Immunospecific analysis of in vitro and ex vivo surface-immobilized protein complex.

Biomaterials used for blood contacting devices are inherently thrombogenic. Antithrombotic agents can be used as surface modifiers on biomaterials to reduce thrombus formation on the surface and to maintain device efficacy. For quality control and to assess the effectiveness of immobilization strategies, it is necessary to quantify the surface-immobilized antithrombotic agent directly. There are limited methods that allow direct quantification on device surfaces such as catheters. In this study, an enzyme immunoassay (EIA) has been developed to measure the density of a synthetic antithrombin-heparin (ATH) covalent complex immobilized on a catheter surface. The distribution of the immobilized ATH was further characterized by an immunohistochemical assay. This analyte-specific EIA is relatively simple and has high throughput, thus providing a tool for quantitative analysis of biomaterial surface modifications. These methods may be further modified to evaluate plasma proteins adsorbed and immobilized on various biomaterial surfaces of complex shapes, with a range of bioactive functionalities, as well as to assess conformational changes of proteins using specific antibodies.

In-vitro assessment of the effect of dabigatran on thrombosis of adult and neonatal plasma: comparisons using thromboelastography and microscopic visualization of fibrin clot structure.

: Thromboelastography (TEG) is a global assay used for evaluating features of clot formation in vitro. Dabigatran is a reversible direct inhibitor of thrombin that has not been studied in neonates using a sophisticated global assay, such as TEG. Neonatal hemostasis differs from adult hemostasis in both quantitative and qualitative characteristics. Our aim was to compare the TEG clotting profile of neonatal and adult platelet-poor plasma when exposed to different concentrations of dabigatran. We used commercially collected adult pooled plasma and neonatal cord blood collected from placentas of healthy full term newborns. Platelet-poor plasma was isolated, pooled, and frozen. Prior to experiment, plasma was thawed and filtered. A reaction mixture of CaCl2, corn trypsin inhibitor, tissue factor, and dabigatran in imidazole buffer was mixed with plasma in a TEG cup. Time to clot initiation (R-time), speed of clot strengthening (α-angle), and maximum clot strength (maximal amplitude) were measured. Scanning electron microscopy was performed to evaluate fibrin clot structure. Without dabigatran, there was no significant difference in TEG measurements between neonatal and adult samples. However, neonatal plasma clotting with dabigatran had slower onset, slower speed, and weaker clots that were more porous with thicker fibers, compared with adult plasma clotting. Thus, neonatal plasma may be more sensitive to dabigatran as assessed by our in-vitro TEG study.

Inhibition of plasmin generation in plasma by heparin, low molecular weight heparin, and a covalent antithrombin-heparin complex.

: The clinical limitations of unfractionated heparin (UFH) and low molecular weight heparin (LMWH) led to the development of an antithrombin-heparin covalent complex (ATH), which displays superior anticoagulant abilities compared with UFH. A recent study investigating its interaction with fibrinolysis showed that ATH inhibited free and fibrin bound plasmin and decreased plasmin generation on fibrin clots. These studies were conducted using purified components and did not elucidate the interaction of ATH with plasmin in the presence of its natural inhibitors α2-antiplasmin (α2-AP) and α2-macroglobulin (α2-M). The aim of this study was to determine the effects of ATH, UFH, and LMWH on plasmin generation in plasma, under more physiological conditions. Plasmin generation in plasma in the absence and presence of anticoagulants was initiated by tissue plasminogen activator and soluble fibrin fragments, and plasmin and plasmin-α2-M complexes generated over time were quantified chromogenically. Generation of plasmin-α2-AP complexes and consumption of plasminogen were quantified by ELISA. Plasmin generation was decreased in the presence of UFH and ATH, whereas LMWH had no effect. Neither plasminogen consumption nor generation of plasmin-α2-AP complexes were affected by UFH or ATH. However, plasmin-α2-M complexes were slightly reduced by ATH suggesting that ATH may be able to compete with α2-M for plasmin. Plasmin generation may be mildly inhibited by heparin-based anticoagulants; however, heparin-catalyzed antithrombin activity is not a major inhibitor of plasmin, as compared to its natural inhibitors α2-AP and α2-M. This adds to our understanding of ATH mechanisms of action and aids in its development for clinical use.

