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Heparin-induced thrombocytopenia
Abstract
Heparin-induced thrombocytopenia (HIT), next to bleeding complications, is the most important side-effect of heparin therapy in cardiac patients and the most frequently found thrombocytopenia induced by medication. Two types of HIT are distinguished on the basis of both severity of disease, and pathophysiology: type I HIT is an early, transient, clinically harmless form of thrombocytopenia, due to direct heparin-induced platelet aggregation. Thromboembolic complications are usually not seen. No treatment is required. A normalization of platelet count even if heparin is continued is a usual observation. Type II HIT is more severe than type I HIT and is frequently complicated by extension of preexisting venous thromboembolism or new arterial thrombosis. The thrombocytopenia is caused by a pathogenic heparin-dependent IgG antibody (HIT-IgG) that recognizes as its target antigen a complex consisting of heparin and platelet factor IV. Type II HIT should be suspected when the platelet count falls to less than 100,000 per cubic millimeter or less than 50% of the base line value 5 to 15 days after heparin therapy is begun, or sooner in a patient who received heparin in the recent past. The clinical diagnosis of type II HIT can be confirmed by several sensitive assays. In cases of type II HIT, heparin must be stopped immediately. However, if the patient requires continued anticoagulant therapy for an acute event such as deep venous thrombosis, substitution of an alternative rapid-acting anticoagulant drug is often needed. In the authors experience Danaparoid sodium, a low-sulfated heparinoid with a low cross-reactivity (10%) to heparin, can be regarded as an effective anticoagulant in patients with type II HIT. Preliminary experiences with intravenous recombinant hirudin are also encouraging and suggest that this direct thrombin inhibitor will emerge as a valuable alternative treatment for patients who suffer from HIT.
... Type II HIT is an adverse immunemediated reaction due to antibodies formed against heparin-platelet factor 4 complexes, which is usually associated with thrombosis risk. It is more severe than type I HIT and should be suspected when patients show a reduction in the platelet count to less than 100,000 per cubic millimeter or more than 50% of the baseline value 5-15 days after initiation of heparin therapy [10,11]. The 4T's score (the severity of Thrombocytopenia, its Timing of heparin exposure, appearance of new Thrombosis, and differential diagnosis by exclusion of oTher causes) has been utilized as a clinical assessment tool to evaluate the likelihood of HIT [11,12]. ...
Background
Tirofiban is a nonpeptide glycoprotein IIb/IIIa receptor antagonist used widely in patients subjected to percutaneous coronary intervention. While the usage of tirofiban sets an important clinical benefit, severe thrombocytopenia can occur with use of this agent.
Case presentation
A 76-year-old Chinese man was admitted with 1-month history of sudden onset of chest tightness. He was diagnosed as having subacute inferior myocardial infarction, and percutaneous coronary intervention was performed. After the procedure, patient received tirofiban at 0.15 µg/kg/minute for 4 h. A blood sample was obtained for a complete blood count; severe thrombocytopenia was reported according to routine orders at our hospital. All antiplatelet drugs including tirofiban, aspirin, and clopidogrel were immediately discontinued. The patient received platelet transfusions and was treated with immunoglobulin G. Two days later, the patient’s platelet count had increased to 75 × 10 ⁹ /L. There was a significant improvement after day 5, and the platelet count was 112 × 10 ⁹ /L. Seven days after the acute thrombocytopenia, he was discharged with normal platelet count.
Conclusions
Clinicians should be particularly aware of tirofiban-induced thrombocytopenia in routine practice.
DNA-based devices are straightforward to design by virtue of their predictable folding, but they lack complex biological activity such as catalysis. Conversely, protein-based devices offer a myriad of functions but are much more difficult to design due to their complex folding. This study combines DNA and protein engineering to generate an enzyme that is activated by a DNA sequence of choice. A single protein switch, engineered from nanoluciferase using the alternate-frame-folding mechanism and herein called nLuc-AFF, is paired with different DNA technologies to create a biosensor for specific nucleic acid sequences, sensors for serotonin and ATP, and a two-input logic gate. nLuc-AFF is a genetically encoded, ratiometric, blue/green-luminescent biosensor whose output can be quantified by a phone camera. nLuc-AFF retains ratiometric readout in 100% serum, making it suitable for analyzing crude samples in low-resource settings. This approach can be applied to other proteins and enzymes to convert them into DNA-activated switches.
The clinical effects of heparin are meritorious and heparin remains the anticoagulant of choice for most clinical needs. However, as with any drug, adverse effects exist. Heparin-induced thrombocytopenia (HIT) is an important adverse effect of heparin associated with amputation and death due to thrombosis. Although the diagnosis and treatment of HIT can be difficult and complex, it is critical that patients with HIT be identified as soon as possible to initiate early treatment to avoid thrombosis.
Clinical outcomes of 1,478 danaparoid treatment case reports for HIT (involving 1,418 patients) treated between 1982 and mid-2004 are analysed. Treatment in 1,291 episodes was for current HIT. Thromboembolism due to HIT was present in 39.4%. The patients include 33 children and 32 pregnancies. Two hundred twenty-six patients required extra-corporeal circuit use for renal failure, 241 patients had a concomitant thrombophilic disorder, and 351 major operations were performed. Clinical outcomes were assessed during danaparoid treatment (range one day to 3.5 years) plus three months of follow-up. Of the danaparoid-treated patients 83.8% survived; 63.7% had no or minor adverse events and 20.1% suffered serious non-fatal adverse events. New thromboses occurred during 9.7% of treatment episodes, and 16.4% of treatment episodes had an inadequate treatment response (i. e. developed one or more of the following: new/extended thrombosis, persistent/new platelet count reduction, unplanned amputation during treatment and follow-up). Major bleeding was reported in 8.1% of treatment episodes. Clinical cross-reactivity of danaparoid (new/persistent platelet count reduction and/or new/extended thrombosis) was confirmed serologically in 23 of 36 patients with positive pretreatment serological danaparoid cross-reactivity and in 22 of 32 additional patients tested at the time of the new event, i.e. a total of 45 patients (3.2%). Clinical outcomes of these case reports of patients given danaparoid because of suspected or confirmed HIT appear to be comparable with those reported by others who used direct thrombin inhibitors, especially when a sufficient danaparoid dosing intensity was used in patients with isolated HIT. Post-operative bleeding limits danaparoid use for cardiopulmonary by-pass surgery. Routine clinical and platelet count monitoring are required to minimise adverse reactions due to cross-reactivity.
