Mechanism of the action of biogenic chloramines and hypochlorite on the initial aggregation of platelets

The antiaggregant effect of two reactive oxidants—N,N-dichlorotaurine (a biogenic chloramine) and sodium hypochlorite—on the initial ADP-induced aggregation of rabbit blood platelets was studied. Platelet aggregation in reconstituted platelet-rich plasma was measured nephelometrically; an increase in the intensity of small-angle light scattering served as an index of aggregation. Addition of chloramine at relatively small concentrations (no greater than 1 mM available chlorine) directly to the reconstituted platelet-rich plasma suppressed the initial aggregation (formation of small aggregates) several times more strongly than preincubation of native plasma with chloramine. This suggests that N,N-dichlorotaurine realizes its antiaggregant effect on the platelet-rich plasma by directly interacting with cells. The effects of the inhibition of platelet aggregation in two variants of addition of high concentrations of N,N-dichlorotaurine did not differ significantly. In this case, a large amount of residual unreacted chloramine remained in the plasma, which caused the suppression of platelet aggregation during subsequent reconstitution of the platelet-rich plasma. Similar data were obtained in studying the antiaggregant effect of hypochlorite. N,N-Dichlorotaurine and hypochlorite at concentrations of 0.2–0.3 and 0.15 mM, respectively, strongly inhibited the initial aggregation of isolated platelets (approximately 2·10⁸ cells/ml) preliminarily activated for 1.5 min by addition of 0.1–0.5 μM ADP. However, the antiaggregants had a more profound suppressive effect on the aggregation of unstimulated platelets. The antiaggregant effects of N,N-dichlorotaurine and hypochlorite probably stem from the oxidative modification of the sulfur-containing groups in platelet plasma membrane.     

Characterization of a potent platelet aggregation inhibitor from Agkistrodon rhodostoma snake venom

By means of CM-Sephadex C-50 column chromatography and gel filtration on Sephadex G-75 and G-50 columns, a potent platelet aggregation inhibitor was purified and characterized. It was a glycoprotein with a molecular weight of 31,000. It was devoid of phospholipase A, ADPase, esterase and fibrino(geno)lytic activities. It inhibited dose-dependently the aggregation of washed platelets induced by collagen, thrombin, sodium arachidonate, platelet activating factor and ionophore A23187 with a similar IC50 (5-10 micrograms/ml). It was also active in platelet-rich plasma, with an IC50 of 10-15 micrograms/ml. The venom inhibitor reduced the elasticity of whole blood clot and inhibited the thrombin-induced clot retraction of platelet-rich plasma. These activities were related to its inhibitory activity on platelet aggregation rather than blood coagulation. The venom inhibitor had various effects on [14C]serotonin release stimulated by aggregation agonists. It had no effect on thromboxane B2 formation of platelets stimulated by sodium arachidonate, collagen and ionophore A23187. The presence of this venom inhibitor prior to the initiation of aggregation was a prerequisite for the maintenance of its maximal activity. It showed a similar inhibitory effect on collagen or thrombin-induced aggregation even when it was added after the platelets had undergone the shape change. High fibrinogen levels partially antagonized its activity. The venom inhibitor completely inhibited the fibrinogen-induced aggregation of alpha-chymotrypsin-treated platelets. It is concluded that this venom inhibitor interferes with the interaction of fibrinogen with fibrinogen receptors, leading to inhibition of aggregation.     