Surface modification of poly(dimethylsiloxane) with a covalent antithrombin-heparin complex for the prevention of thrombosis: use of polydopamine as bonding agent.

A modified poly(dimethyl siloxane) (PDMS) material is under development for use in an extracorporeal microfluidic blood oxygenator designed as an artificial placenta to treat newborn infants suffering from severe respiratory insufficiency. To prevent thrombosis triggered by blood-material contact, an antithrombin-heparin (ATH) covalent complex was coated on PDMS surface using polydopamine (PDA) as a "bioglue". Experiments using radiolabelled ATH showed that the ATH coating on PDA-modified PDMS remained substantially intact after incubation in plasma, 2% SDS solution, or whole blood over a three day period. The anticoagulant activity of the ATH-modified surfaces was also demonstrated: in contact with plasma the ATH-coated PDMS was shown to bind antithrombin (AT) selectively from plasma and to inhibit clotting factor Xa. It is concluded that modification of PDMS with polydopamine and ATH shows promise as a means of improving the blood compatibility of PDMS and hence of the oxygenator device.

Surface modification of polydimethylsiloxane with a covalent antithrombin-heparin complex to prevent thrombosis.

To prevent coagulation in contact with blood, polydimethylsiloxane (PDMS) was modified with an antithrombin-heparin (ATH) covalent complex using polyethylene glycol (PEG) as a linker/spacer. Using NHS chemistry, ATH was attached covalently to the distal chain end of the immobilized PEG linker. Surfaces were characterized by contact angle and X-ray photoelectron spectroscopy; attachment was confirmed by decrease in contact angles and an increase in nitrogen content as determined by X-ray photoelectron spectroscopy. Protein interactions in plasma were investigated using radiolabeled proteins added to plasma as tracers, and by immunoblotting of eluted proteins. Modification of PDMS with PEG alone was effective in reducing non-specific protein adsorption; attachment of ATH at the distal end of the PEG chains did not significantly affect protein resistance. It was shown that surfaces modified with ATH bound antithrombin selectively from plasma through the pentasaccharide sequence on the heparin moiety of ATH, indicating the ability of the ATH-modified surfaces to inhibit coagulation. Using thromboelastography, the effect of ATH modification on plasma coagulation was evaluated directly. It was found that initiation of coagulation was delayed and the time to clot was prolonged on PDMS modified with ATH/PEG compared to controls. For comparison, surfaces modified in a similar way with heparin were prepared and investigated using the same methods. The data suggest that the ATH-modified surfaces have superior anticoagulant properties compared to those modified with heparin.

Interactions of heparin and a covalently-linked antithrombin-heparin complex with components of the fibrinolytic system.

Unfractionated heparin (UFH) is used as an adjunct during thrombolytic therapy. However, its use is associated with limitations, such as the inability to inhibit surface bound coagulation factors. We have developed a covalent conjugate of antithrombin (AT) and heparin (ATH) with superior anticoagulant properties compared with UFH. Advantages of ATH include enhanced inhibition of surface-bound coagulation enzymes and the ability to reduce the overall size and mass of clots in vivo. The interactions of UFH or ATH with the components of the fibrinolytic pathway are not well understood. Our study utilised discontinuous second order rate constant (k2) assays to compare the rates of inhibition of free and fibrin-associated plasmin by AT+UFH vs ATH. Additionally, we evaluated the effects of AT+UFH and ATH on plasmin generation in the presence of fibrin. The k2 values for inhibition of plasmin were 5.74 ± 0.28 x 106 M⁻¹ min⁻¹ and 6.39 ± 0.59 x 106 M⁻¹ min⁻¹ for AT+UFH and ATH, respectively. In the presence of fibrin, the k2 values decreased to 1.45 ± 0.10 x 106 M⁻¹ min⁻¹ and 3.07 ± 0.19 x 106 M⁻¹ min⁻¹ for AT+UFH and ATH, respectively. Therefore, protection of plasmin by fibrin was observed for both inhibitors; however, ATH demonstrated superior inhibition of fibrin-associated plasmin. Rates of plasmin generation were also decreased by both inhibitors, with ATH causing the greatest reduction (approx. 38-fold). Nonetheless, rates of plasmin inhibition were 2-3 orders of magnitude lower than for thrombin, and in a plasma-based clot lysis assay ATH significantly inhibited clot formation but had little impact on clot lysis. Cumulatively, these data may indicate that, relative to coagulant enzymes, the fibrinolytic system is spared from inhibition by both AT+UFH and ATH, limiting reduction in fibrinolytic potential during anticoagulant therapy.

