Massive retroperitoneal pseudotumour in a patient with type 3 von Willebrand disease.

Formation of destructive haemorrhagic pseudocysts or pseudotumours thought to arise from unresolved, encapsulated haematomas is a well-recognized, rare complication of severe haemophilia A or B, and has been reported in a single patient with von Willebrand disease (vWD). We report a 41-year-old patient with type 3 vWD who underwent incomplete resection of a large retroperitoneal pseudocyst in 1995 and presented with a recurrent, extensive right abdominal and flank mass and signs and symptoms of large bowel obstruction. He required emergency partial colectomy for bowel ischaemia and removal of his right kidney, which was hydronephrotic due to prolonged ureteral obstruction by the pseudocyst. Following repeat partial resection of the pseudotumour, he developed persistent bleeding into the operative site despite aggressive administration of von Willebrand factor (vWF)-rich factor VIII concentrates, resulting in retroperitoneal haematomas and abscesses, which resolved after 13 months of percutaneous drainage, extended supplementation of vWF and antibiotic therapy.

The relationship between hirudin and activated clotting time: implications for patients with heparin-induced thrombocytopenia undergoing cardiac surgery.

UNLABELLED: Anticoagulation with recombinant hirudin (r-hirudin) (Refludan) has been suggested as an alternative to heparin for patients with heparin-induced thrombocytopenia requiring cardiac surgery. We sought to develop a modified activated coagulation time (ACT) that would allow quantification of the levels of r-hirudin required during cardiopulmonary bypass (CPB). Twenty-one patients scheduled for elective cardiac surgical procedures requiring CPB were enrolled in this IRB-approved study. R-hirudin was added to blood specimens obtained before heparin administration (before CPB) and 30 min after heparin neutralization with protamine (after CPB) to result in concentrations of 0, 2, 4, 6, 7, or 8 microg/mL. Kaolin/ACT and complete blood count measurements were assayed in native specimens (first 10 patients, Phase I) or in specimens mixed with equal volumes of commercial normal plasma (second 11 patients, Phase II). In Phase I, good (r(2) = 0.83) linear relationships between ACT values and r-hirudin concentrations (< or =4 microg/mL) were observed in specimens obtained before CPB. However, ACT values were markedly prolonged (P < 0.0001) by r-hirudin in specimens obtained after CPB, with ACT values generally exceeding the ACT's detection limit (>999 s) at hirudin concentrations >2 microg/mL. In patient specimens mixed with normal plasma (Phase II), ACT/hirudin relationships (i.e., hirudin/ACT slope values obtained with hirudin concentration < or =4 microg/mL) in the post-CPB period (0.022 +/- 0.004 microg. mL(-1). s(-1)) were similar (P = 0.47) to those (0.019 +/- 0.004 microg. mL(-1). s(-1)) obtained in the pre-CPB period. Accordingly, a significant relationship between normal plasma-supplemented ACT values and predilution hirudin concentration was obtained in the post-CPB (hirudin = 0.039ACT - 4.34, r(2) = 0.91) period. Although our data demonstrate that the ACT test cannot be used to monitor hirudin during CPB, the addition of 50% normal plasma to post-CPB hemodiluted blood specimens yields a consistent linear relationship between hirudin concentration and ACT values up to a predilution concentration of 8 microg/mL. Plasma-modified ACT may be useful in monitoring hirudin anticoagulation during CPB. IMPLICATIONS: A modified activated clotting time test system that may be helpful in monitoring hirudin anticoagulation in patients with heparin-induced thrombocytopenia during cardiac surgery with cardiopulmonary bypass is described.

New insights into how blood clots: implications for the use of APTT and PT as coagulation screening tests and in monitoring of anticoagulant therapy.