Potent platelet aggregation inhibitor from Trimeresurus gramineus snake venom

Using DEAE-Sephadex A-50 column chromatography and gel filtration, a potent platelet aggregation inhibitor from Trimeresurus gramineus venom was purified. It was an acidic phospholipase a, rich in aspartic acid, glutamic acid and half-cystine, with an isoelectric point of 3.6. At a concentration of 10 μg/ml, the purified inhibitor showed a marked inhibitory effect on platelet aggregations induced by adenosine diphosphate, collagen, sodium arachidonate and ionophore A-23187 in rabbit platelet-rich plasma, washed platelet suspension, as well as in thrombin-degranulated platelet suspension. The ID₅₀ of this venom inhibitor was about 2.5–5 μg/ml in platelet aggregations induced by all these aggregation inducers. The action of this inhibitor could be partially antagonized by phosphatidylethanolamine. High concentration of Ca²⁺ (5 mM) did not reverse the inhibitory action even in the presence of ionophore A-238187. The [¹⁴C]serotonin release induced by sodium arachidonate and thrombin was unaffected. Malonic dialdehyde formation induced by these aggregation inducers remained unchanged. Basal and prostaglandin E₁-stimulated cAMP levels were not altered by this inhibitor. No lactate dehydrogenase was released even at a concentration of 62.5 μg/ml. Polylysine-induced platelet agglutination was not affected. β-Mercaptoethanol inactivated both its phospholiase A enzymatic and platelet inhibitory activities, while p-bromophenacyl bromide only inactivated the former activity. The possibility of acting on a common final step of platelet aggregation, i.e. the intercellular adhesion between the activated platelets, was proposed.     

Characterization of ATP-diphosphohydrolase activities in the intima and media of the bovine aorta: evidence for a regulatory role in platelet activation in vitro.

The inner layer of the aorta contains the enzyme ATP diphosphohydrolase (ATPDase: EC 3.6.1.5) which catalyzes the sequential phosphorolysis of ATP----ADP----AMP. Two zones of the inner layer, the intima and media, were separated and both were shown to contain ATPDase activity of similar specific activity (0.08 and 0.10 U/mg protein, respectively). However, the media exhibited about 100-times more enzyme activity than the intima. Both preparations were virtually identical with respect to pH optima (7.5), migration patterns after electrophoresis under non-denaturing conditions, relative rates of ATP and ADP hydrolysis and potency to inhibit ADP-induced platelet aggregation in both human platelet-rich plasma and whole blood. The IC50 values for ADP (2 microM)-induced aggregation were 6.8 and 12.9 mU/ml in platelet-rich plasma and whole blood, respectively. Addition of ATPDase to platelets pre-aggregated with ADP resulted in a dose-dependent disaggregation in platelet-rich plasma (IC50 4.9 mU/ml), but not in whole blood. When both ATPDase (5.6-58.7 mU/ml) and ATP (0.5-10 microM) were added to platelet-rich plasma, there was an immediate dose-dependent aggregation of platelets followed by a slowly developing disaggregation. These data show that ATPDase is present in both the intima and media layers of bovine aorta and suggest a dual role for this enzyme in platelet activation. By converting ATP released from damaged cells into ADP, the enzyme could facilitate platelet aggregation at the site of vascular injury, whereas the subsequent conversion of ADP to AMP could inhibit or reverse platelet aggregation. The consequence of these activities would be to control the growth of a platelet thrombus.     

Thrombosis Prevention by Acetylsalicylic Acid in Hyperlipemic Rats

In rats, administration of acetylsalicylic acid (ASA) by stomach tube two hours before blood removal, or addition of the drug to platelet-rich plasma in vitro, markedly inhibited platelet aggregation induced by thrombin, ADP and collagen. Addition of ASA in vitro to human platelet-rich plasma also inhibited platelet aggregation by thrombin, ADP and collagen. In hyperlipemic rats, ASA (100 to 200 mg./kg.), administered by stomach tube once or five times, markedly inhibited the production of thrombosis initiated by intravenous injection of S. typhosa endotoxin. In these experiments, thrombosis prevention by ASA was associated with both a decrease in platelet aggregation and an increase in the recalcification plasma clotting time.     

Characterization of liposomes carrying von Willebrand factor-binding domain of platelet glycoprotein Ibalpha: a potential substitute for platelet transfusion.