Thrombin generation.

Generation of thrombin has been established as the critical process leading to coagulation in vivo. Indeed, ex vivo markers of thrombin generation in patients have been useful in detecting thrombosis, while many standard global clot-time tests of haemostasis in blood or plasma samples are simple endpoint measures of the potential to generate thrombin. Thus, there has been a recent surge towards direct measurement of thrombin generation potential in plasma/blood samples as a refined methodology for more precisely assessing procoagulant/anticoagulant/hemorrhagic parameters of the haemostatic status. Presently, however, there is no consensus method for thrombin generation determination. The present treatise gives detailed procedures for available thrombin generation tests, with emphasis on the preferred technology.

Covalently linking heparin to antithrombin enhances prothrombinase inhibition on activated platelets.

Factor (F)Xa within the prothrombinase complex is protected from inhibition by unfractionated heparin (UFH), enoxaparin and fondaparinux. We have developed a covalent antithrombin-heparin complex (ATH) with enhanced anticoagulant activity. We have also demonstrated that ATH is superior at inhibiting coagulation factors when assembled on artificial surfaces. The objective of the present study is to determine the ability of ATH vs AT+UFH to inhibit FXa within the prothrombinase complex when the enzyme complex is assembled on the more native platelet system. Discontinuous inhibition assays were performed to determine final k2-values for inhibition of FXa, FXa within the platelet-prothrombinase, or FXa within prothrombinase devoid of various components. Thrombin generation and plasma clotting was also assayed in the presence of resting/activated platelets ± inhibitors. Protection of FXa was not observed for ATH, whereas a moderate 60% protection was observed for AT+UFH. ATH inhibited platelet-prothrombinase ~4-fold faster than AT+UFH. Relative to intact prothrombinase, ratesfor FXa inhibition by AT+UFH in prothrombinase complexes devoid of either prothrombin (II)/activated platelets/FVa were higher. However, inhibition by AT+UFH of prothrombinase devoid of FII yielded slightly lower rates compared to free FXa inhibition. Thrombin generation and plasma clotting was enhanced with activated platelets, while inhibition was better by ATH compared to AT+UFH, thus suggesting an overall enhanced anticoagulant activity of ATH against platelet-bound prothrombinase complexes.

Inhibition of the prothrombinase complex on red blood cells by heparin and covalent antithrombin-heparin complex.

The role of red blood cells (RBCs) in coagulation is not well understood. Overt exposure of phosphatidylserine on surfaces of RBCs provide docking sites for formation of the prothrombinase complex, which further aids in amplification of coagulation leading to subsequent thrombosis. No studies to date have evaluated heparin inhibition of the RBC-prothrombinase system. Therefore, this study examines the ability of heparin and a covalent antithrombin-heparin complex (ATH) to inhibit the RBC-prothrombinase system. Discontinuous inhibition assays were performed to obtain k2 values for inhibition of free or prothrombinase-bound Xa by antithrombin and unfractionated heparin (AT + UFH) versus ATH. In addition, components of the complex (prothrombin, RBCs or Va) were excluded prior to reaction with inhibitors to investigate potential mechanisms involved. Inhibition of thrombin generation, fibrinogen conversion and plasma clotting by the RBC-prothrombinase system was also examined. Protection of Xa was observed for AT + UFH and not for ATH reactions. Inhibition rates for ATH were significantly faster when compared with AT + UFH results. The greatest impact on Xa inhibition was observed from factor Va omission for both inhibitors. ATH inhibited thrombin generation, fibrinogen conversion and plasma clotting better compared with AT + UFH. This study determined potential control of coagulation contributed by RBCs. Moreover, greater control of coagulation is achieved by covalently linking heparin to AT.

