Inhibition of rat platelet aggregation by a Prudhoe Bay crude oil and its aliphatic,aromatic, and heterocyclic fractions

Wasjed platelets isolated from rats 24 hr after oral treatment with a Prudhoe Bay crude oil (PBCO) showed a substantial inhibition of aggregation induced by ADP, arachidonic acid, or epinephrine. In vitro addition of a dimethyl sulfoxide extract of PBCO or its aliphatic, aromatic, or heterocyclic fractions to washed platelets also resulted in an inhibition of aggregation. ADP release was inhibited in platelets to which an extract of PBCO or its fractions were added in vitro or in platelets isolated from rats treated in vivo with PBCO. Thromboxane B₂ release was increased in platelets isolated from rats intubated with PBCO or in platelets to which a dimethyl sulfoxide extract of the aromatic or heterocyclic fraction was added. However, thromboxane B₂ release was inhibited in platelets to which PBCO or the aliphatic fraction extracts were added. The results indicate that PBCO inhibits platelet aggregation presumably by bringing about alterations in the platelet plasma membrane. Inhibition of ADP release could contribute to the inhibition of aggregation but thromboxane B₂ is believed not to play a significant role.     

Effects of reserpine on rabbit platelet aggregation and adherence to collagen or injured rabbit aorta

Effects of reserpine in vivo and in vitro on rabbit platelets in citrated platelet-rich plasma and in suspensions of washed platelets have been studied. Administration of reserpine ($\text{5}\text{mg}\text{kg}$) intraperitoneally 18 hr before platelets were isolated caused inhibition of collagen-induced aggregation but not of aggregation induced by ADP or thrombin. Thrombin-induced aggregation was slightly enhanced. Platelets from reserpine-treated rabbits were less adherent than control platelets to collagen-coated glass surfaces or to the subendothelium of the rabbit thoracic aorta. Similar effects on aggregation were obtained when reserpine (0.2 to 10 μM) was added to suspensions of washed rabbit platelets as little as 2 sec before the addition of collagen. Collagen-induced release of nucleotides and [¹⁴C]serotonin from prelabeled washed rabbit platelets was not affected by the presence of reserpine, whereas thrombin-induced release was slightly enhanced. Inhibition by reserpine (2–10 μM) of platelet adherence to a collagen-coated surface or to the subendothelium was also observed within a time interval too short for the reserpine to have caused depletion of platelet granule contents. Thus, reserpine has an immediate effect on the plasma membrane of the platelets which is responsible for inhibition of platelet adherence to collagen and hence of collagen-induced aggregation. This inhibitory effect differs from a much slower effect of reserpine at the granule membrane which results in the depletion of the granule contents of serotonin and adenine nucleotides. The effect of reserpine is not abolished by washing and resuspending platelets that have been exposed to reserpine in vivo. By inhibiting the interaction of platelets with collagen, reserpine may interfere with one of the components of hemostatic plug and thrombus formation.     

Effect of cefaclor on guinea pig platelet aggregation in vitro

Effects of cefaclor (3-chloro-7-D-(2-phenyl-glycinamido)-3-cephem-4-carboxylic acid) on PAF, ADP, collagen, endotoxin, and thrombin-induced platelet aggregation were examined in vitro with the use of guinea pig platelet-rich plasma and washed platelets. PAF, even at concentrations lower than its minimum effective concentration, enhanced ADP- or endotoxin-induced platelet aggregation and prolonged the time to attain the maximum aggregation. PAF also enhanced collagen-induced platelet aggregation and shortened the lag time. Cefaclor (CCL) inhibited the PAF, ADP or thrombin induced platelet aggregation and shortened their maximum aggregation times at higher concentrations such as 300 micrograms/ml or more. CCL also inhibited the collagen-induced platelet aggregation and prolonged the lag time, but showed no effect on endotoxin-induced platelet aggregation. The effect of CCL was almost the same as that of latamoxef (LMOX). CCL and LMOX, however, showed no effect on cellular Ca2+ increase produced by PAF, ADP, or thrombin, suggesting that the inhibitory effect of CCL and LMOX on platelet aggregation is caused by the inhibition of fibrinogen binding to the glycoprotein IIb/IIIa complex.     