Blood coagulation occurs efficiently on cell surfaces such as activated platelets and monocytes, and fibroblasts. It is initiated by limited amounts of tissue factor (TF) exposed at the sites of vascular injury that complexes with trace amounts of circulating factor VIIa (FVIIa). Additional FVIIa-TF complexes are formed from FVII-TF involving positive feedback loops, including FVIIa-TF as well as factors Xa and IXa as they are formed in subsequent steps. For sustained normal coagulation to proceed, effective in vivo activation of factor X requires the participation of factor IXa generated via the FVIIa-TF complex. This may, in part, be due to effective inhibition of factor Xa and FVIIa-TF complex by tissue factor pathway inhibitor that results in blockage of direct activation of factor X by the FVIIa-TF complex. Additional generation of factor Xa at injury sites may then proceed via the FIXa-VIIIa pathway. Thrombin generated from prothrombin via complex formation of prothrombin with FXa and FVa on phospholipid surfaces (prothrombinase complex) powerfully accelerates coagulation by activation of FVIII and FV, and sustains coagulation through activation of FXI. Thus, in light of our current understanding of how blood clots in vivo, it is clear that both prothrombin time (PT) and activated partial thromboplastin time (APTT) are highly artificial in vitro systems with major limitations. Nevertheless, these tests are quite useful as global screening tests for abnormalities in the intrinsic or extrinsic, as well as common, pathways of coagulation and for monitoring of anticoagulant therapy.

Anticoagulation and anticoagulation reversal with cardiac surgery involving cardiopulmonary bypass: an update.

Accelerated thrombin generation is central to the development of hemostatic abnormalities during cardiopulmonary bypass (CPB) that are associated with both thromboembolic complications and serious, abnormal bleeding. Thrombin not only converts fibrinogen to fibrin, but also activates platelets and coagulation factors V, VIII, and XI and causes release of von Willebrand factor from vascular endothelium. Thrombin can also downregulate the hemostatic system by inducing formation of platelet inhibitory agents, such as nitric oxide and prostacyclin, and release of tissue plasminogen activator, facilitating activation of protein C, and releasing tissue factor pathway inhibitor. Excessive thrombin activity may also result in substantial consumption of platelets, fibrinogen, and labile coagulation factors and abnormal bleeding. Elevated tissue plasminogen activator levels secondary to activation of the contact system and surgery catalyze the formation of plasmin, which also consumes or internalizes platelet glycoprotein receptors and coagulation factors V, VIII, and fibrinogen. Heparin can reduce the generation of and mediate neutralization of excessive and CPB-associated thrombin activity. Heparin anticoagulation is commonly monitored with the activated clotting time (ACT). However, the ACT may be prolonged by factors other than heparin during CPB, such as hemodilution and hypothermia, and therefore may not accurately reflect the extent of anticoagulation by heparin. Aprotinin, a nonspecific serine protease inhibitor used with CPB, can also prolong celite-based ACT values, rendering it less reliable for monitoring heparin anticoagulation. Therefore, several alternative anticoagulation strategies have been recommended when aprotinin is used, such as a higher celite ACT trigger (>750 seconds), monitoring of whole blood heparin concentrations (eg, >2.7 U/mL), or administration of heparin based on a CPB duration-dependent, fixed-dose regimen. Administration of heparin doses higher than those generally recommended, as guided by predetermined, patient-specific whole blood heparin concentration measurements during bypass, can reduce excessive thrombin-mediated consumption of platelets and coagulation factors as well as post-CPB blood loss and blood component transfusions. New modalities of improving suppression of excess thrombin generation during CPB include use of heparin-bonded CPB circuits, heparin cofactor II or related analogs, supplemental antithrombin III, direct thrombin inhibitors (eg, hirudin, argatroban), and inhibitors of the contact and tissue factor pathways. The safety and efficacy of these approaches remains to be established by additional, appropriately powered, prospective studies.

Use of point-of-care test in identification of patients who can benefit from desmopressin during cardiac surgery: a randomised controlled trial.