Platelet glycoprotein (GP) Ib/IX/V complex is a receptor for von Willebrand factor (vWf), which plays a crucial role in primary hemostasis by mediating platelet adhesion to injured blood vessels. We have expressed in CHO cells a fragment of GPIba that retained a vWf-binding function. The recombinant fragment (rGPIba) was incorporated into liposomes and evaluated their functions in vitro. rGPIba on the liposome surface was detectable by flow cytometric analysis. Addition of vWf and ristocetin caused specific agglutination of rGPIbalpha-liposomes, as evaluated by an aggregometer or a fluorescent microscopy. When ristocetin was added to platelet-rich plasma (PRP) pre-mixed with rhodamine-labeled rGPIbalpha-liposomes, platelets aggregated and rhodamine-fluorescence was strongly positive in the platelet thrombi, suggesting that heterologous aggregation (attachment of liposomes to platelets) occurred. Platelet aggregation in PRP at low platelet concentration (20-80 x 10(6)/ml) was enhanced by rGPIbalpha-liposomes in a dose-dependent manner. Thus, rGPIbalpha-liposomes may accumulate on vWf-exposed subendothelial tissues and enhance platelet function in vivo, supporting hemostasis in thrombocytopenic individuals.     

Modulation of platelet activation by native DNA.

Native DNA (dsDNA) was found to induce the aggregation of isolated human platelets and the release of platelet 5HT; this activation was inhibited by both theophylline and TYA, suggesting a role for cAMP and metabolic products formed from arachidonate. By contrast, nonaggregating amounts of dsDNA inhibited platelet activation induced by collagen or thrombin. This inhibition, which could be overcome by use of greater amounts of the stimulatory agents, was not associated with the loss of platelet viability. Activation of platelets by dsDNA was not observed in plasma or in isolated platelet systems to which small amounts of cell-free plasma were added. However, dsDNA maintained in plasma its ability to inhibit platelet aggregation induced by collagen and thrombin. RNA and single-stranded DNA failed to induce platelet aggregation or release of 5HT and to block the platelet activation stimulated by dsDNA. Further, dsDNA did not significantly inhibit platelet aggregation in platelet-rich plasma stimulated by ADP or epinephrine. These data implicate dsDNA as a selective and potentially important activator and modulator of platelet responsiveness.     

Antithrombotic effects of peroxynitrite: Inhibition and reversal of aggregation in human platelets

The inhibition of platelet aggregation by peroxynitrite, a reactive oxygen species derived from the interaction of nitric oxide (NO) and superoxide, was examined in platelet-rich plasma. In this report, we have used a preparation of peroxynitrite that was free of H₂0₂ and MnO₂. As such, peroxynitrite dose-dependently (50–200 μA) inhibited aggregation of human platelets stimulated by ADP (5 μM), collagen (0.5 μg), thrombin (0.5 UlmL) and U46619 (1 PM). In addition, peroxynitrite reversed platelet aggregation induced by collagen, ADP, and thrombin. Peroxynitrite, preincubated with platelet-poor plasma or albumin (7%) for 30 min, did not alter the inhibition of platelet aggregation. This suggested that the inhibitory action of peroxynitrite may be due to nitrosylation of proteins, which by themselves possess activity, rather than conversion to NO or NO donors. Furthermore, we show that peroxynitrite increased the cGMP level only at 200 μM concentrations, further suggesting that the action of peroxynitrite was not completely due to its conversion to NO or NO donors.     

Mechanisms involved in the antiplatelet activity of ketamine in human platelets

The aim of this study was to systematically examine the inhibitory mechanisms of ketamine in platelet aggregation. In this study, ketamine concentration-dependently (100–350 µM) inhibited platelet aggregation both in washed human platelet suspensions and platelet-rich plasma stimulated by agonists. Ketamine inhibited phosphoinositide breakdown and intracellular Ca²⁺ mobilization in human platelets stimulated by collagen. Ketamine (200 and 350 µM) significantly inhibited thromboxane (Tx) A₂ formation stimulated by collagen. Moreover, ketamine (200 and 350 µM) increased the fluorescence of platelet membranes tagged with diphenylhexatriene. Rapid phosphorylation of a platelet protein ofMr 47,000 (P47), a marker of protein kinase C activation, was triggered by phorbol-12,13-dibutyrate (100 nM). This phosphorylation was markedly inhibited by ketamine (350 µM). These results indicate that the antiplatelet activity of ketamine may be involved in the following pathways. Ketamine may change platelet membrane fluidity, with a resultant influence on activation of phospholipase C, and subsequent inhibition of phosphoinositide breakdown and phosphorylation of P47, thereby leading to inhibition of intracellular Ca²⁺ mobilization and TxA₂ formation, ultimately resulting in inhibition of platelet aggregation.     

