Synergistic effects of platelet-activating factor and other platelet agonists in human platelet aggregation and release: The role of adp and products of the cyclooxygenase pathway

The synergistic effects of platelet-activating factor (PAF) with ADP, collagen, thrombin, A23187, adrenaline, sodium arachidonate and ristocetin in human platelet aggregation and ß-thromboglobulin (ß-TG) release were investigated in citrated platelet-rich plasma (PRP). Synergism in both aggregation and release was present with all agonists except ristocetin.Upon oral intake of aspirin (ASA) the PAF-induced irreversible aggregation as well as the synergistic irreversible aggregation became reversible. Both prior to and after ASA ingestion ADP removal by creatine phosphate/creatine phosphokinase (CP/CPK) resulted in a reduced, reversible platelet aggregation induced by PAF alone or in combination with the other agonists. The ADP-removal and ASA-ingestion also strongly inhibited the ß-TG release. The synergistic aggregation and release were also inhibited by ASA and indomethacin in vitro as well as by the competitive ADP-inhibitor ATP.It is concluded that not only the activation of human platelets by low doses of PAF itself, but also the synergism of PAF and other platelet agonists is highly dependent upon ADP and products of the cyclooxygenase pathway.     

Malondialdehyde formation by blood platelets: a diagnostic test to assess acetylsalicylic acid induced thrombocytopathy?

We investigated whether the measurement of N-ethylmaleimide stimulated malondialdehyde (MDA) formation by blood platelets from normal subjects is equally sensitive to acetylsalicylic acid intake as are platelet aggregation studies. MDA production and platelet aggregation by collagen and arachidonate were assayed in ten healthy volunteers before and up to ten days after a single oral dose of 500 mg aspirin. Discordant results of the two tests were seen in several subjects 4 to 6 days after aspirin intake. In three cases with still suppressed MDA values on day 4, collagen or arachidonate induced aggregation was normalized. However, on day 6, when MDA was normalized in all subjects, the aggregation response to arachidonate was still pathologic in 5 of the ten volunteers. In case of a patient with abnormal aggregation response to arachidonate and/or collagen, therefore, a normal MDA value does not permit to exclude aspirin as the cause of the platelet dysfunction.     

Synergistic actions of paf-acether and sodium arachidonate in human platelet aggregation. 2. Unexpected results after aspirin intake

The effect of sodium arachidonate and paf-acether on the activation of human platelet rich plasma from volunteers 2.30 to 36 hours after 500 mg of aspirin intake was studied. Concentrations of paf-acether which induce a reversible aggregation in platelet rich plasma (PRP) (0.29-0.029 microM) and concentrations of sodium arachidonate (AA) which don't produce aggregation (0.75-1mM) on the PRP from these volunteers, induced full aggregation when added together. But no cooperation activity was achieved in the 2.30 hours sample. Contrarily to the in vitro studies performed in human normal PRP, ASA (200 micrograms/ml) or indomethacin(12 microM) added to the PRP were unable to suppress the cooperative aggregation effect; neither did apyrase (12U/ml), esculetin (10 microM) or nordihydroguaiaretic acid (0.1 microM) have any action on the activated platelets but the synergistic action is completely suppressed by BW 755C (0.1 mM). TXB2 formation is very low in all these activated samples and insufficient to cause platelet aggregation. These results suggest 2 behaviors of platelets: synergistic activity of paf-acether and exogenous AA in vitro on normal human PRP is mediated mainly through active metabolites of AA formed via cyclooxygenase, as was previously published. When cyclooxygenase is inhibited in vivo by administration of 500 mg ASA, the cooperative effect of agonists is still present but the active aggregating product(s) is probably, formed through a pathway different of that of the cyclooxygenase or lypoxygenase.     