BACKGROUND: Platelet dysfunction is a major cause of excessive microvascular bleeding after cardiac surgery. A new point-of-care test (hemoSTATUS) can identify patients at risk of excessive bleeding. We aimed to find out whether patients who can benefit from desmopressin during cardiac surgery can be identified by this test. METHODS: We enrolled 203 patients scheduled for elective cardiac surgery in a prospective, double-blind, placebo-controlled trial. Patients with abnormal hemoSTATUS clot-ratio results (<60% of maximum in channel 5) after discontinuation of cardiopulmonary bypass were randomly assigned desmopressin (n=50) or placebo (n=51). Patients with normal clot ratios were included in an untreated control group (n=72). FINDINGS: Intraoperative platelet counts and clot ratios were significantly higher in the untreated control group than in the study-drug groups. In intensive care, clot ratios in patients who received desmopressin were similar to those in the untreated control group, despite significantly lower platelet counts, but were lower in the placebo group than in the other two groups (p=0.0001). Compared with the placebo group, patients who received desmopressin had less blood loss in 24 h (mean 624 [SD 209] vs 1028 mL [682] p=0.0004) and required less transfusion of red blood cells (1.1 [022] vs 2.2 U [0.32] p=0.009), platelets (0.1 [0.04] vs 1.9 U [4.5] p=0.0001), and fresh-frozen plasma (0.1 [0.07] vs 0.75 U [0.21] p=0.0008), and had less total blood-donor exposures (1.56 [0.31] vs 5.2 [0.8] p=0.0001). Placebo patients also had substantially higher blood loss and transfusion requirements than untreated control patients. INTERPRETATION: Patients identified with hemoSTATUS as being at increased risk of excessive bleeding after cardiac surgery can benefit from administration of desmopressin. Further studies are, however, needed to confirm these findings as well as to identify the mechanism of action and safety of desmopressin in the clinical setting.

A randomized, double-blind comparison of two dosage levels of recombinant factor VIIa in the treatment of joint, muscle and mucocutaneous haemorrhages in persons with haemophilia A and B, with and without inhibitors. rFVIIa Study Group.

Recombinant factor VIIa (rFVIIa) was developed to provide an improved procoagulant component capable of 'by-passing' inhibitor antibodies in the treatment of haemophilic patients. The primary objective of this study was to compare the efficacy of two dosage regimens of rFVIIa (given intravenously at periodic intervals) in the treatment of joint, muscle and mucocutaneous haemorrhages in persons with haemophilia A and B with and without inhibitors. The study was designed as a randomized, double-blind, parallel group, international multicenter trial. Patients were randomly allocated to treatment A: 35 mu kg-1 or B: 70 mu kg-1, in blocks of 2. Within each block, one patient was assigned to the 35 mu kg-1 dosing regimen and the other to 70 mu kg-1 dose. One hundred and fifty subjects from 20 sites were screened for this study and 116 had baseline assessments. Of these, 84 were treated on the protocol and 32 were not treated in the study, in most cases because they did not return to the clinic with an eligible bleeding episode. One hundred and seventy-nine bleeding episodes were treated, of which 145 (81%) were acute haemarthroses. Both treatments were efficacious, with 71% having an excellent (59% and 60%) or effective (12% and 11%) response. Overall, the mean and median number of doses given per episode of joint bleeding were 3.1 and 2, respectively. The mean number of doses was 3.1 for the 70 mu kg-1 group and 2.7 for the 35 mu kg-1 group (P value = 0.142). The study concluded that rFVIIa in a dosage of 35 mu kg-1 or 70 mu kg-1 is both safe and reasonably effective in the treatment of joint or muscle haemorrhages in haemophilic patients with inhibitor antibodies to factor VIII or factor IX. It is concluded that the appropriate dose for the treatment of joint and peripheral muscle bleeding in haemophilic patients with inhibitors is 35-70 mu kg-1 given at 2-3 h intervals until haemostasis is achieved.

Platelet adhesion and aggregation in pulsatile shear flow: effects of red blood cells.

