Michael R. Buchanan

Aspirin "resistance" and risk of cardiovascular morbidity: systematic review and meta-analysis

Objective To determine if there is a relation between aspirin “resistance” and clinical outcomes in patients with cardiovascular disease. Design Systematic review and meta-analysis. Data source Electronic literature search without language restrictions of four databases and hand search of bibliographies for other relevant articles. Review methods Inclusion criteria included a test for platelet responsiveness and clinical outcomes. Aspirin resistance was assessed, using a variety of platelet function assays. Results 20 studies totalling 2930 patients with cardiovascular disease were identified. Most studies used aspirin regimens, ranging from 75-325 mg daily, and six studies included adjunct antiplatelet therapy. Compliance was confirmed directly in 14 studies and by telephone or interviews in three. Information was insufficient to assess compliance in three studies. Overall, 810 patients (28%) were classified as aspirin resistant. A cardiovascular related event occurred in 41% of patients (odds ratio 3.85, 95% confidence interval 3.08 to 4.80), death in 5.7% (5.99, 2.28 to 15.72), and an acute coronary syndrome in 39.4% (4.06, 2.96 to 5.56). Aspirin resistant patients did not benefit from other antiplatelet treatment. Conclusion Patients who are resistant to aspirin are at a greater risk of clinically important cardiovascular morbidity long term than patients who are sensitive to aspirin.

Endothelial Function Testing as a Biomarker of Vascular Disease

The endothelium is the monolayer of endothelial cells lining the lumen of all blood vessels. These cells function as a protective biocompatible barrier between all tissues and the circulating blood. Endothelial cells also function as a selective sieve to facilitate bidirectional passage of macromolecules and blood gases to and from tissues and blood. The strategic location of the endothelium allows it to “sense” changes in hemodynamic forces and blood-borne signals and “respond” by releasing a number of autocrine and paracrine substances. A balanced release of these bioactive factors facilitates vascular homeostasis. Endothelial cell dysfunction disrupts this balance, thereby predisposing the vessel wall to vasoconstriction, leukocyte adherence, platelet activation, mitogenesis, pro-oxidation, thrombosis, impaired coagulation, vascular inflammation, and atherosclerosis.1 Our understanding of these endothelial cell responses has led to the development of tests that are believed to reflect endothelial cell dysfunction or integrity in vivo. Given the central role of the endothelium in the development and clinical course of atherosclerosis, endothelial function testing may serve as a useful biomarker of atherosclerosis. Nitric oxide (NO) is the key endothelium-derived relaxing factor that plays a pivotal role in the maintenance of vascular tone and reactivity.2 In addition to being the main determinant of basal vascular smooth muscle tone, NO acts to negate the actions of potent endothelium-derived contracting factors such as angiotensin II and endothelin-1. In addition, NO serves to inhibit platelet and white cell activation and to maintain the vascular smooth muscle in a nonproliferative state. NO is synthesized from l-arginine under the influence of the enzyme NO synthase (NOS). NOS requires a critical cofactor, tetrahydrobiopterin, to facilitate NO production. Tetrahydrobiopterin deficiency leads to an “uncoupling” of NOS that results in the formation of untoward oxidants such as superoxide and hydrogen peroxide (versus NO) with resultant impairment in endothelial function. …

Coagulation disorders of cardiopulmonary bypass: a review

BackgroundPostoperative bleeding is one of the most common complications of cardiac surgery.DiscussionExtensive surgical trauma, prolonged blood contact with the artificial surface of the cardiopulmonary bypass (CPB) circuit, high doses of heparin, and hypothermia are all possible triggers of a coagulopathy leading to excessive bleeding. Platelet activation and dysfunction also occur and are caused mainly by heparin, hypothermia, and inadequate protamine administration. Heparin and protamine administration based on heparin concentrations as opposed to fixed doses may reduce coagulopathy and postoperative blood loss.ConclusionsA better comprehension of the multifactorial mechanisms of activation of coagulation, inflammation, and fibrinolytic pathways during CPB may enable a more effective use of the technical and pharmaceutical options which are currently available.

A comparison of the anti thrombotic and haemorrhagic effects of low molecular weight heparin fractions: The influence of the method of preparation

Bleeding is an important complication of heparin therapy. A number of low molecular weight heparin fractions produce less bleeding than standard heparin for an equivalent antithrombotic effect in experimental animals. Low molecular weight heparin fractions and fragments are produced by a number of different procedures but their relative effects on haemostasis and thrombosis have not been evaluated. We have compared the antithrombotic and haemorrhagic effects of two low molecular weight heparin fragments and of a heparinoid with porcine mucosa heparin and related these in vivo findings to the results of ex vivo tests of blood coagulation and in vitro tests of platelet vivo tests of blood coagulation and in vitro tests of platelet function. Haemorrhage was assessed using a rabbit ear bleeding model. The antithrombotic effects were assessed by measuring inhibition of a tissue thromboplastin-induced jugular vein thrombus and by inhibition of fibrin and platelet accumulation in an arterial-venous shunt. The ex vivo anticoagulant effects were assessed with the thrombin clotting time, activated partial thromboplastin time and anti-Xa assay, and the effect of these glycosaminoglycans on platelet function was assessed by measuring collagen-induced platelet aggregation. For a similar antithrombotic effect, standard heparin produced significantly more bleeding than the other 3 glycosaminoglycans. The antithrombotic effects of all 4 glycosaminoglycans occurred at similar levels of anti-Xa activity but there was no relationship between blood loss and the effects of these glycosaminoglycans on any of the other tests of blood coagulation. Standard heparin had a greater inhibitory effect on collagen-induced platelet aggregation than the low molecular weight glycosaminoglycans, supporting the possibility that the increased bleeding observed with heparin is related in part to its inhibitory effect on platelet function.

