部分蔬菜所含环氧化酶抑制物的抗血小板花生四烯酸代谢研究

为了研究部分蔬菜的环氧化酶抑制剂抗血小板花生四烯酸(arachidonic acid,AA)代谢的作用,将不同种类的蔬菜汁(以阿司匹林作为阳性对照)分别与正常人富血小板血浆(PRP)孵育,加入AA,观察各种蔬菜汁对血小板聚集的影响;血红素和环氧化酶-l(cyclooxygenase-I,COX1)或环氧化酶-2(cyclooxygenase-2,COX2)加入含有COX反应缓冲液的试管,漩涡混匀,与阿司匹林和各种蔬菜汁进行孵育,加入AA,然后利用盐酸终止反应,再加入氯化亚锡,通过酶免疫试剂盒测定COX抑制剂浓度;将不同种类的蔬菜汁(以阿司匹林作为阳性对照)分别与正常人全血进行孵育,加入AA进行反应,再加入消炎痛终止反应,离心,取上清,放射免疫法测定血浆血栓烷素B2(thromboxane B2,TXB2).结果表明,在AA诱导下,菠菜汁、蒜苔汁、蒜黄汁和韭菜汁与对照组相比对人血小板聚集的抑制显著,均在80％以上.4种蔬菜中均含有一定量的COX抑制物,其中菠菜的COX1和COX2抑制物浓度均高于阿司匹林;与生理盐水(对照组)比较,4种蔬菜汁均能显著降低AA诱导下人血浆TXB2的浓度(p＜0.05).结论:4种生蔬菜均含有COX抑制物,抑制了TXA2( thromboxane A2,TXA2)的产生,从而抑制了血小板聚集.因此,生菠菜、蒜黄、韭菜、蒜苔在体外具有显著抑制血小板聚集功能的作用,在抗血栓预防和治疗中可能有潜在的应用前景.     

Endogenous prostacyclin biosynthesis and platelet function during selective inhibition of thromboxane synthase in man.

The consequences of inhibiting the metabolism of prostaglandin G2 to thromboxane A2 in man were studied by using an inhibitor of thromboxane synthase, 4-[2-(IH-imidazol-1-yl)ethoxy] benzoic acid hydrochloride (dazoxiben). Single doses of 25, 50, 100, and 200 mg of dazoxiben were administered to healthy volunteers at 2-wk intervals in a randomized, placebo-controlled, double-blind manner. Serum thromboxane B2 and aggregation studies in whole blood and platelet-rich plasma were measured before dosing and at 1, 4, 6, 8, and 24 h after dosing. Both serum thromboxane B2 and the platelet aggregation response to arachidonic acid (1.33 mM) were reversibly inhibited in a dose-dependent manner. Aggregation induced by 1-O-alkyl-2-acetyl-sn-glycero-3-phosphocholine (0.4 and 4.0 microM) in platelet-rich plasma as well as both aggregation and nucleotide release induced by collagen (95 micrograms/ml) in platelet-rich plasma and whole blood were unaltered by dazoxiben. Additional evidence for a platelet-inhibitory effect of the compound was a significant prolongation of the bleeding time at 1 h after administration of the highest dose (200 mg) of dazoxiben. Endogenous prostacyclin biosynthesis was assessed by measurement of the major urinary metabolite of prostacyclin, 2,3-dinor-6-keto-PGF1 alpha (PGI-M). PGI-M excretion was increased by dazoxiben; it rose a mean 2.4-fold from predosing control values at 0-6 h after administration of the highest dose studied (200 mg).     

Effects of sulfinpyrazone and its metabolite G25671 on platelet activation and desensitization and on bronchoconstriction induced by the prostaglandin endoperoxide analog U46619