In order to determine the efficacy and safety of ancrod, a rapid acting defibrinogenating drug, for patients with heparin-induced thrombocytopenia, 11 consecutive patients who required anticoagulant therapy because of venous thromboembolism and who developed acute heparin-induced thrombocytopenia or had a history of heparin-induced thrombocytopenia were treated with ancrod. Heparin therapy was discontinued (in patients receiving heparin) and ancrod started at a dose of 1 to 2 U/kg every 24 hours with subsequent daily doses adjusted to maintain fibrinogen levels between 0.5 and 1.0 g/L. Ancrod was continued until warfarin had become effective. The platelet count increased to more than 150 x 10(9)/L within 2 to 10 days in all thrombocytopenic patients. Two patients with a history of heparin-induced thrombocytopenia maintained normal platelet counts while receiving ancrod. Two patients had recurrent venous thrombosis while receiving warfarin, 10 days after ancrod was discontinued: one of these patients had metastatic pancreatic carcinoma and developed phlegmasia cerulea dolens and the other patient developed a venographically proven extension of her deep venous thrombosis. One patient suffered a bleeding episode into the thigh with a 16-g/L decrease in her hemoglobin level while receiving ancrod therapy. No other side effects were noted. Our experience indicates that ancrod therapy is a reasonable approach for patients with heparin-induced thrombocytopenia who require anticoagulant therapy.
Studies were performed to determine the cross-reaction rate of the heparin-dependent antibody with Org 10172, a new low molecular weight heparinoid, and to investigate the effect of Org 10172 on platelet activation induced by the antibody. The plasmas of 17 patients with thrombocytopenia induced by standard heparin were shown, by platelet aggregation studies, to contain the heparin-dependent antibody. Of these 17 patient plasmas, only three cross-reacted with the heparinoid, producing a cross-reaction rate of 18%. When Org 10172 was added to a reaction mixture containing normal platelet-rich plasma, patient plasma, and standard heparin with non-cross-reacting plasmas, it inhibited platelet aggregation and thromboxane B2 production induced by the antibody, provided that the ratio of Org 10172 concentration (anti-Xa U/mL) to standard heparin concentration (IU/mL) exceeded 2.5 to 5.0. This inhibitory effect was observed only with platelet activation mediated by the antibody, but not by collagen (2 micrograms/mL) or ADP (5.0 mumol/L). Additionally, three of 17 patients with serious thrombosis, whose plasma showed no cross-reaction with the heparinoid, received Org 10172 treatment with a good response in each case. These findings suggest that Org 10172 may be a useful drug for the treatment of heparin-induced thrombocytopenia.
This report describes studies into the pathophysiology of heparin-induced thrombocytopenia. The IgG fraction from each of nine patients with heparin-induced thrombocytopenia caused heparin-dependent platelet release of radiolabeled serotonin. Both the Fc and the Fab portions of the IgG molecule were required for the platelet reactivity. The platelet release reaction could be inhibited by the Fc portion of normal human or goat IgG, and patient F(ab')2, but not F(ab')2 from healthy controls. These results suggested that the Fab portion of IgG binds to heparin forming an immune complex and the immune complexes initiate the platelet release reaction by binding to the platelet Fc receptors. To directly challenge this hypothesis, we preincubated the serotonin-labeled platelets with the monoclonal antibody against the platelet Fc receptor (IV.3). This monoclonal antibody completely inhibited the release reaction caused by heparin and patient sera, as well as heat aggregated IgG, but did not block collagen or thrombin-induced platelet release. Heparin-dependent platelet release also could be inhibited in vitro by the addition of monocytes and neutrophils, but not by red cells, presumably because the Fc receptors on the phagocytic cells have a higher binding affinity for IgG complexes than do platelets. Platelets from patients with congenital deficiencies of specific glycoproteins Ib and IX (Bernard-Soulier syndrome) and IIb and IIIa (Glanzmann's thrombasthenia) displayed normal heparin-dependent release indicating that the release reaction did not require the participation of these glycoproteins. These studies indicate that heparin-induced thrombocytopenia is an IgG-heparin immune complex disorder involving both the Fab and Fc portion of the IgG molecule.
Heparin and heparin oligosaccharides prepared by nitrous acid depolymerization were fractionated by affinity chromatography on immobilized antithrombin and by gel chromatography. The anticoagulant activities of high affinity heparin of Mr greater than or equal to 7,800 could be readily neutralized by the plasma protein histidine-rich glycoprotein (see also Lijnen, H.R., Hoylaerts, M., and Collen, D. (1983) J. Biol. Chem. 258, 3803-3808), whereas oligosaccharides falling below 18 saccharide units (Mr 5,400) became increasingly resistant to neutralization. An octasaccharide with characteristic marked ability to accelerate the inactivation of Factor Xa by antithrombin retained greater than 50% of its activity even at a histidine-rich glycoprotein/oligosaccharide molar ratio of 500:1. Histidine-rich glycoprotein, like the platelet-derived heparin neutralizing protein platelet factor 4 (Lane, D.A., Denton, J., Flynn, A.M., Thunberg, L. and Lindahl, U. (1984) Biochem J. 218, 725-732), therefore requires interaction with saccharide sequences in addition to the antithrombin-binding pentasaccharide of heparin in order to efficiently express its antiheparin activity. Heparan sulfate isolated from pig intestinal mucosa (HS I, Mr approximately 20,000) and from human aorta (HS II, Mr approximately 40,000) exhibited anti-Factor Xa activities of 180 and 20 units/micromol [corrected], respectively. A fraction corresponding to about 5% of HS I bound with high affinity to immobilized antithrombin and contained all of the anticoagulant activity of the starting material. While these heparan sulfates were readily neutralized by platelet factor 4, they were relatively resistant to neutralization by histidine-rich glycoprotein, although complete neutralization could be attained in the presence of molar excess of this protein. These findings may be of importance in relation (a) to the functional role of endogenous anticoagulant polysaccharides at the vascular wall and (b) to clinical situations in which heparin or heparin-related compounds are administered as exogenous anticoagulants.