An in vitro test system was developed to examine the effects of red blood cells (RBC) on shear-induced platelet adhesion (SIPAD) and platelet aggregation (SIPAG). Suspensions of human platelets labeled with Mepacrine and suspended in citrated plasma were exposed to single, continuous or repetitive (120-300x) one second shear stress pulses of varying amplitude (15-100 dyn/cm2) in a cone-plate viscometer in the presence or absence of fresh, untreated (intact) RBC or glutaraldehyde (GLA)-fixed, rigid, adenosine diphosphate (ADP)-depleted (GLA)-RBC. SIPAG was expressed as percent loss of single platelets. SIPAD was assessed by measuring the amount of Mepacrine-related fluorescent material remaining on glass disks in the plate of the viscometer after washing with EDTA-saline to remove platelet aggregates. Intact RBC were twice as effective as GLA-RBC in potentiating SIPAG at all shear stress levels. Potentiation of SIPAD by intact RBC was markedly less than that observed with GLA-RBC at stresses below 50 dyn/cm2. These findings are consistent with the concept that while both physical and chemical (ADP) mechanisms are substantially involved in potentiation by RBC of SIPAG, RBC support SIPAD largely by enhancement of platelet transport from the bulk flow to the bounding surfaces. The findings also indicate that it is feasible to assess SIPAD and SIPAG in the same flow system simultaneously. A less complicated version of the method described here should prove useful in the evaluation of patients with platelet functional disorders, and in the evaluation and monitoring of antiplatelet agents.

A comparison between continuous infusion versus standard bolus administration of heparin based on monitoring in cardiac surgery.

This study was designed to determine prospectively if stable heparin concentrations can be maintained during extracorporeal circulation by using a continuous infusion technique, compared with a bolus regimen based on whole blood heparin concentration monitoring. Forty patients were assigned randomly to either an infusion or a monitoring group. The reference heparin concentration was defined as the whole blood heparin concentration associated with a kaolin activated clotting time (ACT) of approximately 480 s prior to institution of cardiopulmonary bypass (CPB) for both cohorts. For infusion patients, doses of heparin were administered using a continuous infusion based on the initial patient-specific heparin dose per unit weight; heparin was also added to solutions administered after the initiation of CPB based on the reference heparin concentration. For monitoring patients, the dose of heparin administered during CPB was calculated by the Hepcon instrument. Blood specimens collected prior to and during the CPB period were used to measure anti-Xa plasma heparin concentration and complete blood counts, kaolin ACT and whole blood heparin concentration. Doses of heparin and protamine administered and transfusion requirements were similar in patient cohorts. The apparent rate of clearance of heparin from plasma was variable among patients in the monitoring group prior to CPB. Stable heparin concentrations were maintained using whole blood heparin measurements, whereas mean heparin concentrations were slightly lower using the continuous infusion technique. Therefore, an optimal approach might involve the combined use of these regimens.

Monitoring of hemostasis in cardiac surgical patients: impact of point-of-care testing on blood loss and transfusion outcomes.

Patients undergoing cardiac surgery with cardiopulmonary bypass (CPB) are at increased risk for excessive perioperative blood loss requiring transfusion of blood products. Strategies to optimize administration of heparin and protamine and the assessment of their effects on coagulation are evolving in cardiac surgical patients. Two recent evaluations have focused on the use of multiple point-of-care (POC) coagulation assays for patient-specific adjustment of heparin and protamine dosage. These studies indicate that blood loss and transfusion requirements in cardiac surgical patients may be reduced with more accurate control of heparin anticoagulation and its reversal. Blood component administration in patients with excessive post-CPB bleeding is generally empiric in part, related to turnaround times of laboratory-based tests. Methods are now available for rapid, POC assessment of coagulation to allow appropriate, targeted therapy for acquired hemostatic abnormalities. Recent studies indicate that a rapid evaluation of thrombocytopenia and coagulation factor deficiencies with POC tests can facilitate the optimal administration of pharmacologic and transfusion-based therapy in patients who exhibit excessive bleeding after CPB. POC tests that assess platelet function have been developed, and their use may facilitate identification of which patients at risk for excessive blood loss may respond to pharmacologic interventions such as desmopressin acetate or antifibrinolytic agents.