Sulfinpyrazone (100 microM) and its thioether metabolite G25671 (50 microM) suppressed arachidonic acid-induced platelet aggregation, thromboxane (Tx) B2 formation and ATP release. Platelet activation by the endoperoxide analog U46619 also was prevented by sulfinpyrazone or G25671 (0.3-1 mM). Previous studies have shown that human platelets pre-exposed to arachidonic acid or to U46619 and then washed and resuspended failed to respond to a second challenge by both arachidonic acid and U46619; desensitization by arachidonic acid and U46619 occurred at a site sensitive to endoperoxides/Tx receptor antagonists; and the desensitizing effects of U46619 were direct, whereas those of arachidonic acid were mediated by a cyclooxygenase-dependent metabolite. We now demonstrate that the presence of sulfinpyrazone or G25671 during platelet exposure to arachidonic acid or U46619 prevented desensitization. We also studied the threshold aggregating concentration of arachidonic acid and U46619 in healthy subjects before and after treatment with sulfinpyrazone and we found a good correlation between ex vivo and in vitro findings. We finally examined the actions of sulfinpyrazone and G25671 on the bronchoconstriction in vivo and parenchymal lung strip contraction in vitro induced by U46619. Neither drug had any preventive effect. Our results demonstrate that sulfinpyrazone and its metabolite G25671 are not only cyclooxygenase inhibitors but can also act as endoperoxide/Tx antagonists and indicate clearly that antagonism of U46619 by both drugs is selective for platelets.     

Metabolite cumulation during chronic propafenone dosing in arrhythmia

The cumulation of propafenone and two of its metabolites, 5-hydroxypropafenone (5-OHP) and N-depropylpropafenone (NDPP), was examined in patients with frequent ventricular ectopy. After 2 weeks of propafenone therapy (300 mg twice a day), propafenone was discontinued and blood samples were drawn for 24 hours. The mean (+/- SD) steady-state concentrations of propafenone, 5-OHP, and NDPP were 1010 +/- 411, 174 +/- 113, and 179 +/- 93 ng/ml. The concentration ratios of 5-OHP/propafenone and NDPP/propafenone were 0.177 +/- 0.049 and 0.227 +/- 0.203. Plasma concentrations of 5-OHP and NDPP did not decay in a log-linear manner during the sampling period and thus estimates of their disappearance t1/2s were not possible. At 24 hours after propafenone dosing, concentrations of 5-OHP and NDPP were 63% +/- 37% and 50% +/- 21% of their mean steady-state levels. Our data indicate that these propafenone metabolites cumulate in the plasma during chronic oral propafenone therapy, and that their clinical role needs to be elucidated.     

Etretinate kinetics during chronic dosing in severe psoriasis

Fourteen patients with various forms of psoriasis participated in a clinical study to characterize the pharmacokinetics of etretinate before, during, and after 6 months of therapy. A single 100 mg dose was initially given, followed 2 days later by approximately 170 days of multiple dosing with 25 mg one, two, three, or four times a day depending on the subject's response and tolerance. Blood samples were drawn for 48 hours after the initial dose, for 12 hours after dosing at monthly intervals, and for up to 8 months after administration of the last dose. Blood concentrations of etretinate were determined by a specific reverse-phase gradient elution HPLC assay. Blood concentrations after the first dose declined with an apparent t1/2 of approximately 7 hours, whereas those after the last dose declined with an apparent t1/2 of approximately 120 days. The lengthening of the t1/2 during chronic dosing appears to result from the cumulation of blood concentrations in the measurable range rather than from time-related alterations in drug kinetics. This is substantiated by the fact that etretinate blood concentration--time data for the entire course of therapy were fit by a nonlinear least-squares computer program designed to accommodate changes in the dosing regimen. A single polyexponential kinetic equation described the entire 6-month course of therapy as well as the 8-month washout without the need to invoke nonlinear kinetics. Although single-dose kinetic data for etretinate may not be good predictors of steady-state blood concentrations, etretinate appears to follow linear kinetics during these dosing regimens.     

Amplification and inhibition of platelet function by serum lipoproteins]

Low-density lipoprotein (LDL) at a concentration of 100 micrograms/mL, which is near the dissociation constant (Kd) of LDL-binding, had a maximal stimulatory effect on agonist-induced platelet aggregation. Anti-LDL receptor monoclonal antibody (C-7), like native LDL, induces a transient increase in intracellular Ca2+ and a shape change of human platelets. On the other hand, high-density lipoprotein (HDL) inhibited platelet function. ApoE-rich HDL, as well as, apoE.DMPC potently inhibited platelet aggregation in a dose-dependent manner. ApoE.DMPC stimulated the release of cholesterol into the supernatant, suggesting that apoE plays a major role in the inhibitory effect of apoE-rich HDL in platelet function, presumably due to the release of cholesterol from the plasma membrane.     