Heparin-induced thrombocytopenia (HIT) with thrombosis occurs in about 1 in 2,000 heparin-treated patients. The arterial or venous thromboses may threaten life and limb hence alternative anticoagulation is needed. Some alternative treatments are possible i.e. LMWH, Ancrod, prostacyclin analogues, Dextran, aspirin and oral anticoagulants, but each has its drawbacks. This report reviews treatment of HIT patients with Orgaran (Org 10172), a low molecular weight heparinoid.
Because of its proven antithrombotic activity Orgaran was used to treat 230 HIT patients. One hundred and fifty, nine patients presented with at least one thrombotic problem, which in 88 was due to the heparin use. 92.8% of the patients were considered to have adequately responded to Orgaran during the treatment period. Fifty-nine deaths (25.7%) occurred of which 7 (3.0%) were attributed to Orgaran use. The remaining 52 deaths, 27 of which occurred after Orgaran treatment was successfully terminated, were due to the severe underlying disorders in these patients. These results and the lower cross-reactivity rate (≈10%) with the heparin-induced antibody compared with that of the LMWH (>90%) suggest that although problems remain, Orgaran can be a valuable alternative treatment for patients who suffer from HIT and who require anticoagulation.
The purpose of this study is to determine the incidence of heparin-associated thrombocytopenia (HAT) for various subgroups of heparin exposed patients and the impact of study quality on the reported incidence. Articles were identified using a Medline search, a manual search of the Index Medicus, and a review of article references. Key data included heparin type, administration route, indication, treatment duration, outcome criteria, incidence, and platelet count reliability. The pooled incidence estimate in studies requiring a repeatedly abnormal platelet count was compared with estimates from studies not requiring a repeated platelet count. The results showed that there were no adequately designed studies to estimate the incidence of HAT-related thrombosis or hemorrhage. The pooled incidence of HAT in studies requiring a reproducibly lowered platelet count (<100,000/[mu]L) was 3/281 (1.1%) with intravenous porcine heparin and 4/140 (2.9%) with intravenous bovine heparin. This difference was not staistically significant. The incidence of HAT with intravenous bovine heparin was significantly lower in studies that required a repeated platelet count. The incidence of HAT with heparin administered subcutaneously was small (0%) and in those studies requiring a repeatedly abnormal platelet count, there was no difference between porcine and bovine heparin. The authors concluded that the incidence of HAT is <3% with intravenous heparin and extremely low for subcutaneous heparin. Study quality may influence the reported incidence of HAT.
Heparin is a widely used and valuable agent in the management of many thrombotic disorders involving both the arterial and the venous system. Although it is the oldest of the modern anticoagulant drugs, its mode of action and specific effect on the clotting mechanism in vivo have not yet been clearly defined.1 It is, however, a potent and effective agent and possesses certain distinct advantages over the coumarin drugs when used in combination with surgical treatment. Its rapid action and prompt neutralization by protamine are desirable qualities in many circumstances.
Except for the rare instances of allergic reactions, complications or adverse effects reported from the use of heparin have been due to hemorrhage. Recently we have been using heparin more frequently as the anticoagulant of choice in the treatment of acute thromboembolic disorders or in conjunction with direct surgery on the arteries and veins. There has been a coincident
Twenty-two patients developed significant thrombocytopenia (5,000 to 96,000/cu mm; mean, 29,000/cu mm) while receiving prophylactic or therapeutic heparin. Seventeen of them developed serious thrombohemorrhagic complications which accelerated the deaths of six and contributed to the late death of one. Cessation of heparin therapy led to an immediate remission of the thrombohemorrhagic complications and thrombocytopenia, with no patient who was not already moribund dying, once appropriate therapy had been instituted. Platelet-count monitoring is recommended for all patients receiving heparin for more than 6 days, with cessation of heparin therapy mandatory for the successful management of patients with this disorder. Evidence is presented for an immunologic etiology for this disorder.
In a group of 52 patients receiving continuous intravenous heparin, 16 developed thrombocytopenia (platelets less than 100 000/mm3). Ten of the 16 patients who had thrombocytopenia had elevated titers of fibrinogen-fibrin degradation products, and five of these 10 patients also had a reduction in plasma fibrinogen. The abnormalities disappeared after the heparin preparation was discontinued. These occurrences could not be attributed to drugs other than heparin, to the dose of heparin administered, or to prior exposure to heparin. The mechanism by which the heparin preparation may induce these changes is not known.
Thrombocytopenia has recently been observed in a surprising number of patients during treatment with heparin. A report of five cases appears in this issue of the Journal. Discovered in 1915, heparin has been extensively used in clinical medicine since the mid-1930's. Apart from hemorrhagic complications attributable to the induced coagulation defect, untoward reactions have been infrequent. Rarely, patients with a past history of allergic disease have had immediate hypersensitivity reactions manifested by urticaria, rhinitis, asthma, fever, cyanosis, diaphoresis and hypotension. In some cases these reactions could be averted by use of heparin from another animal source. Severe thrombocytopenia occurring . . .
Progressive thrombocytopenia may develop in as many as 5% of patients receiving heparin anticoagulation. In these patients, the risk of thromboembolic complications as well as continued thrombocytopenia necessitates discontinuation of heparin and initiation of an alternative anticoagulant when indicated. The heparinoid Lomoparan (Org 10172) is a mixture of several non-heparin low molecular weight glycosaminoglycans with proven anticoagulant efficacy that is generally non-reactive with platelets in the presence of plasma from patients with heparin induced thrombocytopenia, whereas standard heparin will induce platelet aggregation. We evaluated the role of heparinoid as a potential alternative anticoagulant in patients with heparin induced thrombocytopenia. During a 6 month period, we identified six patients with heparin induced thrombocytopenia who required an alternative parenteral anticoagulant, four as primary treatment for specific medical problem, and two as anticoagulation during a necessary surgical procedure. Heparinoid was used successfully in both medical and surgical patients requiring parenteral anticoagulation. In no case was there an exacerbation of the thrombocytopenia nor thromboembolic complications while on heparinoid therapy. Three of our patients sustained hemorrhagic complications, predominantly in the post-surgical setting in association with elevated anti-factor Xa levels and additional anticoagulant agents. We feel that these results confirm the utility of heparinoid anticoagulation in a select subset of patients with heparin induced thrombocytopenia who require continued parenteral anticoagulation.