Shape change and aggregation of blood platelets: interaction between the effects of adenosine and diphosphate, 5-hydroxytryptamine and adrenaline.

1 The interaction of effects between 5-hydroxytryptamine (5-HT) and adenosine diphosphate (ADP) on human or rabbit platelets was investigated in vitro. The initial platelet shape change and their aggregation were measured in stirred, citrated platelet-rich plasma (PRP) at 37 degrees C by recording the rate and extent of changes in light scattering and light transmission. 2 Both the velocity and extent of aggregation and the velocity and extent of the rapid morphological change caused by ADP were enhanced by simultaneous addition of 5-HT. Methysergide but not imipramine inhibited the 5-HT effects. 3 Platelets were made refractory to the aggregating and shape changing effect of either ADP or 5-HT by repeated aggregation with the particular agent; platelets made refractory to ADP retained their responsiveness to 5-HT and platelets made refractory to 5-HT responded to ADP. Platelets pre-incubated for 3-10 min with 5-HT without aggregation showed greatly reduced aggregation on subsequent addition of ADP. Methysergide inhibited all the effects of 5-HT whilst imipramine was inactive. 4 When the shape change or aggregation of platelets induced by ADP was submaximal, addition of 5-HT increased it further. Pre-incubation of PRP with 5-HT before the addition of ADP resulted in failure of the secondary induction of aggregation or shape change by 5-HT. The secondary induction by 5-HT also did not occur in the presence of methysergide; imipramine had no inhibitory effect. Similar secondary induction of aggregation was shown by adrenaline injected during aggregation by ADP; the adrenaline effect was removed by phentolamine but not by propranolol. 5 Our results show that the initial change in shape of platelets and their aggregation can be induced by ADP or 5-HT in specific manner. The interaction of the effect of these substances on platelets can result in either increase in platelet sensitivity or, under certain conditions, decrease in platelet responsiveness. The increase or depression of platelet reactivity appears to be a highly specific effect and is probably mediated at specific receptors involved with platelet activation.     

Irreversible aggregation of pig platelets and release of intracellular constituents induced by 5-hydroxytryptamine

Platelet aggregation and the release of intracellular constituents induced by 5-hydroxytryptamine (5-HT) and by ADP were measured at 37° in stirred pig platelet-rich plasma (PRP) anticoagulated with citrate or heparin. In citrated PRP (with calcium partly chelated) aggregation responses to 0·1–10 μM ADP were reversible, but 50 μM ADP or more caused apparently irreversible aggregation. Aggregation induced by 5-HT was always small and reversible. In heparinised PRP, ADP was around 10 times more potent than in citrated PRP, but the pattern of responses was similar. 5-HT-induced aggregation in heparinised PRP was reversible below 1 μM, but higher concentrations caused irreversible aggregation and released adenine nucleotides from the platelets. 5-HT was more effective than was ADP at releasing platelet constituents. Responses in heparinised PRP were not due to the presence of heparin, but to the absence of a chelating anticoagulant: adding calcium to citrated PRP potentiated responses to 5-HT more than those to ADP.     

Increased platelet aggregation in vivo in the Zucker Diabetic Fatty rat: differences from the streptozotocin diabetic rat