Carbacyclin — A potent stable prost acyclin analogue for the inhibition of platelet aggregation

Carbacyclin is a chemically stable analogue of prostacyclin. As an inhibitor of platelet aggregation induced by ADP or collagen in vitro, carbacyclin is 0.03 times as active as prostacyclin in human, dog or rabbit plasma. Carbacyclin, like prostacyclin, reduces systemic arterial blood pressure (BP) in dogs, rabbits and rats and is not inactivated during passage through the pulmonary circulation. Further actions were investigated using a new ex vivo technique which allows rapid preparation of platelet-rich plasma and determination of platelet aggregation. In the dog, intravenous infusion of carbacyclin or prostacyclin inhibits platelet aggregation ex vivo with minimal effects on BP or heart rate. In the anaesthetised or conscious rabbit, carbacyclin and prostacyclin produces similar cardiovascular changes in doses producing an equivalent degree of platelet inhibition. In both rabbit and dog, carbacyclin is 0.1 times as active as prostacyclin in inhibiting ex vivo platelet aggregation. Platelet inhibition is maintained throughout the period of infusion of either compound (up to 3 h) yet is no longer apparent 10 min after terminating the infusion. Carbacyclin is thus a chemically-stable but metabolically-unstable analogue with a biological profile closely similar to prostacyclin.     

Ca2+ signaling in the transformation of promastigotes to axenic amastigotes of Leishmania donovani

Three acidic phospholipases A₂ from Indian cobra (Naja naja naja) venom inhibited platelet aggregation in platelet rich plasma induced separately by ADP, collagen and epinephrine with different potencies. The order of inhibition was epinephrine > collagen > ADP. They did not inhibit platelet aggregation induced by arachidonic acid (10 M). The inhibition was dependent on concentration of the protein and the time of incubation of the phospholipases A₂ with platelet rich plasma. Parabromophenacyl bromide modified PLA₂ enzymes lost their enzymatic activity as well as platelet aggregation inhibition activity suggesting the involvement of catalytic function in platelet aggregation inhibitory activity.     

The radioisotope labelling of thrombocytes using a monoclonal antibody against membrane glycoproteins IIb-IIIa and the measurement of thrombocyte adhesion/aggregation on the substrate surface]

A new method for platelet labeling based on binding of monoclonal antibody to human platelets has been suggested in this study. Monoclonal antibody VM16a against membrane glycoproteins IIb-IIIa was labeled by 125I and then incubated with platelets. About 70% of added antibody was bound when it was used at the concentrations corresponding to the linear part of the concentration curve (0.5 and 1.0 micrograms/ml). Due to high efficiency of binding 125I-VM16a-labeled platelets were used for the measurement of adhesion/aggregation to the substrate in platelet-rich plasma without washing of the free label. Experiments with washed platelets double labeled with 51Cr and 125I-VM 6a showed high correlation between the data obtained with both labels. The method of platelet labeling has been applied for the assessment of drug action on platelet adhesion/aggregation. Measurements were performed in platelet-rich plasma and adhesion/aggregation was stimulated by ADP and analogue of thromboxane A2, U46619. It was shown/that antianginal drug trapidil strongly inhibited and antiatherogenic drug probucol did not affect platelet adhesion/aggregation stimulated by both agonists.     