Antithrombin III during cardiac surgery: effect on response of activated clotting time to heparin and relationship to markers of hemostatic activation.

UNLABELLED: This study was designed to determine if, and to what extent, antithrombin III (AT) levels affect the response of the activated clotting time (ACT) to heparin in concentrations used during cardiac surgery, and to characterize the relationship between AT levels and markers of activation of coagulation during cardiopulmonary bypass (CPB). After informed consent, blood specimens obtained from eight normal volunteers (Phase I) were used to measure the response of the kaolin and celite ACT to heparin after in vitro addition of AT (200 U/dL) and after dilution with AT-deficient plasma to yield AT concentrations of 20, 40, 60, 80, and 100 U/dL. In Phase II, blood specimens collected before the administration of heparin and prior to discontinuation of CPB, were used to measure the response of the kaolin ACT to heparin (preheparin only), AT concentration, and a battery of coagulation assays in 31 patients undergoing repeat or combined cardiac surgical procedures. In Phase I, strong linear relationships were observed between kaolin (slope = 1.04 AT - 2, r2 = 0.78) and celite (slope = 1.36 AT + 6, r2 = 0.77) ACT slopes and AT concentrations below 100 U/dL. In the pre-CPB period of Phase II, only factors V (partial r = -0.49) and VIII (partial r = -0.63) were independently associated with heparin-derived slope using multivariate analysis; an inverse relationship was observed between AT and fibrinopeptide A levels (r = -0.41) at the end of CPB. Our findings indicate that the responsiveness of whole blood (ACT) to heparin at the high concentrations used with CPB is progressively reduced when the AT concentration decreases below 80 U/dL. Because AT is variably, and sometimes extensively, reduced in many patients before and during CPB, AT supplementation in these patients might be useful in reducing excessive thrombin-mediated consumption of labile hemostatic blood components, excessive microvascular bleeding, and transfusion of blood products. IMPLICATIONS: Heparin, a drug with anticoagulant properties, is routinely given to patients undergoing cardiac surgery to prevent clot formation within the cardiopulmonary bypass circuit. However, when levels are reduced, heparin is not as effective. Findings within this study indicate that administration of antithrombin III may help to preserve the hemostatic system during cardiopulmonary bypass.

Effects of platelets and white blood cells and antiplatelet agent C7E3 (Reopro) on a new test of PAF procoagulant activity of whole blood.

This study was designed to evaluate the effects of varying concentrations of platelets, white blood cells (WBC) and Fab fragments of a monoclonal antibody (c7E3, Reopro) directed at the platelet GpIIb-IIIa receptor complex on ACT-based clot ratio values (hemoSTATUS assay) in healthy volunteers. These measurements were made in heparinized whole blood from 10 normal volunteers in which either platelet or WBC concentrations had been varied by differential centrifugation. In addition, blood collected in either heparin or argatroban was incubated with varying concentrations of c7E3 (Reopro). Clot ratio values (%Maximal) in normal blood did not decrease until average platelet counts were less than 50,000. A marked reduction in clot ratios was observed when WBC concentration increased above or decreased below baseline clot ratios within each patient. Strong linear relationships were observed between white cell concentration and clot ratio values when white cell concentrations were either less or greater than baseline values. When argatroban was used as an anticoagulant, inverse relationships were demonstrated between clot ratio values and increasing c7E3 concentration (Ch 3: r = -0.33, Ch4: r = -0.84, Ch5: r = -0.87, Ch 6: r = -0.71). ACT-based clot ratio values determined in heparinized whole blood presumably reflecting PAF inducible platelet procoagulant activity, are affected by platelet concentration when counts are less than 50,000/microliter. The hemoSTATUS test was also found to be affected by WBC concentration since clot ratio values decreased when WBC counts were below 4,000/microliter or above 9,000/microliter. A dose-dependent reduction in clot ratio values was also observed with increasing concentrations of c7E3. This test can reliably detect platelet dysfunction only if the platelet count is > 50,000 and the WBC is normal.