BACKGROUND AND PURPOSE: Diabetes mellitus, especially type 2, is associated with increased arterial thrombosis. Our aims were (i) to characterize and compare platelet aggregation in vivo and in vitro in a type 2 diabetes model; and (ii) to determine whether these results differ from those in a type 1 diabetes model. EXPERIMENTAL APPROACH: Platelet aggregation to ADP in lean or obese Zucker Diabetic Fatty (ZDF) rats and in streptozotocin (STZ)-treated or control Wistar rats was measured in vitro, using Born aggregometry, and in vivo, by (111)Indium-labelled pulmonary platelet accumulation. KEY RESULTS: In vivo, ADP responses were higher in obese (type 2 model) than lean ZDF rats. However, in vitro, ADP aggregation did not differ between platelet-rich plasma from ZDF lean or obese rats; nor was any difference seen in ADP responses when platelets from either lean or obese ZDF rats were suspended in plasma from obese or lean ZDF rats, respectively. In vivo, ADP responses were similar in STZ treated (type 1 model) and control rats whereas, in vitro, isolated platelets from STZ diabetic rats were more responsive to ADP aggregation than controls. Platelets from control or STZ-treated rats suspended in plasma from STZ-treated rats exhibited reduced ADP aggregation, compared to when suspended in plasma from control rats. CONCLUSIONS AND IMPLICATIONS: The platelet aggregation results obtained in vitro do not reflect those in vivo, therefore in vitro aggregation data should be interpreted with caution. Moreover, both in vitro and in vivo, different diabetic models exhibit important differences in platelet responsiveness.     

Differential effect of platelet inhibitors in normal and in hypercholesterolaemic subjects.

Dibutyryl cyclic AMP, forskolin, dipyridamole and butyl imidazole inhibited platelet aggregation (induced by ADP or collagen) in washed platelets more than in platelet-rich plasma preparations. Aspirin, indomethacin and epoprostenol (prostacyclin, PGI2) showed no preferential inhibition of these platelet preparations. When platelet-rich plasma from either normal or familial hypercholesterolaemic (FH) subjects was used, aspirin, indomethacin and dipyridamole (but not forskolin) inhibited platelet aggregation in normal subjects more than in FH patients. When low doses of aspirin (75 mg daily for 7 days) or dipyridamole (250 mg, single dose) were administered in vivo, platelet aggregation was inhibited more in the normal subjects in comparison to the patient group.     

Characterization and molecular cloning of dabocetin, a potent antiplatelet C-type lectin-like protein from Daboia russellii siamensis venom.

A novel C-type lectin-like protein, dabocetin, was purified from Daboia russellii siamensis venom. On SDS-polyacrylamide gel electrophoresis, it showed a single band with an apparent molecular weight of 28 kDa and two distinct bands with the apparent molecular weights of 15.0 kDa and 14.5 kDa under non-reducing and reducing conditions, respectively. cDNA clones containing the coding sequences for dabocetin alpha and beta subunits were isolated and sequenced. The deduced protein sequences of both subunits were confirmed by N-terminal amino acid sequencing and trypsin-digested peptide mass fingerprinting. Dabocetin did not induce platelet aggregation in platelet-rich plasma. It also had little effect on the platelet aggregation induced by ADP, TMVA or stejnulxin. Whereas, dabocetin inhibited ristocetin-induced platelet agglutination in platelet-rich plasma in a dose-dependent manner with an IC50 value of 0.35 microM. Flow cytometry analysis showed that dabocetin significantly inhibited mAb SZ2 binding to platelet membrane glycoprotein Ib alpha, indicating that platelet membrane glycoprotein Ib is involved in the inhibitory effect of dabocetin on ristocetin-induced platelet agglutination.     

Acetal phosphatidic acids: novel platelet aggregating agents

1 Palmitaldehyde, olealdehyde and linolealdehyde acetal phosphatidic acids induced rapid shape change and dose-dependent biphasic aggregation of human platelets in platelet-rich plasma; aggregation was reversible at low doses and irreversible at high doses of the acetal phosphatidic acids. The palmitaldehyde congener elicited monophasic dose-dependent aggregation of sheep platelets in platelet-rich plasma.

2 The threshold concentration for palmitaldehyde acetal phosphatidic acid (PGAP)-induced platelet aggregation was 2.5-5 μM for human platelets and 0.25-0.5 μM for sheep platelets. PGAP was 4-5 times as potent versus human platelets as the olealdehyde and linolealdehyde acetal phosphatidic acids, which were equipotent.

3 PGAP-induced irreversible aggregation of [¹⁴C]-5-hydroxytryptamine ([¹⁴C]-5-HT)-labelled human platelets in platelet-rich plasma was accompanied by release of 44.0±2.4% (s.e.) of the platelet [¹⁴C]-5-HT; reversible aggregation was not associated with release. In contrast, PGAP-induced release of [¹⁴C]-5-HT-labelled sheep platelets was dose-dependent.