Certain monoclonal antibodies (MoAbs) specific for platelet membrane glycoproteins are known to be capable of activating platelets, and it is generally thought that platelets from normal subjects are equally susceptible to stimulation by such MoAbs. We found that platelets from 20 normal donors varied significantly in their sensitivity to three IgG1 murine MoAbs specific for membrane glycoproteins CD9, GPIV (CD36), and the GPIIb/IIIa complex (CD41), respectively. The response of platelets to these MoAbs was blocked by prior addition of MoAb IV.3 specific for the Fc gamma RII receptor, indicating that activation was Fc receptor mediated. Platelets that responded poorly to these MoAbs failed to bind the MoAb 41H.16, specific for the "responder" form of Fc gamma RII, but platelets that responded well reacted with this MoAb. The average number of Fc gamma RII receptors on platelets from "responders" and "non-responders" was approximately the same. However, the number of Fc gamma RII receptors expressed influenced sensitivity of a subgroup of "responder" platelets to the anti-CD41 MoAb. These platelets were judged on the basis of MoAb binding studies to be heterozygous for the two alleles of Fc gamma RIIA. In contrast to their varying sensitivity to IgG1 MoAbs, members of the platelet panel responded equally well to 50H.19, an IgG2a MoAb specific for CD9, and these responses could not be blocked by MoAb IV.3 in the presence of plasma. This appears to be because of dual actions of 50H.19 on platelets: one FcR-dependent and the other complement-dependent. Our findings confirm previous reports that certain IgG1 MoAbs activate platelets through binding of their Fc domains to Fc gamma RII receptors and demonstrate that this response is influenced both by Fc gamma RII phenotype and (in the case of the anti-CD41 MoAb) by the number of Fc gamma RII receptors expressed. The failure of nonresponding platelets to bind detectable amounts of MoAb 41H.16, which is thought to recognize all Fc gamma RII receptors except for one allele of the Fc gamma RIIA gene, is consistent with the possibility that Fc gamma RIIA gene products, but not Fc gamma RIIB or Fc gamma RIIC gene products, are expressed on platelets.
Heparin-induced thrombocytopenia is a common immune-mediated drug reaction that can be complicated by life-threatening arterial thrombosis. The diagnosis can be confirmed by demonstrating heparin-dependent release of radiolabeled serotonin from washed normal platelets in the presence of patient serum. However, certain serum samples from these patients produce 14C-serotonin release from some but not other normal donor platelets. We investigated this problem of donor platelet variability by studying the reactivities of 10 serum samples from patients with heparin-induced thrombocytopenia with platelets from 10 normal donors (100 serum and platelet combinations). We observed a marked variability in reactivity for patient serum and platelets from normal donors; this initially appeared random. However, closer examination indicated that the reactivities varied hierarchically. Because heparin-induced thrombocytopenia is caused by binding of heparin-dependent IgG to platelet Fc receptors, we examined whether platelet Fc receptor number or function explained the variability in platelet reactivity. We observed that platelet Fc receptor function, as measured by platelet release associated with heat-aggregated IgG, was highly correlated with platelet reactivity to heparin-induced thrombocytopenia serum samples. No significant correlation, however, was found between Fc receptor number and platelet response. Reaction of murine monoclonal antibodies that activate human platelets by means of the platelet Fc receptors was not predictive of platelet reactivity to heparin-induced thrombocytopenia serum.(ABSTRACT TRUNCATED AT 250 WORDS)
The response of megakaryocytes and platelets to the administration of recombinant human interleukin-6 (IL-6) was investigated in normal and sublethally irradiated dogs. IL-6 was administered for 2 weeks at doses of 10 to 160 micrograms/kg/d to normal animals to assess dose-response and toxicity. Subsequently, 40, 80, or 160 micrograms/kg/d for 2 weeks was administered to animals treated with 200 cG total body irradiation. Analysis of normal dogs showed a significant increment in the platelet count detectable approximately 11 days after initiation of IL-6 at all administered doses. Large platelets greater than 6.3 microns in diameter were observed 1 day after beginning IL-6, progressively increasing to as many as 19.1% of the total circulating platelets by day 10. The ploidy distribution of the marrow megakaryocytes did not differ from the normal at doses of less than or equal to 80 micrograms/kg/d, but at 160 micrograms/kg/d, a shift toward higher ploidy cells was noted. No change in total white count was noted; however, a decrease in hematocrit was seen at all doses. In the irradiated animals, the platelet count recovered earlier in the IL-6-treated dogs than in the controls, but no consistent change in the ploidy distribution was observed irrespective of dose. Large platelets were also noted in the treated animals, comprising up to 6.9% of the total platelet count. Fibrinogen levels were elevated to greater than 4 times normal. A significant decrease in hematocrit was seen in all animals, while no consistent change was noted in the white count. Elevations in serum cholesterol, triglycerides, and alkaline phosphatase, together with a decline in serum albumin were observed in all the treated animals (both normal and irradiated), but clinical symptoms were observed only in the dogs receiving greater than or equal to 80 micrograms/kg/d. The data show that IL-6 alone is capable of enhancing platelet recovery in dogs with bone marrow suppression.