Plasmin inhibition of platelet function and of arachidonic acid metabolism

To study interactions between platelets and the fibrinolytic system, we examined the effects of human plasmin on human platelets washed by gel filtration. Plasmin concentrations that did not affect platelet shape change, release, or aggregation (less than 1.0 caseinolytic units [CU]/ml) caused a dose- and time-dependent inhibition of platelet aggregation in response to thrombin, ionophore A23187, and collagen. Complete loss of aggregation occurred at 0.1-0.5 CU/ml of plasmin. In a parallel dose-dependent manner, plasmin likewise inhibited thrombin, ionophore, and collagen-stimulated thromboxane B2 production. In contrast, neither aggregation nor thromboxane B2 formation induced by arachidonate was inhibited by plasmin pretreatment of the platelets. Plasmin blocked the thrombin-induced release of [3H]arachidonic acid from platelet membrane phospholipids and the thrombin-induced platelet oxygen burst. However, plasmin did not inhibit the arachidonate-induced oxygen burst. Inhibition of arachidonic acid release by plasmin was not mediated by increase in platelet cyclic AMP. These results suggest that plasmin inhibits platelet function, at least in part, by blocking the mobilization of arachidonic acid from membrane phospholipid pools. The effects of plasmin on platelets may contribute to the hemostatic abnormalities seen in pathologic and pharmacologic fibrinolysis.     

Endogenous biosynthesis of prostacyclin and thromboxane and platelet function during chronic administration of aspirin in man

To assess the pharmacologic effects of aspirin on endogenous prostacyclin and thromboxane biosynthesis, 2,3-dinor-6-keto PGF1 alpha (PGI-M) and 2,3-dinor-thromboxane B2 (Tx-M) were measured in urine by mass spectrometry during continuing administration of aspirin. To define the relationship of aspirin intake to endogenous prostacyclin biosynthesis, sequential urines were initially collected in individuals prior to, during, and subsequent to administration of aspirin. Despite inter- and intra-individual variations, PGI-M excretion was significantly reduced by aspirin. However, full mass spectral identification confirmed continuing prostacyclin biosynthesis during aspirin therapy. Recovery of prostacyclin biosynthesis was incomplete 5 d after drug administration was discontinued. To relate aspirin intake to indices of thromboxane biosynthesis and platelet function, volunteers received 20 mg aspirin daily followed by 2,600 mg aspirin daily, each dose for 7 d in sequential weeks. Increasing aspirin dosage inhibited Tx-M excretion from 70 to 98% of pretreatment control values; platelet TxB2 formation from 4.9 to 0.5% and further inhibited platelet function. An extended study was performed to relate aspirin intake to both thromboxane and prostacyclin generation over a wide range of doses. Aspirin, in the range of 20 to 325 mg/d, resulted in a dose-dependent decline in both Tx-M and PGI-M excretion. At doses of 325-2,600 mg/d Tx-M excretion ranged from 5 to 3% of control values while PGI-M remained at 37-23% of control. 3 d after the last dose of aspirin (2,600 mg/d) mean Tx-M excretion had returned to 85% of control, whereas mean PGI-M remained at 40% of predosing values. Although the platelet aggregation response (Tmax) to ADP ex vivo was inhibited during administration of the lower doses of aspirin the aggregation response returned to control values during the final two weeks of aspirin administration (1,300 and 2,600 mg aspirin/d) despite continued inhibition of thromboxane biosynthesis. These results suggest that although chronic administration of aspirin results in inhibition of endogenous thromboxane and prostacyclin biosynthesis over a wide dose range, inhibition of thromboxane biosynthesis is more selective at 20 than at 2,600 mg aspirin/d. However, despite this, inhibition of platelet function is not maximal at the lower aspirin dosage. Doses of aspirin in excess of 80 mg/d resulted in substantial inhibition of endogenous prostacyclin biosynthesis. Thus, it is unlikely that any dose of aspirin can maximally inhibit thromboxane generation without also reducing endogenous prostacyclin biosynthesis. These results also indicate that recovery of endogenous prostacyclin biosynthesis is delayed following aspirin administration and that the usual effects of aspirin on platelet function ex vivo may be obscured during chronic aspirin administration in man.     

