to specific calibration curves, and the amount of each glycosaminoglycan was calculated in micrograms. The quantitative procedure performed by analysing absolute amounts was used to obtain an accurate quantitative evaluation of each component in mixtures of glycosaminoglycans utilized for pharmaceutical purposes. A sensitive method was developed for the evaluation of very small amounts (0.2% w/w) of possible glycosaminoglycans as contaminants in preparations of a single species of glycosaminoglycan. This technique requires specific enzymatic degradation by bacterial lyases, separation in agarose-gel electrophoresis, and quantitative analysis by photodensitometric analysis and specific calibration curves.

Effects of chondroitin sulfates with different structures on leukemia cells: U-937 cell proliferation and differentiation

Chondroitin sulfates extracted and purified by different manufacturers were tested to evaluate their effects on proliferation and differentiation processes of U-937 cells. The different chondroitin sulfates were evaluated for purity, structure and physicochemical properties. The three chondroitin sulfates utilized did not present other contaminant glycosaminoglycans and proteins and had about the same relative molecular mass but different disaccharide patterns and charge density. Chondroitin sulfates with small amounts of disulfated disaccharides and low charge density, at 5 micrograms/ml concentration, doubled (about + 133%) cell proliferation in comparison to controls. In contrast, chondroitin sulfates with large amounts of disulfated disaccharides and high sulfate to carboxyl ratio were less effective (about + 15%) in stimulating cell proliferation at low concentration. A decrease of U-937 cell proliferation was observed in proportion to the increased amounts of chondroitin sulfate with low sulfate to carboxyl ratio. On the contrary, chondroitin sulfate with large amounts of disulfated disaccharides produced increased cell proliferation depending on concentration. Small amounts (5-10 micrograms/ml) of chondroitin sulfates with low charge density reduced the differentiative process of U-937 cells. Chondroitin sulfate with large amounts of disulfated disaccharides and high charge density seemed to be able to produce a significant decrease of differentiative processes only at very high concentrations (1000 micrograms/ml). These contrasting effects of chondroitin sulfates with different disaccharide patterns (and structure) and charge density on a leukemia cell line could help to explain the regulation of proliferative and/or differentiative processes of hemopoietic cells. This is underlined by the changes of types, physicochemical properties and structure of glycosaminoglycans induced by different extracellular factors and agents.

Diagnostic methods for the determination of iduronic acid in oligosaccharides

A high-performance liquid chromatography (HPLC) method with pulsed amperometric detection (PAD) was used for the determination of the acid hydrolysis products of L-iduronic acid containing oligosaccharides isolated from biological sources. This HPLC-PAD method was compared with gas chromatographic (GLC) methods. Since acid hydrolysis of oligosaccharides can produce a number of products, several uronic acid derivatives were prepared by chemical synthesis. These well characterized standards in conjunction with mass spectrometry allowed for the identification of most of the products of methanolysis or hydrolysis of glycosamino-glycans, which included chondroitin sulfates A and B (dermatan sulfate), heparin, and hyaluronic acid. (4 M) HCl in methanol 100 degrees C for 24 h was found to be optimum for GLC and 1 M aqueous HCl for 4 h at 100 degrees C for HPLC-PAD. All of the monosaccharides, hexosamines, and uronic acids could be separately identified in a single chromatographic step using either technique. Good resolution, high sensitivity (low microgram samples) and rapid analysis makes these methods particularly useful for the determination of small amounts of glycosaminoglycans and other glycoconjugates found in samples isolated from biological sources. These two techniques are specifically designed to allow the qualitative determination of the carbohydrate content and composition of samples whose carbohydrate composition and content is completely unknown.