Hemofiltration during cardiopulmonary bypass: the effect on anti-Xa and anti-IIa heparin activity.

Previous studies have demonstrated that heparin concentrations during cardiopulmonary bypass (CPB) may vary considerably, which may be related to variability in redistribution, cellular and plasma protein binding, and clearance of heparin. The purpose of this study was to determine whether hemofiltration removes lower molecular weight fractions of heparin from plasma and thus contributes to variability of blood levels of heparin. Twenty patients undergoing cardiac surgery with CPB were enrolled in this study after informed consent was obtained. The study was subdivided into two phases. The first 10 patients were enrolled in Phase I, which was designed to determine whether hemofiltration removes lower molecular weight fractions of heparin from blood. Blood specimens obtained from the inflow line and outflow lines of the hemofiltration unit were used to measure complete blood counts (CBC) and plasma heparin activity by anti-Xa and anti-IIa assays. Phase II was designed to evaluate the effect of hemofiltration on circulating plasma heparin activity. In Phase II, blood specimens were obtained from 10 patients via the arterial cannula of the extracorporeal circuit prior to and after hemofiltration for measurements of CBCs, anti-Xa plasma heparin, as well as whole blood heparin concentration using an automated protamine titration assay (Hepcon instrument, Medtronic Inc., Parker, CO). Ultrafiltrate and reservoir volumes were measured in both phases of the study. Hemofiltration did not remove lower (anti-Xa measurable) molecular weight heparin, but it resulted in a considerable increase in heparin activity in the outflow line, as measured by both anti-Xa and anti-IIa assays. The plasma anti-Xa heparin activity obtained after hemofiltration (5 +/- 1.8 U/mL) was substantially (P = 0.003) greater than heparin activity obtained prior to hemofiltration (3.9 +/- 1.7 U/mL). The increase in heparin activity with hemofiltration was directly related to ultrafiltrate volume (r = 0.63, P < 0.0001) and hematocrit (r = 0.73, P < 0.0001). Hemofiltration increases heparin concentration and may contribute to variability in heparin activity during CPB. Point-of-care heparin concentration methods would allow identification of the anticipated rise in heparin concentration, with the apparent clinical implication of a reduced need for supplemental heparin to maintain a target whole blood heparin concentration.

More effective suppression of hemostatic system activation in patients undergoing cardiac surgery by heparin dosing based on heparin blood concentrations rather than ACT.

This study was designed to determine whether the maintenance of higher than usual patient-specific heparin concentrations during cardiopulmonary bypass (CPB) was associated with more effective suppression of hemostasis system activation. Thirty-one patients scheduled for repeat cardiac surgery or combined procedures (i.e., coronary revascularization + valve repair/replacement) were consented and enrolled in this study. All patients received porcine heparin and protamine and were randomly assigned to monitoring of anticoagulation by either celite ACT alone (Control, n = 16) or by kaolin ACT combined with on-site measurements of whole blood heparin concentration (Intervention, n = 15). Blood specimens collected before administration of heparin, before weaning from CPB and after administration of protamine were analyzed with a battery of coagulation assays. Patients in the intervention cohort received appreciably greater heparin doses than control patients, resulting in higher anti-Xa heparin levels at the end of CPB. Fibrinopeptide A and D-dimer levels were higher in the control group before discontinuation of CPB. Percent decrease during CPB were greater in the control group for factors V and VIII, fibrinogen and antithrombin III. Percent decrease in complement 3 was greater in the control group after protamine and bleeding times measured in the Intensive Care Unit were significantly more prolonged in this group. Maintenance of higher patient-specific heparin concentrations during CPB more effectively suppresses excessive hemostatic system activation than do standard heparin doses chosen based on measurement of ACT. These findings may explain, at least in part, the significant reduction in perioperative blood loss and blood product use when higher heparin concentrations are maintained.