The antiplatelet effect of daily low dose enteric-coated aspirin in man: A time course of onset and recovery

We have studied the onset and recovery of inhibition of platelet function by low dose aspirin. Enteric-coated aspirin 50mg daily was administered to five human volunteers for five weeks and then 100mg daily was given for a further five weeks. We studied platelet aggregation and thromboxane formation in response to a range of stimuli: ADP, adrenaline, arachidonate and collagen, and also measured thromboxane formation after coagulation of whole blood (serum thromboxane). The onset of inhibition of platelet aggregation was progressive over several days for each of the four platelet stimuli, and was synchronous with the inhibition of thromboxane formation. Maximum inhibition occurred by day three for the weak stimuli ADP and adrenaline, by day five for the stronger stimuli arachidonate and collagen, but did not occur until day eight for serum thromboxane. Further inhibitory effects on both aggregation and thromboxane generation were observed after 100mg daily. Two weeks after the cessation of aspirin the responses to collagen and arachidonate and serum thromboxane had returned to normal. Platelet aggregation in response to the weaker stimuli, ADP and adrenaline, still showed detectable inhibition two weeks after cessation of aspirin, but had returned to normal by four weeks. These experiments provided no evidence for an effect of aspirin on platelets separate to its effect on cyclooxygenase. The onset and recovery of inhibition of platelet function by low dose aspirin was dependent on the strength of the stimulus studied.     

Effects of aggregating agents and of blood cells on the aggregation of whole blood by impedance technique

In this study the effects of different aggregating agents on platelet rich plasma (PRP) and whole blood (WB) aggregation, as determined by the optical and the impedance method, are evaluated. While the response of PRP to PAF, epinephrine and sodium arachidonate was comparable using the two methods, significantly greater amounts of collagen and ADP were required to obtain 50% aggregation of PRP. In addition, when the response of WB to the aggregation induced by different agents was compared to that of PRP (impedance method), no difference between WB and PRP was detected, with exception for ADP and sodium arachidonate induced aggregation. In vitro data on the aggregation of PRP induced by collagen and ADP in the presence of different concentrations of red cells and of white cells, suggest that WC and RC may affect PRP aggregation only in selected experimental conditions.     

Kinetic parameters of platelet aggregation as an expression of platelet responsiveness

The kinetics of platelet aggregation induced by collagen and by ADP were studied. The maximum aggregation (deltaLTmax) and the ADP and collagen concentrations required to produce half-maximum aggregation (Kd) were determined using platelets obtained from normal individuals, individuals who ingested aspirin and individuals whose platelet-rich plasma (PRP) demonstrated spontaneous aggregation. The Kd and deltaLTmax for ADP-induced platelet aggregation were variable and markedly affected by the citrate concentration. Conversely, kinetic parameters of collagen-induced aggregation were more reproducible and less affected by citrate. The Kd for collagen in platelet aggregation was increased following aspirin ingestion and decreased in samples of PRP that demonstrated spontaneous aggregation. These results suggest that kinetic parameters of platelet aggregation may be useful to express the responsiveness of platelets.     

Platelet aggregation in human whole blood after chronic administration of aspirin

We have used the impedance aggregometer to study the "ex vivo" effect of acetylsalicylic acid (ASA) in whole blood (WB) versus platelet-rich plasma (PRP) in 35 male healthy volunteers after 10 days of treatment with 25, 50, 125, 250, and 500 mg/day of ASA. Percent of inhibition of platelet aggregation was determinated at the end of treatment. A greater inhibition of platelet aggregation was observed in WB than in PRP when ASA was administrated at almost all doses. Maximal differences were at 25, 50, and 125 mg/day of ASA on adrenaline, collagen and arachidonic acid induced aggregation, and with 250 and 500 mg/day of ASA when ADP was used as aggregating agent. In the "in vitro" trials, IC-50 values of ASA on ADP and collagen induced aggregation were determined in platelet aggregation by the impedance method in both WB and PRP. ASA shows a lower IC-50 in WB than in PRP. When leucocytes were incubated in PRP samples, it effect was similar to the percent of inhibition in WB.     

Arachidonate-induced platelet aggregation in the dog.