Marked stereoselectivity in the binding of copper ions by heparin. Contrasts with the binding of gadolinium and calcium ions

Heparin forms a complex with cupric ion (Cu2+) at a level of less than or equal to 10(-3) mol of the metal ion per dimeric unit of the polymer, as evidenced by paramagnetic relaxation effects on its 1H- and 13C-n.m.r. spectra. No interaction occurred with heparin derivatives modified either by desulfation of the residues of alpha-L-iduronic acid 2-sulfate, or by hydrolysis of the sulfamino group of the residues of 2-deoxy-2-sulfamino-alpha-D-glucose 6-sulfate, although binding was induced by N-acetylation of the latter derivative. Under the same experimental conditions, no alternative type of glycosyluronic acid structure tested, including the other glycosaminoglycans, showed significant relaxation enhancement by Cu2+. These results are in contrast to those obtained with gadolinium ion (Gd3+), another paramagnetic probe, or with calcium ion (Ca2+), which promotes chemical-shift displacements. The binding selectivities of those two cations are much broader than that of Cu2%, although they also differ notably in their relationship to the structure of heparin.

Physicochemical characterization of the First World Health Organization International Standard for low molecular weight heparin derivatives

High-field (300 MHz) 1H NMR spectral analysis and particle size distribution analysis employing the quasielastic light scattering (QELS) technique were performed on samples of the 1st International Standard for low molecular weight (LMW) heparin derivatives recently selected by the World Health Organization (WHO). We propose that the results of these analyses, which showed that the material is highly homogeneous in particle size and retains spectral features characteristic of its porcine mucosal origin, form an appropriate basis for physicochemical comparison between the "Standard" and other LMW heparin preparations.

Chemical composition, particle size range, and biological activity of some low molecular weight heparin derivatives

Several low molecular weight (LMW) heparin sodium derivatives from different sources, as well as some related regular heparin sodium preparations, were examined for chemical composition by high field (300 MHz) 1H NMR spectroscopy, for particle size range by quasi-elastic light scattering (QELS) methods, and for anti-coagulation potency and anti-factor Xa activity by the standard U.S. Pharmacopeial assays described for regular heparin. The NMR spectra provided insight into possible modes of depolymerization used to generate the LMW heparins, as well as into the presence of dermatan sulfate or other chemical contaminants. The QELS analysis permitted the heparin preparations to be characterized and compared by virtue of their distinctive particle size distributions.

Examination of a possible role for dermatan sulfate in the aggregation of commercial heparin samples

A wide range of commercial heparin preparations were examined by the technique of quasi-elastic light scattering (QELS) for size distribution and evidence for aggregation in relation to determined dermatan sulfate (DS) content. No correlation could be found between DS content and state of aggregation. The possible interaction of DS with heparin was further studied by QELS in a control experiment in which known quantities of DS were added to a heparin sodium preparation known to be low in DS. The effect of increasing DS content was to slightly decrease the measured most probable size of the samples and also to decrease the size spread. The biological activity (as measured by the official test) of the heparin samples, including those treated with additional DS, was found to fall within the accepted limits, independent of the aggregation state of the samples. Overall, there is no direct, observable effect that links DS to the observed aggregation of commercial heparin samples, although DS itself is known to self-associate.

Applications of quantitative 1H- and 13C-NMR spectroscopy in drug analysis

The usefulness of 1H and 13C Fourier transform (FT) nuclear magnetic resonance spectroscopy (1H- and 13C-NMR) as quantitative methods stems from the potential direct relationship between the area under an NMR peak and the number of the particular type of nuclei that give rise to the signal, though it is necessary, especially for quantitative 13C-NMR, to take some precautions. The experimental limitations that have to be overcome in order to obtain quantitative 13C-NMR spectra are associated with the relaxation time, the nuclear Overhauser effect (NOE), and the NMR instrument itself (filter characteristics, power level of the exciting pulse, dynamic range, digital resolution). Practical problems aside, 13C-NMR has a greater potential than 1H-NMR for the study of organic systems. The sensitivity of 13C chemical shifts to small differences in molecular environment, coupled with a large chemical shift range, gives a "chromatographic" separation of resonances of interest, and has made 13C-NMR an attractive method for analysing complex mixtures. Some applications of quantitative 1H- and 13C-NMR spectroscopy in drug analysis are discussed.