Heparin-associated thrombocytopenia (HAT) is a severe complication of heparin therapy. Its diagnosis is difficult. Conventional assays employ platelet aggregometry (PAA) and/or 14C-serotonin release (SRA) which are either insensitive (PAA) or require radioactive tracers (SRA). We here describe a newly developed sensitive and rapid assay based on visual evaluation of heparin-induced platelet activation (HIPA) in microtiter wells. Using sera of 34 patients with clinically suspected HAT we found the HIPA assay to be as sensitive as the SRA and superior to PAA. The HIPA assay allows investigation of crossreactivity with different types of heparins, low molecular weight (LMW) heparins and heparinoids. Three patients who required further parenteral anticoagulation and in whom the HIPA assay was negative before treatment with the LMW heparinoid Org 10172, were treated with this new heparinoid without adverse reactions. We conclude that the HIPA assay may be a useful tool for differential diagnosis and therapy in patients with HAT.
Heparin-induced thrombocytopenia and thrombosis is associated with a significant incidence of morbidity and mortality. Prompt recognition of this complication and immediate withdrawal of heparin therapy are imperative. This report describes a case of heparin-induced thrombosis and thrombocytopenia with major vascular insufficiency of the extremities. This is the first reported instance of the use of intravenous streptokinase for the treatment of heparin-induced venous thrombosis.
It is common practice to begin anticoagulant treatment of deep-vein thrombosis with a 10-day course of intravenous heparin, with warfarin added on day 5 to 10 and continued for several months. We performed a randomized, double-blind trial comparing a shorter course of continuous intravenous heparin (5 days, with warfarin sodium begun on the first day) with the conventional 10-day course of heparin (with warfarin sodium begun on the fifth day) in the initial treatment of 199 patients with acute proximal venous thrombosis documented by venography. The frequency of objectively documented recurrent venous thromboembolism was low and essentially the same in the two groups (7.1 percent in the short-course group vs. 7.0 percent in the long-course group). Because the observed difference between the groups was 0.1 percent in favor of the long-course group, it is unlikely (P less than 0.05) that a true difference in favor of this group would be greater than 7.5 percent; the difference could be as much as 7.3 percent in favor of the short-course group. Major bleeding episodes were infrequent, and the rate was similar in both groups. We conclude that a five-day course of heparin is as effective as a 10-day course in treating deep venous thrombosis. Furthermore, using the shorter course would permit earlier discharge from the hospital and thus offer substantial cost savings.
A case of skin necrosis at the sites of injection of subcutaneous heparin is described. The patient went on to develop heparin-induced thrombocytopenia and pulmonary embolism. Review of the previously described cases of heparin-associated skin necrosis reveals that this sequence of events is not uncommon.
Two unfractionated heparins (UH), a porcine intestinal mucosal heparin (PIM), a bovine lung heparin (BLH) and a low molecular weight heparin (LMWH), CY 222, were assessed for their capacity to enhance platelet aggregation in vitro. Their potential proaggregatory effect was investigated in four systems: (a) enhancement of submaximal platelet aggregation induced by conventional agonists in platelet rich plasma and (b) in whole blood; (c) reversal of inhibition of platelet aggregation induced by iloprost, a stable analogue of prostacyclin; (d) the direct aggregatory effect of these anticoagulants on hyperactive platelets prepared from patients with severe peripheral vascular disease or anorexia nervosa. Whereas BLH and PIM, at therapeutic concentrations, had a proaggregatory effect in all four systems, CY 222 had no significant effect when compared with the controls. BLH was more potent than PIM in three of the four systems studied. These observations confirm that conventional UH are more proaggregatory than LMWH, and thus the latter may be potentially safer. These observations are also consistent with the fact that BLH administration causes thrombocytopenia more frequently than PIM. The direct activation by UH of platelets from patients not previously exposed to heparin also challenges the hypothesis that heparin-induced platelet activation and thrombocytopenia is solely mediated by classical heparin-dependent immune mechanisms.
Heparin-associated thrombocytopenia with thrombosis (HATT) is fatal in 29% and leads to limb amputation in another 21% of patients. Patients with arterial thrombosis do worse than do those with venous thrombosis alone. Heparin-associated thrombocytopenia is mediated through IgG or IgM immunoglobulin fractions and is believed to be an immune phenomenon, with heparin acting as a hapten. In addition, endothelial injury may be responsible for the development of thrombosis. Heparin-induced platelet aggregation persists for weeks to months after its withdrawal in these patients. Acute management of HATT includes surgical thrombectomy, thrombolytic therapy, dextran, ancrod, low-molecular-weight heparin, and antiplatelet agents, but overall results remain unsatisfactory. We report the use of plasmapheresis, along with aspirin and dextran, in a patient with HATT. The patient experienced pain relief in 1 day; the heparin-associated platelet aggregation test became negative in 5 days, and there was functional salvage of the affected limb. We suggest that plasmapheresis may be an effective therapy in the management of HATT.
Heparin-induced thrombocytopenia and thrombosis was diagnosed in a 50-year-old man undergoing a repeat heart operation after heparinization led to microemboli and an eventual left transmetatarsal amputation. A third heart operation was aborted when anticoagulation with low molecular weight heparin produced intraoperative thrombi. The patient was referred to Toronto where ancrod (Arvin) was used to lower plasma fibrinogen level, allowing successful repair of a ventricular septal defect using cardiopulmonary bypass support. The patient made an uneventful recovery.
Evidence has recently been presented that a 40,000 dalton membrane sialoglycoprotein (p40) shared by monocytes and granulocytes serves as the human platelet receptor for aggregated IgG. We now report that the platelets of normal donors exhibit stable quantitative differences in the expression of this receptor molecule, as determined by flow cytometry using fluorescent staining with murine monoclonal antibody to p40 (mab IV.3). These inter-donor differences were reproducible on repeated testing over at least 4 mo. In concurrent assays, the binding of mab IV.3 to each donor's platelets was highly correlated with the binding of heat-aggregated human IgG, also assayed by flow cytometry. The biological relevance of this quantitative variation in IV.3 binding is suggested by its reproducible correlation with platelet responsiveness to aggregated IgG measured by aggregometry. Such stable quantitative variation in platelet Fc receptor expression among individual humans could contribute to differences in severity of certain pathologic processes initiated by IgG-containing immune complexes.