Comparison of N-linked glycosylation of protein C in newborns and adults.

Protein C (PC) is a major anticoagulant that stems the propagation of thrombin. The activated form of PC (APC), in association with the cofactor protein S, proteolytically converts activated coagulation factors VIIIa and Va into inactive forms. Studies have shown that forms of PC that contain 3N-linked glycans (beta-PC) are functionally distinct from the fully glycosylated 4-glycan type (alpha-PC). Since some findings have also hinted at qualitative differences in PC from newborns and adults, we decided to determine the relative constitution of glycoforms in these age groups. Subtypes of PC in newborn and adult plasmas were distinguished by SDS polyacrylamide electrophoresis and Western blotting, followed by immunological analysis. Newborns were found to have alpha-PC/beta-PC mole ratios of 8.8:1, compared to 2.3:1 in adults. PC was also isolated by immunoaffinity chromatography from newborn and adult plasmas. Glycans were released by protease treatment and studied by mass spectrometry. Results from glycan analysis showed a small range of glycan structures in both age groups. No clear differences were noted between newborn and adult PC microheterogeneity in glycan structures (branching). We conclude that newborns have important differences in PC macroheterogeneity in glycoform content relative to adults. This age-dependent glycosylation variation may have implications in management of PC function in vivo.

Polyurethane modified with an antithrombin-heparin complex via polyethylene oxide linker/spacers: influence of PEO molecular weight and PEO-ATH bond on catalytic and direct anticoagulant functions.

A segmented polyurethane (PU) was modified with polyethylene oxides (PEO) of varying molecular weight and end group. The PEO served as linker/spacers to immobilize an antithrombin-heparin (ATH) anticoagulant complex on the PU. Isocyanate groups were introduced into the PU to enable attachment of either "conventional" homo-bifunctional dihydroxy-PEO (PEO-OH surface) or a hetero-bifunctional amino-carboxy-PEO (PEO-COOH surface). The PEO surfaces were functionalized with N-hydroxysuccinimide (NHS) groups using appropriate chemistries, and ATH was attached to the distal NHS end of the PEO (PEO-OH-ATH and PEO-COOH-ATH surfaces). Water contact angle and fibrinogen adsorption measurements showed increased hydrophilicity and reduced fibrinogen adsorption from buffer on all PEO surfaces compared to unmodified PU. ATH uptake on NHS-functionalized PEO was quantified by radiolabeling. Despite the different PEO molecular weights and end groups, and NHS-functionalization chemistries, the surface densities of ATH were similar. The adsorption of fibrinogen and antithrombin (AT) from plasma was measured in a single experiment using dual radiolabeling. On PEO-ATH surfaces fibrinogen adsorption was minimal while AT adsorption was high showing the selectivity of the heparin moiety of ATH for AT. The PEO-COOH-ATH surfaces showed slightly greater AT adsorption than the PEO-OH-ATH surfaces. Thrombin adsorption on all of the PEO-ATH surfaces was greater than on the corresponding PEO surfaces without ATH, and was highest on the PEO-OH-ATH, suggesting potential anticoagulant properties for this surface via direct thrombin inhibition by the AT portion of ATH.

Mechanism of inhibition of the prothrombinase complex by a covalent antithrombin-heparin complex.