4 The adenosine diphosphate (ADP) antagonist, 2-methylthio-AMP, and the cyclo-oxygenase inhibitor, aspirin, abolished PGAP-induced second phase aggregation and release in human platelets but did not affect the first, reversible, phase of aggregation. Both the first and second phases of PGAP-induced aggregation were abolished by chlorpromazine, by the phospholipase A₂ inhibitor, mepacrine, and by nmolar concentrations of prostaglandin E₁ (PGE₁); these agents abolished the second, but not the first phase of ADP-induced aggregation.

5 The related phospholipids, lecithin, lysolecithin and phosphatidic acid, at <100 μM, neither induced aggregation of human platelets in platelet-rich plasma, nor modified PGAP-induced aggregation; 1-palmityl lysophosphatidic acid elicited aggregation of human platelets at a threshold concentration of 100 μM.

6 It is concluded that the acetal phosphatidic acids induce platelet aggregation per se by direct action at the platelet membrane, and that the acetal function is of primary importance in their potent platelet-stimulating activity. Moreover, as the acetal phosphatidic acids are the major components of the smooth muscle-contracting acidic phospholipid tissue extract `Darmstoff' (Vogt, 1949), their potent platelet-aggregating properties may be of physiological or pathological significance.

     

Mechanism of action of the platelet function inhibitor from Vipera russelli siamensis snake venom

Human platelet aggregation induced by ADP, adrenaline, collagen or thrombin was inhibited by the venom inhibitor. Heating reduced both its phospholipase A2 enzymatic and anti-aggregatory activities, although not in parallel. The inhibitor caused significant dose-related inhibitory effects on the clot retraction of rabbit platelet-rich plasma caused by thrombin, while platelet malondialdehyde formation stimulated by thrombin was not affected. Furthermore, the venom inhibitor increased basal cyclic AMP levels in platelets, while cyclic GMP content was slightly lowered, but not in a dose-dependent manner. In addition, microscopic study revealed that the cytoskeleton was disordered after treatment of platelets with the venom inhibitor. The platelets lost their discoid form, while the ultrastructural changes of platelet aggregation induced by ADP were blocked. It is concluded that increasing platelet cyclic AMP and the disorder of the cytoskeleton may be the mechanism of action of the venom inhibitor on platelet function.     

5—HT增强家兔ADP介导的血小板聚集反应

AIM: To study the enhanced effects of 5-hydroxytryptamine (5-HT) on ADP-induced aggregation. METHODS: Platelet aggregation was quantified by the light transmission, the cytosolic-free calcium ([Ca2+]i) was measured by digital fluorescent microscopy, and inositol 1,4,5-triphosphate (IP3) was determined by receptor binding assay. RESULTS: In rabbit platelet-rich plasma (PRP), 5-HT 0.03-3 mumol.L-1 induced a decrease in light transmission (DLT) in a concentration-dependent manner with centralization of granules, as revealed by electron microscopy. The DLT was accompanied with neither platelet aggregation nor a release reaction. In single washed platelets loaded with Fura-2, 5-HT caused a concentration-dependent elevation of [Ca2+]i, and IP3 level was also transiently increased in washed platelets at 15 s after stimulation by 5-HT. Adenosine diphosphate (ADP) also caused DLT transiently in PRP before its own aggregation without a release reaction. Pretreatment of PRP or washed platelets with 5-HT, the DLT by ADP was reduced concentration-dependently and ADP-induced aggregation and [Ca2+]i mobilization were enhanced. CONCLUSION: The enhancement of ADP-induced aggregation was attributed to the superimposition of the calcium release from the storage sites and calcium influx induced by ADP over the calcium release from the storage sites by 5-HT.     