The platelet rich plasma (PRP) from most dogs aggregates in response to ADP, collagen and thrombin. Dog PRP generally does not aggregate in response to epinephrine, and previous studies found that dog PRP uniformly failed to aggregate when exposed to arachidonic acid prepared in an ethanol-sodium carbonate medium. Our studies demonstrate that 30% of randomly selected mongrel dogs have PRP which aggregates when exposed to sodium arachidonate dissolved in modified Tyrode's buffer, PRP from these dogs also aggregates with lower concentrations of ADP and collagen than PRP which is unresponsive to arachidonate. Pre-incubation of PRP with epinephrine uniformly transforms PRP which does not aggregate on exposure to arachidonate alone into arachidonate-aggregating PRP. Dog PRP which aggregates with arachidonate release ¹⁴C-serotonin, while non-aggregating PRP does not. However, arachidonate stimulates malondialdehyde production in both aggregating and non-aggregating PRP.The results of this study indicate that dogs are heterogeneous in regard to their aggregation response to arachidonate. The mechanism of this heterogeneity is unknown: however, since prostaglandin metabolism is intact and the platelets of some dogs respond to arachidonate alone, it appears to be the result of variable sensitivity to endoperoxides and thromboxane A₂.     

Effect of sodium arachidonate on thrombin generation through platelet activation--inhibitory effect of aspirin

BACKGROUND: Sodium arachidonate was used in this study to determine its capacity to generate thrombin through platelet activation. Whether aspirin prevent this effect was also investigated. METHODS AND RESULTS: Seventeen healthy volunteers without and after 160 mg/day aspirin intake for 3-5 days were studied. Lag-time and TG at basal condition and after platelet stimulation by sodium arachidonate (AA) were measured in normal non-aspirinated as well as "in vivo" aspirinated platelet rich plasma. (PRP). The lag-time was statistically significant shorter in non-aspirinated PRP activated with AA compared with non-activated PRP. This effect was inhibited by aspirin. In non-aspirinated PRP, there was an increase of TG at 4 and 6 min. incubation when platelets were activated with AA but the difference disappeared after 8 min. incubation, (84 +/- 71; 148 +/- 58 and 142 +/- 92 nmol/L respectively) compared with non-aspirinated. non-activated platelets (16 +/- 23; 55 +/- 56 and 111 +/- 76 nmol/L at 4,6 and 8 min, p < 0.0001, p < 0.0001 and p = 0.292, respectively). The AUCo-->22 min were 520.6 +/- 545.5 in non-aspirinated, non-stimulated PRP and 808.9 +/- 617, in non-aspirinated PRP activated with sodium arachidonate (p = 0.014). Aspirin administered in vivo produced a decrease of TG in PRP activated with AA. CONCLUSION: Platelet activated by AA trigged TG. This effect was inhibited by aspirin and could be an additional beneficial effect of aspirin in the prevention of thrombosis.     

Peripheral venous plasma aspirin concentrations and platelet aggregation inhibition produced by enteric-coated aspirin formulations

In a random cross-over design, six healthy consenting adult volunteers were given on separate occasions single doses of 300-650 mg of 3 different formulations of enteric-coated aspirin. Over various intervals for 48-54 h following dosage, plasma aspirin and salicylate concentrations were measured together with percentage inhibition of platelet aggregation activated by threshold concentrations of sodium arachidonate alone and combined with ADP and collagen. In all subjects each formulation delivered measurable quantities of aspirin to the peripheral circulation, the unchanged drug being detected at various times up to and including 28 h after dosage. Moreover, low aspirin concentrations were found to co-exist with unimpaired platelet aggregation. All 3 formulations yielded statistically significant (P less than 0.01) inhibition of platelet aggregation activated both by arachidonate and by the combination of aggregants when tested 24-29 and 48-54 h after dosage; there were no significant differences (P greater than 0.05) between the 3 formulations in this regard. Two different patterns of delivery of unchanged aspirin to the systemic circulation from these enteric-coated formulations were apparent. These patterns may be important when considering which aspirin formulation might be most appropriate in chronic use for an antiplatelet effect. None of the enteric-coated formulations used in this study may be optimal in this regard.     

