Lösche W

The value of rotation thromboelastometry to monitor disturbed perioperative haemostasis and bleeding risk in patients with cardiopulmonary bypass.

Rotation thromboelastometry (ROTEM) performed on whole-blood samples provides information on the contribution of fibrinogen and platelets to clot formation. Such measurements are believed superior to classical plasma coagulation measurements as a means of monitoring disturbed haemostasis. On-pump cardiac surgery is associated with high bleeding risk. The study objective was to obtain information on the frequency of abnormal values of ROTEM variables and to assess their value in estimating bleeding risk in such patients. We studied 150 patients undergoing elective on-pump cardiac surgery. We found a significant surgery-induced decrease in haemostatic potential, with more abnormal ROTEM values in intrinsically activated coagulation (up to 50%) than in extrinsically activated coagulation (up to 27%) or the maximum clot firmness in FIBTEM (10%), a test measuring the contribution of fibrinogen. All ROTEM variables tend to normalize within 14–18 h postoperatively. Best positive predictive values and specificity for a postoperative blood loss above 600 ml were found for the clot formation time in extrinsically activated coagulation (71%/94%) and the maximum clot firmness in FIBTEM (73%/95%); these values were superior to the activated partial thromboplastin time or prothrombin time (56%/72% and 43%/5%, respectively). There was no relation between preoperative or early postoperative ROTEM values and intraoperative bleeding. ROTEM recorded a benefit of administration of platelet concentrates or fresh-frozen plasma, particularly when given postoperatively, on haemostasis. In contrast, intraoperative administration of red blood cells impaired haemostasis. ROTEM can provide a more detailed diagnostic basis enabling a focused therapy to cardiac surgery patients with high bleeding risk.

GPIIb-IIIa antagonists cause rapid disaggregation of platelets pre-treated with cytochalasin D. Evidence that the stability of platelet aggregates depends on normal cytoskeletal assembly.

Platelet activation is accompanied by changes in the composition of the platelet cytoskeleton with rapid incorporation and displacement of certain proteins. Here we have inhibited cytoskeletal assembly by pretreating platelets with cytochalasin D (CyD) and investigated the effect on the stability of the aggregates that form. The experiments were performed in both citrated and hirudinized platelet-rich plasma (PRP) and aggregation was induced by adenosine diphosphate (ADP), collagen, the TXA2-mimetic U46619 and adrenaline. Platelets in the aggregates that formed, underwent rapid disaggregation on addition of EDTA or a GpIIb-IIIa antagonist such as MK-852 and GR144053F, all of which are agents that interfere with the ability of fibrinogen to interact with GpIIb-IIIa. This was the case irrespective of the aggregating agent used and occurred in both citrated and hirudinized PRP. In contrast, the rate of disaggregation brought about by some other agents, iloprost and ARL 66096, appeared to be unaffected by CyD. Information was also obtained on the effects of CyD on the cytoskeletal changes brought about by ADP and the effects on the cytoskeleton of subsequent addition of M K-852. The results show that CyD retards the incorporation of certain proteins (actin, myosin, alpha -actinin, actin binding protein and a 66 K protein) into the cytoskeleton and that subsequent addition of MK-852 results in rapid displacement of some of these with re-incorporation of a 31 K protein. The results suggest that the early changes in the cytoskeleton following platelet activation contribute to the stability of the aggregates that form, and that interference with these early changes results in aggregates that are easily disassembled by agents that interfere with GpIIb-IIIa-fibrinogen complex formation.

The role of the GSH-disulfide status in the reversible and irreversible aggregation of human platelets.

Disturbance of cellular SH/SS status of blood platelets by diminution of the level of reduced glutathione is very sensitively reflected in changes of the in vitro aggregation. Additionally, disulfide-linked protein polymers are formed. One of these polymers participates in mediating platelet disaggregation.

Effect of GSH depletion by 1-chloro-2,4-dinitrobenzene on human platelet aggregation, arachidonic acid oxidative metabolism and cytoskeletal proteins

Platelet reduced glutathione (GSH) is completely depleted by 1-chloro-2,4-dinitrobenzene (CDNB), which is a substrate for GSH-S-transferase. GSH-depleted platelets: a) aggregate normally at high inducer concentration; b) respond with increased (after arachidonic acid) or depressed (after collagen) aggregability at low inducer concentration; c) show almost no arachidonic acid-induced stimulation of the hexose monophosphate shunt; d) are sensitized to oxidant agents such as diamide, which elicits a faster cytoskeletal protein oxidative polymerization and reversible aggregation. Our results suggest that GSH acts as a reducing cofactor and/or free radical scavenger in the PG-hydroperoxidase step of the cyclooxygenase pathway; moreover, GSH protects membrane and cytoskeletal protein -SH groups from oxidation.