Evaluation of a new point-of-care test that measures PAF-mediated acceleration of coagulation in cardiac surgical patients.

BACKGROUND: This study was designed to evaluate a new point-of-care test (HemoSTATUS) that assesses acceleration of kaolin-activated clotting time (ACT) by platelet activating factor (PAF) in patients undergoing cardiac surgery. Our specific objectives were to determine whether HemoSTATUS-derived measurements correlate with postoperative blood loss and identify patients at risk for excessive blood loss and to characterize the effect of desmopressin acetate (DDAVP) and/or platelet transfusion on these measurements. METHODS: Demographic, operative, blood loss and hematologic data were recorded in 150 patients. Two Hepcon instruments were used to analyze ACT values in the absence (channels 1 and 2: Ch1 and Ch2) and in the presence of increasing doses of PAF (1.25, 6.25, 12.5, and 150 nM) in channels 3-6 (Ch3-Ch6). Clot ratio (CR) values were calculated with the following formula for each respective PAF concentration: clot ratio = 1-(ACT/control ACT). These values also were expressed as percent of maximal (%M = clot ratio/0.51 x 100) using the mean CRCh6 (0.51) obtained in a reference population. RESULTS: When compared with baseline clot ratios before anesthetic induction, a marked reduction in clot ratios was observed in both Ch5 and Ch6 after protamine administration, despite average platelet counts greater than 100 K/microliter. There was a high degree of correlation between clot ratio values and postoperative blood loss (cumulative chest tube drainage in the first 4 postoperative hours) with higher concentrations of PAF: CRCh6 (r = -0.80), %M of CRCh6 (r = -0.82), CRCh5 (r = -0.70), and %M of CRCh5 (r = -0.85). A significant (P < 0.01) improvement in clot ratios was observed with time after arrival in the intensive care unit in both Ch5 and Ch6, particularly in patients receiving DDAVP and/or platelets. CONCLUSIONS: Activated clotting time-based clot ratio values correlate significantly with postoperative blood loss and detect recovery of PAF-accelerated coagulation after administration of DDAVP or platelet therapy. The HemoSTATUS assay may be useful in the identification of patients at risk for excessive blood loss and who could benefit from administration of DDAVP and/or platelet transfusion.

Effect of heparin on whole blood activated partial thromboplastin time using a portable, whole blood coagulation monitor.

OBJECTIVES: To evaluate the responsiveness of whole blood activated partial thromboplastin time (aPTT) to varying heparin doses in vitro and to examine the ex vivo relationship of whole blood aPTT to plasma heparin concentration. DESIGN: Prospective, controlled laboratory study. SETTING: Surgical suites and laboratory at a tertiary center. PATIENTS: Surgical patients and volunteers at a tertiary center were eligible for inclusion in this study. In vitro evaluation was performed using specimens obtained from each of five, healthy volunteers. Ex vivo evaluation was performed using specimens obtained from 30 cardiac surgical patients before and after systemic administration of heparin for extracorporeal circulation. INTERVENTIONS: Blood specimens were obtained from volunteers and added to syringes containing varying amounts of unfractionated porcine heparin for in vitro evaluation. For ex vivo evaluation, blood specimens were obtained from patients before and after systemic administration of 20 U/kg of heparin. MEASUREMENTS AND MAIN RESULTS: For the in vitro evaluation, specimens were divided into two aliquots after mixing with varying amounts of unfractionated porcine heparin. One aliquot was used to measure whole blood aPTT using a whole blood coagulation monitor immediately after blood collection and 3 mins later, and a second aliquot was used to determine plasma aPTT with a conventional, laboratory-based assay. Linear regression analysis demonstrated a high correlation (r = .94; r2 = .88) between aPTT assay systems and bias analysis demonstrated a mean aPTT measurement difference of 1.6 secs with +/- 2 SD limits of -15 to +18.2 secs. As indicated by comparable regression slopes, the in vitro aPTT responsiveness to increasing heparin concentration was similar with the two assay systems among individual subjects. Whole blood aPTT measurements after 3 mins of blood specimen storage were similar to immediate measurements. For ex vivo evaluation, blood specimens obtained from patients before and after systemic administration of heparin were divided into two aliquots. One aliquot was used to measure whole blood aPTT in duplicate and a second aliquot was used to measure plasma heparin concentration with an antifactor X active chromogenic assay. A high correlation (r = .89; r2 = .79) between whole blood aPTT and plasma heparin concentration was observed. CONCLUSIONS: Heparin responsiveness of whole blood aPTT, measured with a portable whole blood coagulation monitor, is similar to that of conventional laboratory aPTT over a clinically relevant range of heparin concentrations in vitro and ex vivo. On-site whole blood aPTT measurements should be useful in clinical situations requiring rapid aPTT results.