Effect of cobaltous chloride on aggregation of platelets from normal and afibrinogenaemic human blood

The aggregation of normal human platelets in vitro induced by ADP was severely inhibited after preincubation of platelet-rich plasma (PRP) with CoCl2. Platelets from a patient with congenital afibrinogenaemia did not aggregate until fibrinogen was added. This recovered response was also inhibited by CoCl2. The impairment of aggregation seemed to be due to the action of cobalt on surrounding fibrinogen and not to a direct action on the platelets themselves. These results illustrate another aspect of the potential toxicity resulting from the use of cobaltous salts in treating the anaemia of renal failure, in which bleeding disorders have been reported.     

Contribution of ADP to the amplification of primary platelet aggregation by platelet activating factor (PAF): modulatory role of aspirin

Platelet Activating Factor (PAF)-induced human platelet aggregation in citrated plasma is accompanied by activation of the cyclo-oxygenase pathway and release of intracellular constituents including Adenosine-5'-diphosphate (ADP). Inhibition of the cyclo-oxygenase pathway by aspirin prevented the amplification of primary platelet aggregation induced by threshold concentrations of PAF. Removal of ADP by enzymatic systems had little or no effect on PAF-induced full aggregation, but reversed the aggregating effect of PAF (at 10 times threshold concentrations) on 'aspirinated' platelets. Aspirin also prevented the synergism between PAF and ADP when subthreshold concentrations of both compounds were combined. Similar results were obtained in heparinized platelet-rich plasma. Thus, ADP may amplify the primary response to PAF but its role is modulated by the availability of the cyclo-oxygenase pathway products.     

新型血小板GPⅡb/Ⅲa受体拮抗剂Z4A5抗血小板作用的研究

目的研究血小板GPⅡb/Ⅲa受体拮抗剂Z4A5抑制血小板聚集的活性、稳定性以及对已聚集血小板的解聚作用。方法采用比浊法测定Z4A5对体外二磷酸腺苷(aden-osine diphosphate,ADP)诱导血小板聚集的抑制作用和稳定性及对ADP诱导聚集血小板的解聚作用。结果 Z4A5浓度依赖性的抑制ADP诱导的血小板聚集,半数抑制浓度(50%concentration of inhibition,IC50)为(0.46±0.05)μmol.L-1(n=10,P<0.05);Z4A5在血浆中孵育3 h仍保持85.55%(P<0.05)的活性;10μmol.L-1 Z4A5在加入ADP诱导聚集的血小板3 min及7 min后的解聚率为分别为22.66%(P<0.05)及30.93%(P<0.01)。结论 Z4A5在体外有较强的、稳定的抑制血小板聚集作用,而且对聚集血小板有一定的解聚作用。     

Inhibition of Platelet Thromboxane Formation and Phosphoinositides Breakdown by Diisoeugenol

Abstract— Diisoeugenol inhibited the platelet aggregation and ATP release of rabbit platelets caused by ADP, arachidonic acid, platelet-activating factor (PAF), collagen and thrombin. Prolongation of the incubation time of platelets with diisoeugenol did not cause further inhibition and the aggregability of platelets could not be restored after washing. In human platelet-rich plasma, diisoeugenol inhibited the biphasic aggregation and ATP release induced by adrenaline and ADP in a concentration-dependent manner. Thromboxane B₂ formation caused by arachidonic acid, collagen and thrombin was markedly inhibited by diisoeugenol in a concentration-dependent manner. Diisoeugenol also inhibited the formation of inositol monophosphate caused by collagen, PAF and thrombin. The cAMP level of washed platelets was not changed by diisoeugenol. It is concluded that the antiplatelet effect of diisoeugenol is due to the inhibition of thromboxane formation and phosphoinositides breakdown.     