Abciximab treatment in vitro after aspirin treatment in vivo has additive effects on platelet aggregation, ATP release, and P-selectin expression

To prevent arterial thrombosis, abciximab is administered together with aspirin. However, whether or not there are benefits to combine abciximab with aspirin is not yet well defined. Healthy volunteers were studied for the effect of aspirin+abciximab using sodium arachidonate and adenosine diphosphate (ADP) alone or in combination to induce platelet activation/aggregation. Abciximab produced complete inhibition of platelet aggregation induced with ADP but only 40% inhibition of aggregation induced by 0.75-mmol/l sodium arachidonate. Abciximab added in vitro to platelet-rich plasma (PRP) from platelets from aspirin-treated donors produced an almost complete inhibition of platelet aggregation. Aspirin, and abciximab alone, did not inhibit adenosine triphosphate (ATP) release as thoroughly as aspirin+abciximab did. Abciximab (3–5 μg/ml) produced inhibition of P-selectin expression induced with 5 (from 46.2±6.0% to 27.4±7.0%, P=.002) and 20-μmol/l ADP (from 53.1±8.1% to 35.1±11.0%, P=.019), but no effect was observed when 0.75-mmol/l sodium arachidonate was used (P=.721). Aspirin diminished P-selectin expression in sodium arachidonate-stimulated platelets (from 77.7±11.8% to 40.2±3.6%, P<.0001) in non-aspirinated and platelets from aspirin-treated donors, respectively. Abciximab (3, 4, and 5 μg/ml) added to platelets from aspirin-treated donors decreased P-selectin expression in platelets stimulated with sodium arachidonate from 40.2±8.6% to 25.6±11.5% (P=.027), to 20.5±3.5% (P<.0001), and to 22.5±1.8% (P<.0001). We concluded that the antiplatelet effect of abciximab is greatly increased by aspirin.     

Synergism between platelet aggregating agents: the role of the arachidonate pathway.

Aggregation of platelets by low concentrations of ADP is augmented by non-aggregating concentrations of collagen, thrombin, arachidonate or the divalent cation ionophore A23,187. Release-inducing agents act synergistically with ADP and with each other. Both collagen and thrombin cause aggregation by releasing ADP and by freeing platelet arachidonate to form prostaglandin endoperoxides which give rise to thromboxane A₂. In these experiments the role of the arachidonate pathway in the synergism between pairs of aggregating and release-inducing agents was examined. Indomethacin was used to inhibit conversion of arachidonate to prostaglandin endoperoxides and thromboxane A₂ and creatine phosphate/creatine phosphokinase (CP/CPK) was used in some experiments to convert released ADP to ATP. Synergism of collagen with ADP, arachidonate or thrombin was inhibited by indomethacin indicating that the arachidonate pathway plays a major role in the synergistic effects to which collagen contributes. Synergism of thrombin with collagen or arachidonate was inhibited by indomethacin but synergism of thrombin with ADP was only slightly affected. Indomethacin had little influence on the combined effects of these two agents on platelet aggregation. Thus it appears that the conversion of platelet arachidonate to prostaglandin endoperoxides and thromboxane A₂ plays a minor part in the synergistic effects in which thrombin or A23,187 are involved. Thus, the non-steroidal anti-inflammatory drugs may have only limited use in inhibiting the contribution of thrombin and ADP to the formation of platelet thrombi at sites of vessel injury.     

Some properties of mouse platelets

Mouse platelets were aggregated by arachidonate, thrombin, collagen and ADP. In general they were, like rat platelets, more aggregable in heparinized PRP than in citrated (3.8%) PRP. Mouse platelets underwent the release reaction when aggregated by arachidonate, collagen and thrombin, but not when stimulated by ADP. The aggregation of the platelets to arachidonate was inhibited by cyclooxygenase inhibitors and by prostacyclin. Studies with tritiated arachidonate showed that mouse platelets possess the lipoxygenase and cyclooxygenase pathways found in other mammalian platelets and produce thromboxane and 12-HETE. The mouse provides a convenient model for the study of many conditions known to affect platelet aggregation. The similarity of mouse platelets to the platelets of other mammals together with the ability to study large numbers of animals at low cost, should encourage further use of mouse platelets.     