Effects of α,β-methylene-adenosine-5′-diphosphate on blood platelet aggregation

The effects on platelet aggregation of α,β-methylene-adenosine-5′-diphosphate (Ado-PCP) have been investigated. Using human citrated platelet-rich plasma it has been shown that: (i) at concentrations of 10^?3 M or higher Ado-PCP is able to induce platelet aggregation; (ii) the rate of Ado-PCP-induced aggregation increases on raising the pH of platelet-rich plasma above the pK_a for the secondary phosphonyl dissociation of Ado-PCP; (iii) at concentrations from 1 · 10^?4 to 5 · 10^?4 M Ado-PCP does not cause platelet aggregation itself, but it inhibits ADP-induced aggregation. This inhibition is also observed in washed platelet suspensions. The data suggest that Ado-PCP acts at the same site on the platelet membrane as does ADP and that ADP to AMP transformation is not a prerequisite for the process of aggregation. The observed effect of pH on the rate of Ado-PCP induced aggregation suggests that the ionization state of a nucleotide terminal acid group is important in the process of aggregation.     

Effect of prostaglandin E1 alone and in combination with theophylline or aspirin on collagen-induced platelet aggregation and on platelet nucleotides including adenosine 3′:5′-cyclic monophosphate

1. Human platelet nucleotides were labelled by incubating platelet-rich plasma with [U-(14)C]adenine. With such platelets, the effects of prostaglandin E1, theophylline and aspirin were determined on collagen-induced platelet aggregation and release of platelet ATP and ADP. Intracellular changes of platelet radioactive nucleotides, particularly 3':5'-cyclic AMP, were also determined both with and without collagen treatment. 2. Prostaglandin E1, theophylline and aspirin inhibited collagen-induced aggregation of platelets in a dose-dependent manner. Collagen-induced release of ATP and ADP and breakdown of radioactive ATP were also inhibited in a dose-dependent manner. 3. Prostaglandin E1 stimulated the formation of platelet radioactive 3':5'-cyclic AMP in a dose-dependent manner. With a given dose of prostaglandin E1, maximum formation of radioactive 3':5'-cyclic AMP occurred by 10-30s and thereafter the concentrations declined. The degree of inhibition of aggregation produced by prostaglandin E1, however, increased with its time of incubation in platelet-rich plasma before addition of collagen, so that there was an inverse relationship between the radioactive 3':5'-cyclic AMP concentration measured at the time of collagen addition and the subsequent degree of inhibition of aggregation obtained. 4. Neither theophylline nor aspirin at a concentration in platelet-rich plasma of 1.7mm altered platelet radioactive 3':5'-cyclic AMP contents. In the presence of prostaglandin E1, theophylline increased the concentration of radioactive 3':5'-cyclic AMP over that noted with prostaglandin E1 alone, but aspirin did not. 5. Mixtures of prostaglandin E1 and theophylline had a synergistic effect on inhibition of platelet aggregation. The same was true to a lesser extent with mixtures of prostaglandin E1 and aspirin. Such mixtures also inhibited collagen-induced release of platelet ATP and ADP and breakdown of platelet radioactive ATP. 6. Certain concentrations of either theophylline or aspirin and mixtures of small concentrations of prostaglandin E1 with either theophylline or aspirin caused little or no increase of radioactive 3':5'-cyclic AMP at the time of collagen addition, but inhibited aggregation to a marked degree, whereas higher concentrations of prostaglandin E1 alone caused a much greater increase of radioactive 3':5'-cyclic AMP at the time of collagen addition but inhibited aggregation to a lesser extent. With these compounds there does not appear to be a correlation between these parameters.     

Antiplatelet effects of clausine-D isolated from Clausena excavata

Clausine-D inhibited concentration-dependently the aggregation and release of washed rabbit platelets induced by arachidonic acid and collagen, without affecting those induced by U46619, PAF and thrombin. The IC₅₀ values of clausine-D on arachidonic acid-and collagen-induced platelet aggregation were calculated to be 9.0±1.1 and 58.9±0.9 μM, respectively. Thromboxane B₂ and prostaglandin D₂ formation in platelets caused by arachidonic acid were also suppressed. Clausine-D inhibited increased intracellular concentration of calcium in platelets caused by arachidonic acid and collagen, and also abolished the generation of inositol monophosphate caused by arachidonic acid, but not that by collagen U46619, PAF and thrombin. In human citrated platelet-rich plasma, clausine-D inhibited the secondary phase, but not the primary phase, of aggregation induced by epinephrine and ADP. These results indicate that the antiplatelet effect of clausine-D is due to inhibition of the formation of thromboxane A₂.     