Factor-Xa assembly into the prothrombinase complex decreases its availability for inhibition by antithrombin + unfractionated heparin (AT + UFH). We have developed a novel covalent antithrombin-heparin complex (ATH), with enhanced anticoagulant actions compared with AT + UFH. The present study was performed to extend understanding of the anticoagulant mechanisms of ATH by determining its inhibition of Xa within the critical prothrombinase. Discontinuous inhibition assays were performed to determine final k(2) values for inhibition of Xa. Fluorescent microscopy was conducted to evaluate inhibitor-prothrombinase interactions. The k(2) for inhibition of prothrombinase versus free Xa by AT + UFH was lower, whereas for ATH were much higher. Relative to intact prothrombinase, rates for Xa inhibition by AT + UFH in complexes devoid of prothrombin/vesicles/factor-Va were higher. For ATH, exclusion of prothrombin decreased k(2), removal of vesicles increased k(2) and exclusion of factor-Va gave no effect. While UFH may displace Xa from prothrombinase, Xa is detained within prothrombinase during ATH reactions. We confirm prothrombinase hinders inhibitory action of AT + UFH, whereas ATH is less affected with prothrombin being a key component in the complex responsible for the opposing effects. Overall, the results suggest that covalent linkage between AT-heparin assists access and neutralization of complexed Xa, with concomitant inhibition of prothrombinase function compared with conventional non-conjugated heparin.

Modification of polyurethane surface with an antithrombin-heparin complex for blood contact: influence of molecular weight of polyethylene oxide used as a linker/spacer.

Polyurethane (PU) was modified using isocyanate chemistry to graft polyethylene oxide (PEO) of various molecular weights (range 300-4600). An antithrombin-heparin (ATH) covalent complex was subsequently attached to the free PEO chain ends, which had been functionalized with N-hydroxysuccinimide (NHS) groups. Surfaces were characterized by water contact angle and X-ray photoelectron spectroscopy (XPS) to confirm the modifications. Adsorption of fibrinogen from buffer was found to decrease by ~80% for the PEO-modified surfaces compared to the unmodified PU. The surfaces with ATH attached to the distal chain end of the grafted PEO were equally protein resistant, and when the data were normalized to the ATH surface density, PEO in the lower MW range showed greater protein resistance. Western blots of proteins eluted from the surfaces after plasma contact confirmed these trends. The uptake of ATH on the PEO-modified surfaces was greatest for the PEO of lower MW (300 and 600), and antithrombin binding from plasma (an indicator of heparin anticoagulant activity) was highest for these same surfaces. The PEO-ATH- and PEO-modified surfaces also showed low platelet adhesion from flowing whole blood. It is concluded that for the PEO-ATH surfaces, PEO in the low MW range, specifically MW 600, may be optimal for achieving an appropriate balance between resistance to nonspecific protein adsorption and the ability to take up ATH and bind antithrombin in subsequent blood contact.

Determination of alpha-2-macroglobulin complexes by a new immuno-activity assay.

INTRODUCTION: Alpha-2-macroglobulin (α(2)M) is a broad specificity protease inhibitor which impacts several hemostatic pathways. Selective detection of various α(2)M complexes may be useful to define markers for the status of different hemostatic components. We present proof of principle for a novel assay to quantitatively measure α(2)M in complex with a variety of hemostatic factors. MATERIALS AND METHODS: The assay makes use of the fact that α(2)M entraps proteases within a molecular "cage", leaving them inaccessible to macromolecular substrates while retaining functionality against small synthetic substrates. Wells coated with anti-α(2)M antibodies were used to isolate the complexes from buffer or plasma, followed by detection of specific proteases with chromogenic substrates. Macromolecular inhibitors were added to eliminate signal from any unbound proteases. RESULTS: Calibration curves constructed with purified protease-α(2)M complexes were sigmoidal in nature, as is typical with immuno-assays. The specificity of signal production was confirmed with inhibitors that target either free protease, or both free and α(2)M-bound protease. The detection range of the assay was dependent on the protease being measured, and the surrounding matrix. Interference in detection of complexes in plasma was found to be caused, in part, by free α(2)M. Thrombin-α(2)M complexes were quantified in adult and newborn plasma following induction of thrombin generation and found to be significantly higher in adults, likely due to higher prothrombin levels. CONCLUSIONS: This assay provides a versatile platform method for quantification of multiple protease-α(2)M complexes. It may prove useful for mechanistic in vitro studies of hemostatic pathways, and potentially for clinical applications.

Immobilization of an antithrombin-heparin complex on gold: anticoagulant properties and platelet interactions.