The effect of different agitation modes on platelet metabolism, thromboxane formation, and alpha-granular release during platelet storage

Platelet concentrates (PCs), prepared by plateletpheresis, were stored in aliquots in polyvinylchloride blood bags for 5 days at 22 degrees C under rapid, slow, or no agitation. Nonagitated PCs were also stored in a 98-percent oxygen atmosphere. In nonagitated PCs, pO2, lactate production, and platelet factor 4 (PF 4) concentration increased, whereas the ATP level and pH dropped rapidly. These changes were somewhat minimized in nonagitated PCs stored in oxygen. There was no significant difference between the two agitated groups. The increase in PF 4 correlated inversely to the decrease in ATP: r = -0.91, p less than 0.001, n = 24. The formation of thromboxane B2 (TxB2) after stimulation with arachidonic acid or collagen was significantly higher in slowly agitated PCs on Day 5 than on Day 0 (p less than 0.01). Nonagitated PCs produced lower levels of TxB2 (collagen stimulation) on Day 5 (p less than 0.05). In unstimulated PCs, the levels of TxB2 and ATP were inversely correlated on Day 5 (r = -0.70, p less than 0.001, n = 20). In vivo survival was performed after 72 hours of storage; mean survival (+/- SD) was 6.5 (+/- 0.3) days for nonagitated oxygenated PCs and 6.8 (+/- 0.7) days for agitated PCs. In nonagitated PCs, anaerobic metabolism increased, although oxygen diffusion through the container wall was sufficient. Agitation seems to facilitate the diffusion of oxygen through the storage medium. Nonagitated PCs were stored safely for 24 hours; this period can be extended to at least 72 hours when aerobic metabolism is maintained.     

Potentiation of clopidogrel active metabolite formation by rifampicin leads to greater P2Y12 receptor blockade and inhibition of platelet aggregation after clopidogrel

Summary. Background: The thienopyridine P2Y₁₂ receptor antagonist clopidogrel reduces the risk of arterial thrombosis and individual pharmacodynamic responses to clopidogrel are believed to reflect the levels of active metabolite (AM) generated. Rifampicin increases the inhibitory effect of clopidogrel on platelet aggregation (PA). We studied the response to clopidogrel before and during administration of rifampicin in order to study the relationship between individual AM levels and P2Y₁₂ blockade. Methods: Healthy volunteers received a 600‐mg loading dose of clopidogrel followed by 75 mg daily for 7 days and, after a washout period and treatment with rifampicin [300 mg twice a day (b.i.d.)], received the same regimen of clopidogrel. Clopidogrel AM levels were determined over 4 h after the clopidogrel loading dose and unblocked P2Y₁₂ receptor number was assessed using a ³³P‐2MeSADP binding assay. PA was measured by optical aggregometry with ADP and TRAP. Results: Rifampicin enhanced clopidogrel AM production [area‐under‐the‐curve (AUC): clopidogrel 89 ± 22 ng h mL^?1, clopidogrel + rifampicin 335 ± 86 ng h mL^?1, P < 0.0001], and P2Y₁₂ blockade (unblocked receptors: clopidogrel 48 ± 24, clopidogrel + rifampicin 4 ± 2, P < 0.0001) and reduced PA (5 μmol L^?1 ADP: clopidogrel 20 ± 4, clopidogrel + rifampicin 5 ± 2, P < 0.01). Increasing numbers of unblocked receptors were required for an aggregation response with a decreasing concentration of ADP. PA induced by ADP 2 μmol L^?1 was particularly sensitive to low levels of receptor blockade. Conclusion: Potentiation of clopidogrel AM production by rifampicin leads to greater P2Y₁₂ blockade and consequently greater inhibition of PA. PA responses to low concentrations of ADP are more sensitive to P2Y₁₂ blockade.     

Differences in platelet growth factor release and leucocyte kinetics during autologous platelet gel formation

Three commercial systems for whole blood separation were compared to obtain the buffy coat composed of platelet-rich plasma (BC-PRP) and leucocytes . These samples of the buffy coat were used to make a platelet gel (PG), which was used to measure platelet growth factor (PGF) release, to perform a white blood cell (WBC) count and to measure myeloperoxidase (MPO) release from WBCs. Aliquots of whole blood obtained from ten volunteers were distributed either to a blood cell separator (The Electa Cell-Separator, E-CS) or to a tabletop centrifuge (Gravitational Platelet Sequestration System, GPS) to prepare the BC-PRP. The third system combines the BC-PRP production by E-CS with a micro porous filter (Autologous Growth Factor filter, AGF) to enrich for the BC-PRP. Autologous thrombin was used to activate the BC-PRP and to prepare the PG and subsequently to degranulate the platelet concentrate. Platelet-derived growth factor-AB and transforming growth factor-beta1 were present in high levels after thrombin activation of the E-CS or GPS prepared samples. However, the AGF prepared samples released their growth factors before thrombin activation. The WBCs were significantly increased with each of the three systems. Contrary to the AGF, no leucocyte degranulation occurred with the E-CS or GPS prepared samples, based upon the low MPO concentrations in the BC-PRP. The three types of apparatus had different harvesting capacities for collecting the enriched platelets and the release of high concentrations of PGF. When the E-CS and GPS, but not the AGF, were used, low levels of MPO were maintained in the PG, which potentially contributes to antimicrobial properties of platelet gel at the site of application.     