Cross-reactive immunodeterminants on Streptococcus sanguis and collagen. Predicting a structural motif of platelet-interactive domains.

Cross-reactive immunodeterminants on a fibril-associated surface antigen of Streptococcus sanguis and types I and III collagen participate in the induction of aggregation of human platelets. To further understand the basis for this apparent molecular mimicry, antitype-specific collagen antibodies, anti-KPGEPGPK (an analogue of platelet-interactive domains on collagen) and a panel of KPGEPGPK-like synthetic peptides were used as probes. When collagen or S. sanguis cells were pretreated with the anti-collagen antisera, the induction of aggregation of platelet-rich plasma was greatly delayed or abrogated. These anti-collagen antibodies also neutralized KPGEPGPK and purified S. sanguis platelet-interactive antigens as inhibitors of S. sanguis or collagen-induced aggregation of platelets in plasma. In immunoblot analyses, these anti-collagen antibodies reacted with S. sanguis platelet-interactive antigens. Additionally, antisera against the platelet-interactive antigen of S. sanguis selectively reacted with undigested type I collagen and with fragments CB3 and CB6 of cyanogen bromide-treated type I collagen. Finally, when platelets were pretreated with synthetic peptides containing specific amino acid substitutions within the KPGEPGPK sequence, the time to onset of platelet-rich plasma aggregation by both agonists was altered. The hierarchical pattern of responses of platelets to these peptides and predictions of the structural changes produced by simulated insertions of each peptide into the CB4 sequence of type III collagen suggested conformational requirements for interactions with platelets. Thus, these data show that cross-reactive immunodeterminants of S. sanguis and collagen induce platelet aggregation. The platelet-interactive domains are predicted to be characterized by a structural motif with the consensus sequence X-P-G-E-P/Q-G-P-X.     

Platelet activating factor-induced aggregation of calf platelets: Apparent positive cooperativity in the kinetics and non competitive inhibition by diltiazem

Aggregation of calf platelets by platelet activating factor was characterized by a spectrophotometric method. The aggregation kinetics of both platelet-rich plasma and purified platelets showed concave up double-reciprocal plots and linear Hill plots withh > 1 (1.7 ± 02) consistent with positive cooperativity. Comparable values of maximum rates of aggregation(R) were obtained with platelet-rich plasma (0.25 ± 0.08) and purified platelets (0.28 ± 0.18) but the half-maximal saturation concentration (S_0.5) differed greatly between platelet-rich plasma (6 ± 3 nM) and purified platelets (0.28 ± 0.18 nM). An Arrhenius activation energy of 21 ±2 kcal/mol was found for aggregation of purified platelets. Diltiazem was inhibitory with half-maximal inhibitory concentration (I_0.5) of 4 M but the inhibition was not competitive. Diltiazem inhibited rates but not the extent of shape-change. The receptor-antagonist and sulphydryl reagent N-ethylmaleimide and the platelet antagonistic omega-3-fatty acid, 5,8,11,14,17-eicosa pentaenoic acid, inhibited both rates and extent of shape-change reactions and inhibited aggregation competitively (I_0.5 ∼ 5 M). Eicosa pentaenoic acid at > 25 M could abolish shape-change reactions and at 50 M served as an activator of platelets and the activation was enhanced by aspirin (1 mM). Although N-ethylmaleimide at > 20 M could also induce platelet activation it failed to induce aggregation and aspirin had no effect on the shape-change reactions induced by it.     