A comparison of the thrombolytic and hemorrhagic effects of tissue-type plasminogen activator and streptokinase in rabbits.

Tissue-type plasminogen activator (t-PA) is a promising thrombolytic agent because it can produce thrombolysis without inducing a plasma proteolytic state. It is uncertain if this potentially important feature renders t-PA less hemorrhagic than other plasminogen activators. We have compared the hemorrhagic and thrombolytic effects of t-PA and streptokinase in rabbits. Streptokinase, 4000 U/kg/hr over 4 hr, failed to produce significant thrombolysis and 8000 U/kg/hr streptokinase over 4 hr produced only 28 +/- 6% thrombolysis. Both streptokinase regimens were associated with a plasmin-mediated plasma proteolytic state and both streptokinase regimens produced a significant increase in hemorrhage that was evident within 15 min of beginning the infusion and was progressive over the 4 hr of drug administration. In contrast, t-PA in a dose of 7500 U/kg/hr produced 35 +/- 6% thrombolysis, but it did not produce a plasmin-mediated plasma proteolytic state or a significant increase in hemorrhage over the 4 hr of infusion. t-PA in a dose of 15,000 U/kg/hr produced 85 +/- 4% thrombolysis but was associated with a plasmin-mediated proteolytic state and produced significant bleeding which, in contrast to streptokinase-induced bleeding, was delayed in onset. Therefore, t-PA induced less hemorrhage than streptokinase at doses that produced more effective thrombolysis. Bleeding with both thrombolytic agents was associated with a plasmin-mediated proteolytic state.

Aspirin inhibits platelet function independent of the acetylation of ciclo-oxygenase

Aspirin inhibits platelet function and prevents thrombosis in some clinical situations. This antithrombotic effect is attributed to the irreversible inhibition of platelet thromboxane A2 synthesis, an effect which is achieved by a low dose of aspirin. There is some evidence that higher doses of aspirin may have additional antithrombotic effects. To test this possibility, we measured the effect of high and low dose aspirin on hemostasis in vivo and platelet function ex vivo in the rabbit. Both carotid arteries were isolated. One was replaced with a 2 cm piece of polyethylene tubing and the other was left intact. The prosthetic and intact vessels were then punctured with a needle and the time take for bleeding from each to cease was measured. Aspirin (3 and 100 mg/kg given 1 or 20 hours before hand) had no effect on the bleeding from the intact vessel, but prolonged the bleeding time in the prosthetic vessel in a dose-related manner. Washed platelets obtained from the 100 mg/kg-treated rabbits were less responsive to collagen and thrombin than platelets obtained from the 3 mg/kg-treated rabbits which in turn, were less responsive than control platelets. This additional effect of aspirin on platelet function was not due to the further inhibition of platelet thromboxane A2 release nor to further inhibition of the platelet release phenomenon. It is suggested that the enhanced effect of high dose aspirin on haemostasis from the arterial prosthesis is related to the second platelet inhibiting effect of aspirin.

Gender-related differences in morbidity and mortality during combined valve and coronary surgery

BACKGROUND Gender-related differences in morbidity and mortality are well described for coronary artery bypass grafting but are not well understood for combined valve and bypass surgery. METHODS We reviewed retrospectively the morbidity and mortality of 1570 consecutive patients who underwent combined valve and bypass procedures at the Toronto General Hospital between January 1990 and October 2000. RESULTS There were 1073 men (68%) and 497 women (32%). The mean ages (+/- 1 SD) of women and men were 69 +/- 9 and 68 +/- 9 years, respectively (P =.02). Of the 1570 total patients, 973 patients (62%) underwent aortic valve and coronary bypass surgery, 481 patients (31%) had mitral valve and coronary bypass operations, and 116 (7%) patients had double or triple valve and coronary bypass operations. Preoperative hypertension (P =.002), diabetes (P =.001), and atrial fibrillation (P =.001) were seen more frequently in women. Body surface area was significantly lower in women (P =.0001). At presentation, more women were in congestive heart failure (69% vs 58%, P =.001) and in New York Heart Association functional class III or IV (25% vs 19%, P =.001). Although there was no difference in the number of women with three or more diseased vessels (32% vs 38%), only 35% of women received three or more grafts compared with 44% of men (P =.001). The use of left internal thoracic grafts, although uncommon in the whole study population (36%), was less common in women than in men (26% vs 41%, P =.001). Multivariable logistic analyses for morbidity and mortality showed female gender to be an independent risk factor. Mitral valve replacement, age, left ventricular dysfunction, New York Heart Association classes III and IV, and association of tricuspid valve disease, diabetes, peripheral vascular disease, and preoperative renal failure were found to be independent risk factors for mortality. CONCLUSION Female gender is an independent risk factor for combined morbidity and mortality during and after combined valve and coronary bypass surgery. As with isolated coronary artery bypass grafting, women undergoing combined procedures have more premorbid conditions, are more often in heart failure, had an equal incidence of triple vessel disease but received fewer grafts than men, and, therefore, were more frequently incompletely revascularized.