Do Aspirin and Other Antiplatelet Drugs Reduce the Mortality in Critically Ill Patients

Platelet activation has been implicated in microvascular thrombosis and organ failure in critically ill patients. In the first part the present paper summarises important data on the role of platelets in systemic inflammation and sepsis as well as on the beneficial effects of antiplatelet drugs in animal models of sepsis. In the second part the data of retrospective and prospective observational clinical studies on the effect of aspirin and other antiplatelet drugs in critically ill patients are reviewed. All of these studies have shown that aspirin and other antiplatelet drugs may reduce organ failure and mortality in these patients, even in case of high bleeding risk. From the data reviewed here interventional prospective trials are needed to test whether aspirin and other antiplatelet drugs might offer a novel therapeutic option to prevent organ failure in critically ill patients.

Role of GPIIb-IIIa in platelet-monocyte and platelet-neutrophil conjugate formation in whole blood.

Platelets in stirred whole blood can be induced to form aggregates and also to form heterotypic platelet-monocyte (P/M) and platelet-neutrophil (P/N) conjugates. Here we have investigated the effects of three GPIIb-IIIa antagonists (GR144053F, MK-852 and Reopro, a CD62P-blocking antibody, GA6, and EDTA on the conjugate formation that occurs on stirring whole blood and in response to adding ADP and PAF. We have confirmed the identities of the conjugates by light microscopy after cell sorting. Platelet aggregation was measured by platelet counting. Monocytes, neutrophils, P/M and P/N were detected and quantitated using immunofluorescence and flow cytometry. Stirring whole blood resulted in both platelet aggregation and formation of P/M but not P/N. Adding ADP or PAF to whole blood caused rapid platelet aggregation and generation of both P/M and P/N. All of the GPIIb-IIIa antagonists studied had similar effects: inhibition of stirring-induced platelet aggregation and P/M formation, and inhibition of ADP-induced platelet aggregation and P/N formation. In contrast, they accelerated ADP induced-P/M conjugate formation and PAF-induced formation of both P/M and P/N. Both EDTA and GA6 completely inhibited P/M and P/N, which is commensurate with CD62P being involved in platelet-leucocyte conjugate formation. The results of these investigations suggest that GPIIb-IIIa has a dual role in determining the interaction between platelets and leukocytes.

Formation of platelet-leukocyte conjugates in whole blood

The purpose of this investigation was to obtain information on platelet-leukocyte conjugate formation in whole blood and on factors that affect it. We also measured platelet and leukocyte activation by quantitating the expression of CD62P and CD11b. In both cases a flow cytometric approach was used. The results show that platelet-monocyte and platelet-polymorphonuclear leukocyte (PMNL) conjugate formation is enhanced by simply stirring blood, with optimum conjugate formation occurring after 10 min. In the case of monocytes,conjugate formation was enhanced by adenosine diphosphate (ADP). Both monocyte and PMNL conjugate formation was enhanced by phorbol myristate acetate (PMA), but L-formyl methionyl lysyl proline (FMLP) was either without effect (monocytes) or inhibitory (PMNL). EDTA also inhibited conjugate formation (implying involvement of divalent cations), as did dextran sulphate (implying involvement of P-selectin = CD62P). Interestingly GR144053F, which acts at GpIIb-IIIa on platelets to interfere with fibrinogen binding, and also glycyl prolyl arginyl proline (GPRP), a peptide that interferes with the interaction between CD11c on leukocytes and fibrinogen, did not inhibit platelet-monocyte conjugate formation, but did inhibit the platelet-PMNL interaction; this indicates that GpIIb-IIIa on platelets and CD11c on leukocytes and fibrinogen are involved in mediating the interaction between platelets and PMNL but not platelets and monocytes. Surprisingly arginyl-glycyl aspartyl serine (RGDS) inhibited the formation of both types of conjugate but this may be because it also inhibited both platelet and leukocyte activation as measured by CD62P and CD11b exposure and/or interferes with the binding of adhesion molecules other than fibrinogen. The results show that a flow cytometric procedure can be effective in obtaining rapid information on platelet-leukocyte conjugate formation in whole blood and on factors that are involved in its regulation. It is suggested that the technique may be applicable to the study of platelet-leukocyte conjugate formation in whole blood in disease, and also to study the effects of drugs interfering with conjugate formation.