Use of urokinase to treat heparin-associated thrombocytopenia and thrombosis in one patient is described, and various treatments proposed for this syndrome are discussed. A 56-year-old man received an intravenous bolus dose of heparin sodium at his local hospital and was transferred to another institution for treatment of suspected pulmonary embolism; he had received heparin two weeks earlier during coronary angiography. The patient's platelet count was reported to be normal before heparin administration. When embolism was confirmed, heparin was discontinued and streptokinase was given for 24 hours. Heparin infusion was then restarted at 1000 units/hr and continued for four days. Platelet count on admission to the second hospital was 47,000/cu mm; 12 hours later it was 19,000/cu mm, and it remained low despite platelet transfusions. Five days after admission, deep-vein thrombosis developed in the left leg. Heparin was discontinued and urokinase and warfarin were started. Urokinase was infused at 320,000 IU/hr for 12 hours and continued at dosages of 160,000-320,000 IU/hr for a total of 40 hours. The initial warfarin sodium dose was 15 mg, followed by a dosage of 10 mg/day. Symptoms of deep-vein thrombosis improved within 12 hours and platelet count increased after heparin was discontinued. If it is recognized early enough, heparin-associated thrombocytopenia can be reversed by discontinuation of heparin. Transfusions of platelets are of little benefit. Dipyridamole, cyclo-oxygenase inhibitors such as aspirin, and protamine sulfate may be useful. Long term anticoagulation with warfarin is recommended to prevent recurrent thrombosis.(ABSTRACT TRUNCATED AT 250 WORDS)
Although thrombocytopenia occurs in approximately 10% of medical patients who receive heparin, this complication has not been described in neurosurgical patients. We report the clinical course of two patients who in the immediate postoperative period developed heparin-associated thrombocytopenia that resulted in significant morbidity. In these two cases, the origin of the heparin was in "flush" solutions used to maintain the patency of indwelling vascular catheters and was infused at a dose of 250 to 500 units/day. The minimal daily dose previously reported to result in thrombocytopenia is 9000 units/day administered in divided doses subcutaneously. The case reports indicate that heparin in "flush" solutions should be considered as a cause for unexpected thrombocytopenia and that platelet counts should be monitored in patients receiving heparin in any amount.
Cutaneous necroses, acute renal failure and an adrenocortical insufficiency appeared during heparin therapy in a 47 year old patient with myocardial infarction. The thrombocytes fell to 73,000/microliter and displayed intensified spontaneous aggregation. In histological investigation of the cutaneous necroses, intensive thromboses of the cutaneous and subcutaneous blood vessels were found. The findings indicate a thromboembolic etiology of the acute renal failure and the adrenocortical insufficiency. This case involves a complex example of a heparin-induced thrombopenia with thromboembolic complications.
Heparin-induced thrombocytopenia can be a serious and difficult-to-diagnose complication of heparin therapy. Serum from patients with heparin-induced thrombocytopenia can cause heparin-dependent platelet aggregation, but the low sensitivity and specificity of this test limit its clinical usefulness. In this report we describe an assay for heparin-induced thrombocytopenia that is both sensitive and specific. The improvement in the assay was accomplished by measuring platelet release instead of aggregation and by measuring platelet release at two heparin concentrations. The rationale for the use of two heparin concentrations was that sera from patients with heparin-induced thrombocytopenia caused release at therapeutic but not at high concentrations of heparin. Twenty-eight sera samples from patients suspected of having heparin-induced thrombocytopenia and 573 controls were coded and tested in the assay. The patients with possible heparin-induced thrombocytopenia were ranked according to the likelihood of having this disorder by using prospectively defined criteria. The test had a high specificity (99%); only one of 573 controls showed a positive result. The test was also very sensitive, and the likelihood of a positive test result was directly correlated with the clinical likelihood of the patient having heparin-induced thrombocytopenia. Six of six patients with definitive heparin-induced thrombocytopenia had positive test results, whereas zero of four patients in whom the diagnosis was unlikely had positive test results. The two-point test for heparin-induced thrombocytopenia represents a sensitive and specific test for this disorder. This test may be useful not only in confirming the diagnosis of this disorder but also may provide information about its pathogenesis.
We have shown that heparin and heparin fractions cause in vitro platelet aggregation in a large portion of a normal population. Furthermore, this aggregation occurs in a concentration-dependent manner and is not related to the anti-Xa activity of heparin or its fractions. In addition, it appears that at least part of the mechanism by which heparin induces aggregation is through the production of thromboxane. However, this is not the sole mechanism, since approximately 20% aggregation still occurs when thromboxane production is totally inhibited or the thromboxane receptor is completely blocked. Furthermore, although protamine (at the concentrations used) completely neutralizes the anticoagulant activity of heparin, it does not always completely inhibit the platelet aggregating activity of heparin. Finally, we have shown that heparin alone promotes thromboxane production and PF4 release in a whole blood system. Additional studies are needed to characterize further the mechanisms of heparin-induced platelet aggregation.
This report concerns 34 cases of heparin-associated thrombocytopenia in which standard heparin has been systematically replaced by LMW heparin CY 216 Choay. There were 21 women and 13 men, mean age, 69 years. Twenty-six of the 34 cases had thrombotic complications. All of the patients were treated by standard heparin of porcine mucosal origin, in most cases for prevention of deep vein thrombosis and pulmonary embolism. Twenty-six cases occurred along with orthopedic and traumatologic surgery (especially for total hip replacement, 15 cases). Four cases involved vascular surgery and three involved medical thrombotic disease. Standard heparin treatment was always replaced by LMW heparin CY 216. Initial doses were 0.30 ml three times daily, later increased to obtain global hypocoagulability. Surgical procedures (embolectomy and vena cava filter) were carried out when necessary. Five patients had thrombolytic treatment (urokinase) in conjunction with LMW heparin. The overall results were 31 recoveries, but with seven severe sequelae (three amputations and four hemiplegias) most often attributable to the first ischemic attack, and three deaths. For the last 16 patients, indirect platelet aggregation tests were performed (control platelet-rich plasma plus patient platelet-poor plasma plus LMW heparin): nine cases had negative tests, with nine recoveries and seven cases had positive tests, with five recoveries and two deaths.(ABSTRACT TRUNCATED AT 250 WORDS)
Two patients receiving intravenous heparin for pulmonary emboli developed disseminated intravascular coagulation during therapy. Both patients were receiving adequate anticoagulation before the onset of this syndrome. Mechanisms that might cause or prolong disseminated intravascular coagulation during heparin therapy are proposed.