Mechanism of action of biogenic chloramines and hypochlorite on initial aggregation of blood platelets

The antiaggregant action of two reactive oxidants N,N-dichlorotaurine (chloramine of biogenic type) and sodium hypochlorite on the initial ADP-induced aggregation of rabbit blood platelets has been studied. Platelet aggregation in the reconstructed platelet-rich plasma (PRP) was measured by the nephelometric method, and the aggregation index was an increase in the intensity of small-angle light scattering. The introduction of chloramine at comparatively small concentrations (no greater than 1 mM active chlorine) directly into the reconstructed platelet-rich plasma induces the suppression of the initial aggregation (formation of small aggregates) several times stronger than in the case of its preliminary incubation with plasma alone. This suggests that N,N-dichlorotaurine exerts its antiaggeregant action on the platelet-rich plasma by direct interaction with cells. The effects of the inhibition of platelet aggregation in two variants of introduction of high concentrations of N,N-dichlorotaurine do not significantly differ. In this case a great amount of residual chloramine remains in the plasma, which just induces the suppression of platelet aggregation during subsequent reconstruction of the platelet-rich plasma. Similar data have been obtained in the study of the antiaggregant action of hypochlorite. N,N-Dichlorotaurine and hypochlorite at final concentrations of 0.2-0.3 and 0.15 mM, respectively, inhibit strongly the initial aggregation of isolated platelets (approximately 2 x 10(8) cells in 1 ml) preliminarily activated for 1.5 min by the addition of 100-500 nM ADP. However, the antiaggregants show a more profound suppression of aggregation of unstimulated platelets. The antiaggregant effects of N,N-dichlorotaurine and hypochlorite are probably due to the oxidative modification of sulfur-containing groups in platelet plasmatic membrane.     

Inhibition of human platelet aggregation and membrane lipid peroxidation by food spice, saffron

The inhibitory activity of saffron extract was studied on human platelets. Platelet aggregation and lipid peroxidation were evaluated with platelet rich plasma (PRP) and platelet membranes respectively obtained from blood of healthy human volunteers. Human platelets were subjected to stimulation with a variety of agonists like ADP (61 μM), epinephrine (76 μM), collagen (11 μg/ml), calcium ionophore A 23187 (6 μM) and ristocetin (1.25 μg/ml) in the presence and absence of saffron extract with IC₅₀ being 0.66, 0.35, 0.86 and 0.59 mg respectively and no inhibition with ristocetin. The inhibitory effect was dose dependent with concentrations varying between 0.16 to 0.80 mg and time dependent at IC₅₀. A significant decrease was observed in malondialdehyde (MDA) formed, one of the end products of arachidonic acid metabolism and of serotonin released from dense granules of platelets at respective IC₅₀. Lipid peroxidation in platelet membranes induced by iron-ascorbic acid system was inhibited by saffron extract significantly with IC₅₀ of 0.33 mg. Hence, it may be said that aqueous extract of saffron may have component(s), which protect platelets from aggregation and lipid peroxidation. (Mol Cell Biochem 278: 59–63, 2005)     

Interralation of prostaglandin endoperoxide (prostaglandin G2) and cyclic 3′,5′-adenosine monophosphate in human blood platelets

The prostaglandin endoperoxide, prostaglandin G₂, in platelet-rich plasma may produce reversible platelet aggregation without secretion, irreversible aggregation with secretion of platelet constituents inhibited by indomethacin, or the latter effects despite indomethacin, depending on the concentration of the endoperoxide. Irreversible aggregation and platelet secretion induced by prostaglandin G₂ apparently result from the action of ADP, since these responses are inhibited by 2-n-amylthio-5′-AMP (an inhibitor of the actions of ADP on platelets) and they do not occur in heparinized platelet-rich plasma. Prostaglandin G₂ lowers the platelet level of cyclic 3′,5′-AMP. Its actions are inhibited by elevation of cyclic AMP levels by prostaglandin E₁ or dibutyryl cyclic AMP or adenosine. Like malondialdehyde production induced by thrombin, ADP, or arachidonic acid, prostaglandin G₂-induced malondialdehyde production is reduced by dibutyryl cyclic AMP and prosraglandin E₁. Platelet activation by prostaglandin G₂ is enhanced by the adenylate cyclase inhibitor, 9-(tetrahydro-2-furyl)-adenine.The action of prostaglandin G₂ on platelets is more complex then previously reported.