The impact of heparin concentration and activated clotting time monitoring on blood conservation. A prospective, randomized evaluation in patients undergoing cardiac operation.

A whole blood hemostasis system (Hepcon) provides both activated clotting time and accurate whole blood heparin concentration measurements via an automated protamine titration method. This study was designed to prospectively evaluate the impact of heparin and protamine administration using this system on the incidence and treatment of bleeding after cardiopulmonary bypass. Two hundred fifty-four patients requiring cardiopulmonary bypass were enrolled in this prospective study over a 7-month period. Patients treated with antifibrinolytic agents (aprotinin, epsilon-aminocaproic or tranexamic acid) were excluded. Patients were randomly assigned to either a control (n = 127) or intervention (n = 127) group. For control patients, the anticoagulation protocol consisted of an initial fixed dose of 250 U/kg of heparin, and additional 5000 U heparin doses were administered if the activated clotting time was less than 480 seconds. Heparin was neutralized with an initial fixed dose of protamine (0.8 mg protamine per milligram total heparin). For the intervention group, an initial dose of heparin was based on an automated heparin dose-response assay. Additional heparin doses were administered if the heparin concentration was less than the reference concentration or for an activated clotting time less than 480 seconds. The protamine dose was based on the residual heparin concentration. Treatment of excessive bleeding after cardiopulmonary bypass was based on an algorithm using point-of-care testing with whole blood prothrombin time, activated partial thromboplastin time, heparinase activated clotting time, and platelet count. No differences between the two treatment groups were identified in reference to demographic factors, preoperative anticoagulant medications, preoperative coagulation data, number of reoperations, or combined procedures and duration of cardiopulmonary bypass. Indirect evidence for coagulation factor consumption was demonstrated in control patients by more prolonged whole blood prothrombin time and activated partial thromboplastin time values after cardiopulmonary bypass when compared with values obtained in the intervention group. Patients in the intervention cohort received greater doses of heparin (intervention: 612 +/- 147, control: 462 +/- 114 U/kg, p < 0.0001) and had lower protamine to heparin ratios (intervention: 0.70 +/- 0.64, control: 0.94 +/- 0.21, p = 0.0001) compared with control patients. Patients in the intervention cohort received significantly fewer platelet (intervention: 1.7 +/- 3.6 U, control: 3.7 +/- 6.7 U, p = 0.003), plasma (intervention: 0.4 +/- 1.3 U, control: 1.4 +/- 2.5 U, p = 0.0001), and cryoprecipitate units (intervention: 0.0 +/- 0.0 U, control: 0.2 +/- 1.2 U, p = 0.04) during the perioperative interval than control patients.(ABSTRACT TRUNCATED AT 400 WORDS)