Inhibition of human platelet function in vitro and ex vivo by acetaminophen

The effects of acetaminophen (APAP) in vitro, or ex vivo following APAP ingestion, on human platelet aggregation, ¹⁴C-5HT secretion, and thromboxane B₂ (TxB₂) formation were assessed. APAP added in vitro to citrated platelet-rich plasma (PRP) inhibited aggregation, secretion, and TxB₂ formation induced by collagen, epinephrine, arachidonate, and the ionophore A23187, but had no effect on the responses induced by the endoperoxide analog U44069. Arachidonate-induced responses were inhibited by lower concentrations of APAP than were the responses to the other agonists. In PRP obtained 1 hour after ingestion of 650 mg or 1000 mg APAP, arachidonate-induced TxB₂ formation was inhibited by 40–99% in five subjects tested, whereas inhibition of collagen- or epinephrine-induced TxB₂ formation was less consistent. Aggregation and secretion responses were not altered by APAP ingestion m 4 of the 5 subjects, but were inhibited in the remaining subject, who had the highest plasma APAP levels. In contrast to aspirin and indomethacin, APAP-induced inhibition of collagen-stimulated TxB₂ formation could be partially overcome with increasing collagen concentrations. No such partial correction occurred with epinephrine, however. In washed platelet suspensions labeled with ³H-arachidonate, both APAP and aspirin inhibited the formation of labeled PGD₂ and PGE₂, as well as TxB₂. These results suggest that APAP acts in human platelets as a reversible inhibitor of cyclo-oxygenase, as found previously in other tissues, and that recent APAP ingestion can, on occasion, produce inhibition of platelet functional responses measured in vitro.     

The effects of argon laser on in vitro aggregation of platelets in platelet rich plasma and whole blood

The effects of an Argon laser on platelet aggregation were studied, since platelets may be exposed to laser energy when used intravascularly. Various preparations of platelets in platelet rich plasma (PRP) and whole blood, with or without aspirin, were tested with the aggregating agents ADP, collagen, thrombin, and epinephrine. Simultaneous release of ATP was also measured in PRP. At relatively low levels of irradiation, platelet aggregation was potentiated. Enhancement was evidenced by an increase in percent aggregation, earlier onset of the reaction, and reduction in the amount of aggregating agent required. In PRP, the mechanism of laser potentiation appeared to be the release of endogenous ATP from platelets. At relatively high levels of irradiation, platelets were destroyed and aggregation abolished. In whole blood, the mechanism was somewhat more complicated since release of ATP occurred from RBCs as well as platelets. Spontaneous aggregation following laser treatment occurred in isolated instances in PRP and in every trial in whole blood preparations. Aspirin ingestion inhibited the laser's effects in PRP but not in whole blood. These results may have important clinical implications for laser angioplasty, and the potentiated aggregation response may prove useful in laboratory studies of platelet function.     

Effect of increasing doses of aspirin on platelet aggregation among stroke patients

BACKGROUND AND PURPOSE: Aspirin has been shown to reduce the risk of myocardial infarction and stroke. Some investigators believe that low-dose aspirin inhibits platelet aggregation to the same degree as high-dose aspirin. Our study aimed to assess the effect of increasing doses of aspirin on the degree of platelet aggregation induced by collagen and adenosine diphosphate (ADP) among stroke patients. METHODS: Sixteen poststroke patients were prescribed aspirin at daily doses of 40, 80, 160, 325, 650, and 1,300 mg, each dose to be taken for 14 days (total duration 12 weeks). Platelet aggregation studies using 2 microgram/ml collagen and 2 microM ADP were performed on platelet-rich plasma at baseline and on the 14th day of each dose. RESULTS: Platelet aggregation studies using 2 microgram/ml collagen at the start of treatment and at the 14th day of each dose revealed dose-dependent inhibition by aspirin starting at 40 mg/day, but was optimal at 80- 160 mg/day. ADP-induced platelet aggregation inhibition appears to be dose dependent up to 1,300 mg/day. CONCLUSION: Inhibition of collagen-induced platelet aggregation by aspirin appears to be optimal at 80-160 mg/day, while ADP-induced platelet aggregation inhibition by aspirin appears to be dose dependent up to 1,300 mg/day in our poststroke patients, albeit to a less remarkable degree at higher doses.     