Specific inhibition of PAF-acether-induced platelet activation by BN 52021 and comparison with the PAF-acether inhibitors kadsurenone and CV 3988

BN 52021 is a chemically defined substance extracted from Ginkgo biloba leaves. Its inhibitory potency was tested on washed human platelets prepared so as to render them specifically sensitivity either to adenosine 5'-diphosphate (ADP), arachidonic acid (AA) or PAF-acether. Its activity and specificity were compared with those of two other reported inhibitors of PAF-acether effects: Kadsurenone and CV 3988. PAF-acether-induced aggregation of washed human platelets was concentration dependently inhibited by BN 52021 (IC50: 2.22 +/- 0.79 microM against 7.5 nM PAF-acether (n = 3)). Under the same experimental conditions the aggregation triggered by ADP was not modified and that induced by AA was marginally affected. The PAF-acether EC50 in platelet-rich plasma was increased 5- and 46-fold with 1 microM and 5 microM of BN 52021 respectively. This strongly suggested that the mechanism of action of BN 52021 is of the competitive type. Analysis of [3H]PAF-acether binding showed that BN 52021 as well as unlabelled PAF-acether prevented [3H]PAF-acether binding to intact washed platelets. In washed human platelets Kadsurenone affected only PAF-acether-induced aggregation (IC50: 0.8 +/- 0.4 microM (n = 3)), whereas CV 3988 inhibited the aggregation induced by ADP, AA and PAF-acether (IC50 were 10.2 +/- 2.3 microM; 2.2 +/- 0.1 microM; 1.0 +/- 0.1 microM respectively (n = 3). In contrast, up to 30 microM, CV 3988 was a specific antagonist of PAF-acether-induced platelet aggregation in plasma.(ABSTRACT TRUNCATED AT 250 WORDS)     

Role of platelets in aspirin-sensitive bronchoconstriction in the guinea-pig; interactions with salicylic acid

1 The bronchoconstriction caused in the guinea-pig by arachidonic acid (AA), bradykinin, adenosine diphosphate (ADP) and adenosine triphosphate (ATP) was correlated with effects on platelets. ATP and ADP produced a brief thrombocytopenia and AA a more prolonged one. Bradykinin had no effect on platelets.2 Aspirin inhibited bronchoconstriction and thrombocytopenia produced by AA and part of the bronchoconstriction produced by ATP, but had no effect against ADP. Thrombocytopenia produced by ADP and ATP was not affected by aspirin or indomethacin.3 Platelet depletion by antiserum prevented bronchoconstriction in response to ADP and to ATP, but not in response to bradykinin or to AA, showing that platelets are not involved in aspirin-sensitive bronchoconstriction. Infusions of ADP reduced bronchoconstriction and thrombocytopenia in response to ADP itself and to ATP, but not to AA. Bronchoconstriction by ADP or ATP involves an action on platelets. Only that due to ATP is partially dependent on the activity of prostaglandin synthetase.4 ATP induced aggregation in vitro in guinea-pig platelet-rich plasma (PRP). Rabbit PRP responded only when ATP was first incubated with guinea-pig plasma. The aggregating compound formed was probably ADP, since it was destroyed by apyrase. Its formation was not inhibited by aspirin or indomethacin, indicating that aspirin inhibits ATP-induced bronchoconstriction by a different mechanism.5 The aggregating effect of ATP on guinea-pig platelets was inhibited by concentrations of apyrase that block ADP-induced aggregation, and potentiated by lower concentrations of apyrase.6 Adenosine 5'-tetraphosphate did not aggregate platelets in vivo or in vitro. In vitro aggregation occurred when apyrase was added, suggesting transformation into ADP. Adenosine 5'-tetraphosphate and apyrase inhibited aggregation due to ADP, but failed to affect that due to AA. This suggests that aggregation involving products of prostaglandin synthesis does not require ADP.7 Salicylic acid did not interfere with bronchoconstriction or aggregation due to AA, but prevented inhibition by aspirin when the weight ratio, salicylic acid:aspirin was 4:1. Salicyclic acid may be useful in studies of potential inhibitors of thromboxane A2 synthesis and of thromboxane A2-dependent processes in vivo and in vitro.     