The anticoagulant properties and platelet interactions of gold surfaces modified with an antithrombin-heparin (ATH) complex are reported. ATH was attached to gold through either a short disulfide (linker) or a thiol-terminated polyethylene oxide (PEO) (linker, spacer). Analogous surfaces were prepared with uncomplexed heparin. Antithrombin (AT) uptake was measured before and after selectively destroying the active pentasaccharide sequence of the heparin moiety, and was found to be predominantly through the active sequence on all of the surfaces. AT binding was higher on the ATH surfaces than on the corresponding heparin surfaces. Heparin activity was assessed by an anti-factor Xa assay. The ratio of active heparin density (from the anti-FXa assay) to total heparin density was taken as a measure of heparin bioactivity. The ratio was greater on the ATH- than on the heparin-modified surfaces, i.e. the PEO-ATH surfaces showed the greater proportion of active heparin. Platelet adhesion from flowing whole blood was found to be reduced on PEO- and ATH-modified surfaces compared to bare gold. The PEO-ATH modified surfaces, but not the heparinized surfaces, were shown to prolong the clotting time of recalcified plasma.

Binding of heparin to metals.

Heparin is a major prophylactic and treatment agent for thrombosis. Structurally, this anticoagulant is a polydisperse, highly negatively charged polysaccharide mixture that contains a variable density of sulfate group substituents per molecule. Previous study has shown that heparin molecules have a high affinity for a wide range of metal ions with varying oxidation states. However, reports in literature on binding of heparin to metals have investigated only a small sampling of heparin-metal ion interactions. Since interaction of heparin with fluid phase and cell surface macromolecules in vivo is dependent on the heparin structure when bound in a metal ion complex, a survey of the physical parameters for heparin binding to metals is imperative. Atomic absorption and spectrophotometry experiments were performed for metal quantification, and in this study, the relative values for affinity constants and number of binding sites for heparin binding to several alkaline, alkaline earth, main group, and transition metals in their most common oxidation states are reported. We found an overall trend for heparin-metal affinity to be Mn(2+) > Cu(2+) > Ca(2+) > Zn(2+) > Co(2+) > Na(+) > Mg(2+) > Fe(3+) > Ni(2+) > Al(3+)> Sr(2+), with the trend in N (b) being opposite compared with the K (a).

Chemical-physical characterization of polyurethane catheters modified with a novel antithrombin-heparin covalent complex.

Detailed structural studies were made of polyurethane catheter surfaces modified with a covalent antithrombin-heparin (ATH) complex that has superior anticoagulant activity compared to unfractionated heparin. ATH was grafted onto polyurethane catheters by surface film preparation involving a three-step process: (1) activation of ATH through functionalized poly(ethylene glycol) (PEG), (2) base-coating treatment of the polyurethane surface and (3) final attachment of ATH onto the surface by free radical polymerization. With the application of base coating, composed of polyhydroxyethylmethacrylates and poly(ethylene oxide) (PEO), the coating process could easily be transferred to other biomaterials by adjusting the base-coating composition. Anti-factor Xa assays confirmed high anticoagulant activity of the ATH coatings. To determine structural aspects critical for biological function, the product was analyzed using differential scanning calorimetry and SDS-PAGE. Radiolabeled ATH was used to determine the graft density, homogeneity and stability of modified surfaces, as well as the competition of PEO-ATH migration to the surface with self-aggregation of the PEO-ATH molecules during the coating process. X-ray photoelectron spectroscopy was used to investigate the surface chemical composition before and after ATH application. Analysis showed that PEO-ATH was strongly surface-bound at a final density of 15-200 pmol/cm(2), depending on the incubation concentration.

Antithrombin-heparin covalent complex reduces microemboli during cardiopulmonary bypass in a pig model.