Eleven patients in whom thrombocytopenia developed during heparin therapy were studied. Six patient (group 1) had severe thrombocytopenia with delayed onset and five of these patients had thromboembolic complications. A serum factor which induced heparin-dependent thromboxane B2 synthesis, 14C-serotonin release, and platelet aggregation was found in all patients in group 1. The serum factor was shown to be IgG. These findings suggest that the mechanism of the severe thrombocytopenia secondary to heparin therapy is immunological and the associated thromboembolic complications may be attributed to in-vivo activation of the platelet prostaglandin pathway and platelet aggregation induced by the heparin-dependent antibody. The five patients in group 2 had mild symptomless thrombocytopenia with early onset. In this group, the heparin-dependent antibody was not found and the mechanism of the thrombocytopenia is probably a direct action of heparin on platelets.
Porcine intestinal mucosal heparin induced aggregation of platelets in citrated platelet-rich plasma and enhanced platelet aggregation and serotonin secretion induced by other agents. This action of heparin was blocked by substances that elevate platelet cyclic AMP and by EDTA but not by inhibitors of platelet cyclooxygenase. The effect was not inhibited by apyrase or by N-amylthio-5'-AMP and therefore did not require the action of ADP, nor was there activation of platelet phospholipase. Platelet aggregation by heparin required a plasma cofactor different from the cofactor required for ristocetin. Fractionation of heparin yielded preparations that varied in molecular weight and, within a given molecular weight fraction, in affinity for antithrombin III. Fractions of high molecular weight (average 20,000) were more reactive with platelets than were fractions of low molecular weight (7,000). Anticoagulant activity did not parallel the platelet reactivity of heparin fractions. Among high molecular weight fractions, preparations of high or low antithrombin affinity were equally active in induction of platelet aggregation. In low molecular weight fractions, there was an inverse relationship between platelet reactivity and anticoagulant activity in normal platelet-rich plasma, but, in platelet-rich plasma depleted of antithrombin, low molecular weight fractions of high and low antithrombin affinity reacted equally with platelets. These results suggest that formation of an antithrombin-heparin complex protected platelets from aggregation by heparin. Selection of heparin fractions of low molecular weight and high antithrombin affinity may improve anticoagulant therapy and development of thromboresistant heparin-coated artificial materials.
Heparin-associated thrombocytopenia is a relatively common complication of heparin therapy occurring in approximately 5% of the patients who receive this drug. The incidence is higher with bovine heparin then with porcine heparin. Onset of heparin-associated thrombocytopenia usually occurs 6 to 12 days after initiation of treatment and by itself has a low morbidity. Heparin-associated thrombocytopenia plus arterial thrombosis can cause major complications including stroke, heart attack, and death. The incidence of heparin-associated thrombocytopenia plus arterial thrombosis is lower than that for heparin-associated thrombocytopenia alone. The diagnosis of heparin-associated thrombocytopenia remains one of exclusion, but testing for the presence of a heparin-dependent platelet-aggregating factor may prove to be useful. Analysis of the time of onset suggests a strategy for prevention. Oral anticoagulants could be started concomitantly with the heparin so that it could be discontinued in several days. This approach may prevent most episodes of heparin-associated thrombocytopenia.
The frequency and characteristics of thrombocytopenia resulting from administration of amrinone, a new inotropic and vasodilator agent, was evaluated in 43 patients. Thrombocytopenia attributable to amrinone developed in eight patients (18.6%). The thrombocytopenia was due to accelerated peripheral loss of platelets. There appeared to be a dose relationship with regard to the rapidity of onset and degree of thrombocytopenia. Although platelet-associated IgG levels were elevated when measured in patients with thrombocytopenia, the clinical features were suggestive of a direct, perhaps nonimmunologic effect of amrinone on platelets. Thrombocytopenia was mild in most cases and bleeding attributable to thrombocytopenia did not occur. Several patients continued amrinone therapy over long periods despite low platelet counts, showing that mild to moderate thrombocytopenia is not necessarily an indication that therapy should be discontinued, but that platelet counts should be observed closely.
To determine if interleukin-6 (IL-6) administration influences platelet function, platelet activation was analyzed sequentially in IL-6-treated (80 micrograms/kg/d) and control dogs. Platelet activation was determined in whole blood by flow cytometry by quantitating the binding of a monoclonal antibody to platelet surface P-selectin after stimulation with graded doses of thrombin. Administration of IL-6 resulted in a twofold decrease in the thrombin concentration required for induction of half-maximal P-selectin expression (ED50) compared with control animals. The ED50 returned to normal after cessation of IL-6 administration. As measured by P-selectin expression, enhanced responsiveness to the strong agonist platelet activating factor (PAF) was also observed in the IL-6-treated dogs. IL-6 had no effect on the susceptibility of platelets to thrombin activation when incubated with anticoagulated dog blood. The data show that, in addition to augmenting the platelet count in normal dogs, IL-6 enhances the sensitivity of platelets to activation in response to thrombin and PAF.
Heparin‐induced thrombocytopenia is a rare but severe complication of heparin therapy that can result in severe venous or arterial thromboembolic events and whose treatment remains partially unanswered. Recombinant hirudin is potentially effective as an antithrombotic treatment in the management of heparin‐induced thrombocytopenia, given its potent antithrombin effects without known interaction with platelets. We report the results obtained with intravenous recombinant hirudin (HBW 023) administered on a compassionate basis to patients suffering from heparin‐induced thrombocytopenia.
Six patients suffering from heparin‐induced thrombocytopenia were submitted to intravenous recombinant hirudin (HBW 023) administered at a dose of 0.05 mg/kg/hr after an initial bolus injection of 0.07 mg/kg in the case of a venous thromboembolic event, and at a dose of 0.15 mg/kg/hr with the same initial bolus injection in the case of an arterial thromboembolic event. Whenever possible, oral anticoagulation with acenocoumarol was introduced at the same time as recombinant hirudin, which was interrupted as soon as the international normalized ratio reached 3. Clinical events, particularly thromboembolism and bleeding, were noted; activated partial thromboplastin time (aPTT), and platelet count were assessed throughout the administration of recombinant hirudin.