Resveratrol inhibits aggregation of platelets from high-risk cardiac patients with aspirin resistance

Up to 20% of serious vascular events in high-risk vascular patients is attributable to a failure of aspirin (ASA) to suppress platelet aggregation. Resveratrol is a cardioprotective phytoestrogen that can inhibit platelet aggregation in animal models. We hypothesized that resveratrol can also inhibit aggregation of platelets from ASA-resistant (ASA-R) patients. Thus, platelet-rich plasma was isolated from ASA-sensitive (ASA-S) and ASA-R patients (aspirin resistance was defined as higher-than-expected aggregation to collagen and epinephrine [>/=40%] after oral treatment with 100 mg/d ASA). Aggregation to adenosine diphosphate (ADP; 5 and 10 mumol/L), collagen (2 mug/mL), and epinephrine (10 mumol/L) in the absence and presence of resveratrol (10 mol/L) was measured by optical aggregometry. Maximal aggregation to 5 mumol/L ADP was only slightly affected by resveratrol. Similar results were obtained using 10 mumol/L ADP. Maximal aggregation of ASA-R platelets to collagen was significantly decreased by resveratrol, whereas resveratrol had only marginal effects in ASA-S platelets. Similar results were obtained with epinephrine as well. Collectively, resveratrol effectively inhibited collagen- and epinephrine-induced aggregation of platelets from ASA-R patients, which may contribute to its cardioprotective effects in high-risk cardiac patients.     

Specific inhibition of ADP-induced platelet aggregation by clopidogrel in vitro

1. The thienopyridine clopidogrel is a specific inhibitor of ADP-induced platelet aggregation ex vivo. No direct effects of clopidogrel (< or = 100 microM) on platelet aggregation in vitro have been described so far. 2. Possible in vitro antiaggregatory effects (turbidimetry) of clopidogrel were studied in human platelet-rich plasma and in washed platelets. 3. Incubation of platelet-rich plasma with clopidogrel (< or = 100 microM) for up to 8 h did not result in any inhibition of ADP (6 microM)-induced platelet aggregation. 4. Incubation of washed platelets with clopidogrel resulted in a time- (maximum effects after 30 min) and concentration-dependent (IC50 1.9+/-0.3 microM) inhibition of ADP (6 microM)-induced platelet aggregation. Clopidogrel (30 microM) did not inhibit collagen (2.5 microg ml(-1))-, U46619 (1 microM)- or thrombin (0.1 u ml(-1))-induced platelet aggregation. The inhibition of ADP-induced aggregation by clopidogrel (30 microM) was insurmountable indicating a non-equilibrium antagonism of ADP actions. The R enantiomer SR 25989 C (30 microM) was significantly less active than clopidogrel (30 microM) in inhibiting platelet aggregation (32+/-5% vs 70+/-1% inhibition, P < 0.05, n = 5). 5. In washed platelets, clopidogrel (< or = 30 microM) did not significantly reverse the inhibition of prostaglandin E1 (1 microM)-induced platelet cyclic AMP formation by ADP (6 microM). 6. The antiaggregatory effects of clopidogrel were unchanged when the compound was removed from the platelet suspension. However, platelet inhibition by clopidogrel was completely abolished when albumin (350 mg ml(-1)) was present in the test buffer. 7. It is concluded that clopidogrel specifically inhibits ADP-induced aggregation of washed platelets in vitro without hepatic bioactivation. Inhibition of ADP-induced platelet aggregation by clopidogrel in vitro occurs in the absence of measurable effects on the reversal of PGE1-stimulated cyclic AMP by ADP.     

Antiplatelet action of ilexoside D,a triterpenoid saponin fromIlex pubescens

The anti-platelet activity of ilexoside D isolated from the roots ofIlex pubescens Hook. et Arn. was investigated inin vitro andex vivo models of platelet aggregation induced by ADP, thrombin or collagen in rats.In vitro ilexoside D inhibited more effectively platelet aggregation induced by ADP and thrombin than by collagen as compared with aspirin.Ex vivo ilexoside D also inhibited platelet aggregation induced by ADP and collagen, but not by thrombin, and the inhibitory action of ilexoside D was more effective than that of aspirin. However,in vitro ilexoside D inhibited very poorly the generation of malonyldialdehyde, which is known to be concomitantly released with thromboxane A₂ during platelet aggregation. These results suggest that the anti-platelet activity of ilexoside D may not be responsible for prostaglandin synthesis in platelets.