Transcranial Doppler-detected high-intensity transient signals (HITS) during cardiopulmonary bypass (CPB) surgery have been associated with postoperative neurocognitive dysfunction, suggesting microemboli in the brain could be a contributing factor. HITS occur despite administration of unfractionated heparin (UFH). This study was done to determine whether antithrombin-heparin covalent complex (ATH), a more potent anticoagulant than heparin, can reduce HITS during CPB. In a pig CPB model, ATH, UFH, or UFH + antithrombin (AT) was intravenously administered to female Yorkshire pigs after sternotomy. Twenty minutes later, hypothermic CPB was initiated and continued for 1.25 hours, then normothermia was re-established for 45 minutes. Protamine sulfate was given to neutralize the anticoagulants, and pigs were allowed to recover. HITS were monitored using an arterial flow probe placed over the carotid artery. Compared with UFH (300 or 1000 U/kg), ATH reduced the number of HITS during CPB in a dose-dependent manner. AT (3 mg/kg) + UFH (300 U/kg) resulted in an intermediate HITS rate between UFH and ATH (2 mg/kg in terms of AT). Examination of brain sections for emboli formation confirmed that, similar to HITS, number of thrombi decreased in direct proportion to ATH dosage. These results support the hypotheses that the majority of HITS represent thromboemboli and that ATH reduces emboli formation during CPB.

Effect of covalent antithrombin-heparin on activated protein C inactivation by protein C inhibitor.

Protein C in its activated form (APC) limits thrombin generation. Protein C inhibitor (PCI) readily neutralizes APC. Heparin accelerates this reaction, which may complicate anticoagulant treatment in patients with varying APC generation potential. A potent anticoagulant conjugate of antithrombin and heparin (ATH) was prepared, and its effect on APC+PCI reactions was tested. Second order rate constants for APC+PCI reactions were measured by discontinuous rate experiments in the presence of heparin or ATH. Similarly, low molecular weight fractions of heparin (LMWH) and ATH (LMWATH) were tested, as was high molecular weight ATH (HMWATH). Mechanisms of heparin or ATH binding to APC or PCI were assessed using electrophoresis. While heparin gave a higher maximal APC inhibition rate compared to ATH, peak inhibition rate was achieved at comparatively lower ATH concentrations. Since LMWH was ineffective at enhancing APC inhibition by PCI, unfractionated heparin likely acts by bridging APC and PCI. Unlike heparin, ATH may conformationally activate either APC or PCI since LMWATH significantly catalyses APC inhibition. Binding studies showed that ATH readily associates with APC. Thus, although a small fraction of ATH efficiently catalyses APC inhibition by PCI, complete ATH preparations induce a decreased maximal rate of APC-PCI formation compared to unfractionated heparin.

Surface modification with an antithrombin-heparin complex for anticoagulation: studies on a model surface with gold as substrate.

Gold was used as a substrate for immobilization of an antithrombin-heparin (ATH) covalent complex to investigate ATH as a surface modifier to prevent blood coagulation. Three different surface modification methods were used to attach ATH to gold: (i) direct chemisorption; (ii) using dithiobis(succinimidyl propionate) (DSP) as a linker molecule and (iii) using polyethylene oxide (PEO) as a linker/spacer. The ATH-modified surfaces were compared to analogous heparinized surfaces. Water contact angles and X-ray photoelectron spectroscopy confirmed the modifications and provided data on surface properties and possible orientation. Ellipsometry measurements showed that surface coverage of DSP and PEO was high. ATH and heparin densities were quantified using radioiodination and quartz crystal microbalance, respectively. The surface density of ATH was greatest on the DSP surface (0.17 microg cm(-2)) and lowest on the PEO (0.05 microg cm(-2)). The low uptake on the PEO surface was likely due to the protein resistance of the PEO component. Using radioiodinated antithrombin (AT), it was shown that ATH-immobilized surfaces bound significantly greater amounts from both buffer and plasma than the analogous heparinized surfaces. Immunoblot analysis of proteins adsorbed from plasma demonstrated that surfaces chemisorbed with PEO, whether or not subsequently modified with ATH, inhibited non-specific adsorption. The immunoblot response for AT was stronger on the DSP-ATH than on the heparin surfaces, thus confirming the results from radiolabelling. The ATH surfaces again showed higher selectivity for AT binding than analogous heparin-modified surfaces, indicating the enhanced anticoagulant potential of ATH for biomaterial surface modification.