The effects of GPIIb-IIIa antagonists and a combination of three other antiplatelet agents on platelet-leukocyte interactions

SUMMARY The effects of the GPIIb-IIIa antagonists abciximab and MK-852 on platelet-leukocyte interactions in vitro were studied and the results compared with those obtained with a combination of aspirin, dipyridamole and AR-C69931 (Asp/Dip/AR-C). Platelet-monocyte (P/M) and platelet—neutrophil (P/N) conjugate formation increased when blood was stirred or a platelet agonist was added. Leukocyte activation also occurred as judged by expression of surface tissue factor antigen and CD11b. Abciximab and MK-852 potentiated P/M, especially when collagen was used. They also increased the amount of tissue factor on the monocytes, but not CD11 b. The Asp/Dip/AR-C did not enhance P/M or tissue factor exposure. Augmented tissue factor expression on monocytes in the presence of a GPIIb-IIIa antagonist may be relevant to the increased mortality associated with trials of such antagonists when given orally in patients with vascular disease. The Asp/Dip/AR-C was superior to abciximab and MK-852 in inhibiting platelet and leukocyte function.

Short-term exercise and platelet activity, sensitivity to agonist, and platelet-leukocyte conjugate formation

Strenuous exercise may be partially responsible for cardio-vascular events. The aim was to investigate the platelet activity, reactivity and different platelet-leukocyte-conjugate formation following maximal short-term exercises. Fifteen healthy non-smokers underwent three isokinetic maximal tests on a SRM cycle ergometry system with durations of 15, 45 and 90 s. Blood samples were taken after a 30-min rest, immediately before and after exercise, and 15 min and 1 h after completion of exercise. Platelets were detected flow-cytometrically by CD41, and activated platelets by CD62P. In addition, stimulation of the platelets in vitro with 7.5 μM TRAP-6 was initiated. For testing platelet-leukocyte-conjugates, antibodies against CD45, CD14 and CD41 were used. After the exercise tests the percent of non-stimulated CD62P-positive platelets (%PC) was unchanged. In contrast, an increase in %PC (CD62P) TRAP-6 stimulated (15-s test: 37.2±10.3 to 46.2±12.3%, P < 0.05; 90-s test: 40.6±9.5 to 51.7±10.2%, P < 0.01) and in platelet-granulocyte, platelet-lymphocyte, and platelet-monocyte conjugate formation 15 min after exercise (45- and 90-s test; P < 0.05) were observed in comparison with the changes on the control day. The changes nearly reversed 1 h after exercise. Maximal short-term exercise only leads to a moderate increase of platelet reactivity and to an increase in the different platelet-leukocyte conjugates. The implications of the changes in platelet-leukocyte conjugate formation should be investigated in future studies.

Studies on the effects of agonists and antagonists on platelet shape change and platelet aggregation in whole blood

The shape change that occurs when platelets are stimulated with an agonist can be quantitated by monitoring changes in their forward-scatter/side-scatter profile using a flow cytometer. Here we have stimulated platelets in citrated whole blood with several agonists and determined the time-course and extent of the shape change that occurs. In some experiments parallel investigations of shape change and aggregation were performed. Aggregation was measured by monitoring the fall in number of single platelets using a Whole Blood Platelet Counter. Some agents (ADP, PAF, U46619 and 5HT) produced a strong and rapid change in platelet forward-scatter/side-scatter that was maximal within 10 s. Others (A23187 and collagen) produced a strong but slower response. Adrenaline produced only a weak response that was also slow to develop, and PMA did not produce any response. The concentrations of each of ADP, PAF, U46619 and 5HT needed to induce a shape change were lower than those required for aggregation. Selective PAF, TXA2 and 5HT antagonists (WEB 2086, sulotroban and MCI-9042) clearly inhibited both the shape change and the aggregation induced by the appropriate agonist; in each case the effect of the antagonist was to move the dose-response curve to the right. These results are consistent with the shape change and aggregation brought about by each of these agonists being mediated via a single receptor. In contrast, a selective P2T purinoceptor antagonist (ARL 66096) markedly inhibited the aggregation induced by ADP but was found to have little or no effect on shape change. This is consistent with these platelet responses to ADP being mediated by different receptors, with P2T receptors mediating only the aggregation response.