Sex differences in mouse platelet aggregation

The role of platelets in the sex difference observed in mouse thrombosis models was evaluated by examining platelet diminution in vivo after thrombotic challenge, and aggregation of mouse platelets in PRP. A fall in platelet count was observed in both sexes after i.v. injection of either arachidonic acid or the thromboxane agonist, U46619. Platelet diminution induced by high dose arachidonate (50 mg/kg) was significantly greater in males compared to female mice. Responses to U46619 were similar in both sexes. In PRP, male platelets exhibited a greater response than female platelets to both ADP (15 uM) and arachidonate (0.3 mM), but not to U46619 (4.6 and 6.9 uM). These results suggest that the gender difference in arachidonate-induced sudden death, in which males are more susceptible than females, is related to a sex difference in mouse platelet function.     

Phospholipase C from clostridium perfringens induces human platelet aggregation in plasma

We studied the aggregating effect of different concentrations of phospholipase C (PLC) (extracted from Clostridium perfringens) on human platelet-rich plasma (PRP). PRP was preincubated with PLC for 3 min at 37 degrees C and the platelet aggregation was followed for 10 min. The threshold aggregating concentration (TAC) of PLC was 3-4 U/ml. We also studied the potentiation of PLC with other stimuli on platelet aggregation. Potentiating stimuli, such as arachidonic acid (AA), ADP. Platelet Activating Factor (PAF) and U-46619 (a stable analogue of cyclic endoperoxides) were all used at subthreshold concentrations. We also studied the possible inhibitory effect of aspirin, apyrase, TMQ, a prostaglandin endoperoxide/thromboxane receptor antagonist and BN-52021, a PAF receptor antagonist. Only aspirin and apyrase were able to reduce aggregation induced by PLC alone and PLC + AA and PLC + ADP respectively. TMQ and BN-52021 were inactive. In ex vivo experiments oral aspirin (500 mg) partially inhibited platelet aggregation induced by PLC alone, PLC + AA and PLC + ADP 2 and 24 h after administration. Aspirin 20 mg for 7 days also reduced aggregation induced by PLC + AA.     

Testosterone potentiation of ionophore and ADP induced platelet aggregation: relationship to arachidonic acid metabolism

The role of arachidonic acid oxygenated products in human platelet aggregation induced by the ionophore A23187 was investigated. The ionophore produced an increased release of both saturated and unsaturated fatty acids and a concomitant increased formation of TxA2 and other arachidonate products. TxA2 (and possibly other cyclo oxygenase products) appears to have a significant role in ionophore-induced aggregation only when low concentrations (less than 1 micro M ) of the ionophore are employed. Testosterone added to rat or human platelet-rich plasma (PRP) was shown previously to potentiate platelet aggregation induced by ADP, adrenaline, collagen and arachidonic acid (1, 2). We show that testosterone also potentiates ionophore induced aggregation in washed platelets and in PRP. This potentiation was dose and time dependent and resulted form increased lipolysis and concomitant generation of TxA2 and other prostaglandin products. The testosterone potentiating effect was abolished by preincubation of the platelets with indomethacin.     

Collagen-induced platelet aggregation:--evidence against the essential role of platelet adenosine diphosphate

The hypothesis that platelet ADP is responsible for collagen-induced aggregation has been re-examined. It was found that the concentration of ADP obtaining in human PRP at the onset of aggregation was not sufficient to account for that aggregation. Furthermore, the time-course of collagen-induced release in human PRP was the same as that in sheep PRP where ADP does not cause release. These findings are not consistent with claims that ADP alone perpetuates a collagen-initiated release-aggregation-release sequence. The effects of high doses of collagen, which released 4-5 microM ADP, were not inhibited by 500 microM adenosine, a concentration that greatly reduced the effect of 300 microM ADP. Collagen caused aggregation in ADP-refractory PRP and in platelet suspensions unresponsive to 1 mM ADP. Thus human platelets can aggregate in response to collagen under circumstances in which they cannot respond to ADP. Apyrase inhibited aggregation and ATP release in platelet suspensions but not in human PRP. Evidence is presented that the means currently used to examine the role of ADP in aggregation require investigation.