Heparins responsible for heparin‐induced thrombocytopenia were porcine sodium or calcium heparinate in four cases, nadroparin in one case, and enoxaparin in one case. Thrombocytopenia was discovered on routine systematic platelet count in two patients and after the occurrence of arterial and venous thromboembolism in two patients, respectively. After discontinuation of heparin and the onset of recombinant hirudin, clinical evolution was uneventful in all patients, with no recurrence of thromboembolism, limb amputation, or hemorrhagic complication. The aPTT ratio varied from 1.8 to 3.5 (median 2.4) throughout administration of recombinant hirudin. Platelet count rose from nadir (median value 60 × 10 ⁹ 15 to 90) to above 100 × 10 ⁹ /L in every patient within 3–6 days (median 5), after discontinuation of heparin.
Intravenous administration of recombinant hirudin ensured safe anticoagulation in patients with heparin‐induced thrombocytopenia and made it possible to wait for oral anticoagulation to become efficient and platelet count to return to normal values without occurrence or recurrence of thromboembolism.
Heparin-induced thrombocytopenia, defined by the presence of heparin-dependent IgG antibodies, typically occurs five or more days after the start of heparin therapy and can be complicated by thrombotic events. The frequency of heparin-induced thrombocytopenia and of heparin-dependent IgG antibodies, as well as the relative risk of each in patients given low-molecular-weight heparin, is unknown.
We obtained daily platelet counts in 665 patients in a randomized, double-blind clinical trial comparing unfractionated heparin with low-molecular-weight heparin as prophylaxis after hip surgery. Heparin-induced thrombocytopenia was defined as a decrease in the platelet count below 150,000 per cubic millimeter that began five or more days after the start of heparin therapy, and a positive test for heparin-dependent IgG antibodies. We also tested a representative subgroup of 387 patients for heparin-dependent IgG antibodies regardless of their platelet counts.
Heparin-induced thrombocytopenia occurred in 9 of 332 patients who received unfractionated heparin and in none of 333 patients who received low-molecular-weight heparin (2.7 percent vs. 0 percent; P = 0.0018). Eight of the 9 patients with heparin-induced thrombocytopenia also had one or more thrombotic events (venous in 7 and arterial in 1), as compared with 117 of 656 patients without heparin-induced thrombocytopenia (88.9 percent vs. 17.8 percent; odds ratio, 36.9; 95 percent confidence interval, 4.8 to 1638; P < 0.001). In the subgroup of 387 patients, the frequency of heparin-dependent IgG antibodies was higher among patients who received unfractionated heparin (7.8 percent, vs. 2.2 percent among patients who received low-molecular-weight heparin; P = 0.02).
Heparin-induced thrombocytopenia, associated thrombotic events, and heparin-dependent IgG antibodies are more common in patients treated with unfractionated heparin than in those treated with low-molecular-weight heparin.
Heparin-associated thrombocytopenia is a serious medical problem, especially when the patient requires continued anticoagulation. Hirulog is an immediate-acting intravenous anticoagulant that can be substituted for heparin. A new use of Hirulog in the treatment of life-threatening heparin-associated thrombocytopenia with thrombosis (HATT) is presented. Two patients suffering from the HATT syndrome were successfully treated with Hirulog to prevent further thrombosis. A third patient had developed heparin-associated thrombocytopenia after coronary artery bypass surgery in the past and was subsequently treated with Hirulog during a peripheral angioplasty procedure. Hirulog was an effective and predictable anticoagulant for these patients and was free from adverse effects.
Patients with the heparin-induced thrombocytopenia syndrome (HIT) have heparin-associated antibodies (HAb+), which, in the presence of heparin, are responsible for platelet activation and aggregation. This study addressed the questions: (1) are the antibodies specific for heparin; and (2) how do the antibodies cause platelet aggregation?
Plasmas from 79 patients with HIT were divided into seven plasma samples: HAb+ plasma sample 1 (24 pooled plasmas); HAb+ plasma sample 2 (50 pooled plasmas); and HAb+ plasma samples 3 through 7 (individual plasmas). Normal patient plasmas were used as controls (HAb-).
All seven HAb+ plasma samples caused platelet aggregation (PLA) in the presence of heparin and formed a precipitation line with heparin in gel immunodiffusion plates (HAb- plasmas did neither). The HAb+ plasma samples reacted with heparin, as determined by immunoprecipitation in sodium dodecylsulfate-polyacrylamide gel, with the production of a band at 50 kd (no band with HAb- plasmas). The plasma samples 1 and 2 were passed over heparin sepharose beads three times; the unabsorbed plasmas produced 3+ PLA, the first effluent produced 2+ PLA, and the second and third effluents produced no PLA. The heparin sepharose beads stained 3+, 2+, and 1+, after the respective passages, with fluorescein-labeled goat sera containing anti-human immunoglobulin G antibody. HAb+ plasma samples were digested with pepsin to separate the F(ab')2 fragments from the Fc fragments. The F(ab')2 fragments reacted with heparin as determined by immunoprecipitation in sodium dodecylsulfate-polyacrylamide gel with the production of a band at 25 kd, but did not cause PLA in the presence of heparin.
Patients with HIT have heparin-specific antibodies that react with heparin in a classic F(ab')2 reaction and require the Fc fragment for platelet aggregation.
A 62-year-old woman who underwent an aortic valve replacement for severe aortic valve stenosis developed postoperative thrombocytopenia and adult respiratory distress syndrome, simultaneously. Both complications resolved promptly after discontinuing heparin therapy. The presence of a heparin-related antiplatelet antibody was detected by in vitro testing. The time course of clinical events suggests the possibility of a heparin-induced, immune-mediated injury to both the pulmonary vascular endothelium and the platelet membrane as an underlying pathophysiologic mechanism.