Respective role of antithrombin III and heparin cofactor II in the in vitro anticoagulant effect of heparin and of various sulphated polysaccharides

Summary. The in vitro anticoagulant effects of standard heparin (SH) and of seven other sulphated polysaccharides (SPS) were investigated by measuring activated partial thromboplastin time (APTT) prolongation of normal plasma and of plasmas selectively depleted of antithrombin III (AT III), of heparin cofactor II (HCII) and of both heparin cofactors. This allowed the determination of the relative contribution of each of the two heparin cofactors to the SPS anticoagulant effect. The SPS varied in their relative activities as catalysts of thrombin inhibition by purified AT III or HC II. The anticoagulant activities of heparin and dermatan sulphate were primarily attributable to their ability to enhance thrombin inhibition by AT III and HC II respectively. Heparin had an additional minor anticoagulant activity which was independent of both AT III and HC II. Pentosan polysulphate, high molecular weight dextran sulphate, heparin with low affinity for AT III and a sulphated heparin derivative had weaker anticoagulant activities in normal plasma than standard heparin. The anticoagulant activities of these last four SPS in plasma depleted of both AT III and HC II were similar to their respective activities in normal plasma. This suggests that these SPS act by directly preventing thrombin generation rather than by enhancing thrombin inhibition.

Chemotherapy enhances endothelial cell reactivity to platelets

Recent studies indicate that chemotherapy is a cause for thrombosis in breast cancer patients. We performed experiments to determine whether the enhanced thrombosis was due, in part, to an effect of chemotherapy on endothelial cell reactivity. Heparinized blood samples were obtained from stage II breast cancer patients receiving monthly adjuvant chemotherapy consisting of cyclophosphamide, epirubicin and 5-fluorouracil. Cultured human endothelial cells were incubated with the plasmas for 2 h, and then the reactivity of the endothelial cells to normal donor platelets was determined isotopically. Endothelial cell reactivity was increased when the endothelial cells were incubated with the post-chemotherapy plasmas. The plasma effect persisted after the chemotherapy drugs were cleared from the circulation, but this plasma effect was abolished when the plasmas were heat-inactivated. Furthermore, the increase in endothelial cell reactivity correlated with the level of interleukin-1 present in the post-chemotherapy plasmas. Finally, the increased endothelial cell reactivity was inhibited by the GRGDS peptide, or by an antibody to the endothelial cell vitronectin receptor. These observations suggest that chemotherapeutic drugs alter endothelial cell reactivity to platelets by inducing the release of interleukin-1 which, in turn, facilitates adhesion molecule expression on the endothelial cell surface. If so, these observations provide a possible explanation for one mechanism which may contribute to the thrombogenic effect seen in breast cancer patients undergoing chemotherapy.

The thrombolytic and hemorrhagic effects of tissue type plasminogen activator: Influence of dosage regimens in rabrits

Tissue type plasminogen activator (t-PA) is an effective thrombolytic agent in experimental animals and in humans. We have previously observed that the thrombolytic effect of t-PA persists beyond its time of clearance from the circulation and that wound bleeding induced by a high dose infusion of t-PA is delayed for at least one and a half hours after commencing the infusion. These observations suggest that improved thrombolysis may be obtained with t-PA by infusing a high dose over a short period of time. To test this hypothesis we compared the thrombolytic and hemorrhagic effects of t-PA infused over 240, 60, 30 and 15 minutes in the rabbit. A 4 hour infusion of 30,000 U/kg of t-PA produced 36% thrombolysis. The same dose of t-PA infused over 60, 30 and 15 minutes produced 87%, 88% and 96% thrombolysis, respectively (p less than 0.01). The 1 hour infusion of 30,000 U/kg of t-PA produced a significant increase in blood loss relative to saline infusion (p less than 0.01). The same dose infused over 30 and 15 minutes did not produce significantly more bleeding than saline. A higher dose of t-PA, 60,000 U/kg, infused over 4 hours, produced 95% thrombolysis, but was associated with a significant increase of blood loss (p less than 0.001). Our findings suggest that improved thrombolysis with t-PA with minimal bleeding side-effects is achieved in rabbits when t-PA is administered in a relatively high dose given over a short period of time.