Plasma brain natriuretic peptide,platelet parameters,and cardiopulmonary function in chronic obstructive pulmonary disease

BACKGROUNDChronic obstructive pulmonary disease (COPD) is a chronic respiratory disease with worldwide occurrence and high disability and mortality rate. It occurs mostly in the elderly population with pulmonary heart disease, type II respiratory failure, and other serious complications.AIMTo investigate the correlation of plasma brain natriuretic peptide (BNP) and platelet parameters with cardiac function and pulmonary hypertension in patients with COPD and pulmonary heart disease. METHODSFrom June 2016 to June 2019, 52 patients with COPD-pulmonary heart disease (pulmonary heart disease group), 30 patients with COPD (COPD group), and 30 healthy individuals (control group) in our hospital were enrolled in the study. The pulmonary heart disease group was further divided into subgroups according to cardiac function classification and pulmonary artery pressure. Plasma BNP and platelet parameters were estimated and compared among each group and subgroup. The correlation of plasma BNP and platelet parameters with cardiac function classification and pulmonary artery pressure was then analyzed.RESULTSIn the pulmonary heart disease group, the COPD group, and the control group, the levels of plasma BNP, platelet distribution width (PDW), and mean platelet volume (MPV) showed a decreasing trend (P < 0.05), while an increasing trend was found in platelet count (PLT) and plateletcrit (PCT) levels among the three groups (P < 0.05). In the pulmonary hypertension mild, moderate, and severe subgroups, the levels of plasma BNP, PDW, and MPV showed an increasing trend (P < 0.05), while a decreasing trend was observed in PLT levels (P < 0.05); however, PCT levels showed no significant difference among the three subgroups (P > 0.05). In the cardiac function grade I, II, III, and IV subgroups, the levels of plasma BNP, PDW, and MPV showed an increasing trend (P < 0.05), while a decreasing trend was noted in PLT and PCT levels among the four subgroups (P < 0.05). Correlation analysis showed that the levels of plasma BNP, PDW, and MPV in patients with pulmonary heart disease were positively correlated with their pulmonary artery pressure (P < 0.05), while PLT was negatively correlated with their pulmonary artery pressure (P < 0.05). Moreover, plasma BNP, PDW, and MPV levels were positively correlated with cardiac function grade (P < 0.05) of these patients, while PLT and PCT levels were negatively correlated with their cardiac function grade (P < 0.05).CONCLUSIONPlasma BNP and PLT parameters are significantly correlated with the cardiac function and pulmonary hypertension in patients with COPD and pulmonary heart disease, indicating that these parameters have high clinical relevance in reflecting the health condition of these patients and for guiding their treatment.     

Stereoselective increase in propranolol bioavailability during chronic dosing in the dog

The disposition of (+)- and (-)-propranolol was determined after chronic as compared to single oral doses of racemic drug. Single oral doses (80 mg) of a stable isotope-labeled pseudoracemate were given to six dogs before and after chronic pretreatment with unlabeled propranolol. The bioavailability of (-)-propranolol (5.7 +/- 1.6%; mean +/- S.E.) was considerably lower (P less than .01) than that of (+)-propranolol (16.1 +/- 5.9%) after single doses. Chronic pretreatment led to a 167% increase in the bioavailability of (-)-propranolol to 15.2 +/- 3.7% (P less than .01), with only a 47% increase in (+)-propranolol to 23.7 +/- 4.5% (N.S.). Chronic pretreatment had no effect on the kinetics of i.v. doses of tritium-labeled racemic drug administered simultaneously or on blood binding. This stereoselective increase in the bioavailability of (-)-propranolol was associated with an unexpected 62% increase in the glucuronidation of this enantiomer (P less than .01) with no effect on the glucuronidation of (+)-propranolol. There was, however, a change in the stereochemical composition of 4'-hydroxypropranolol from single doses, (-)/(+)-enantiomer ratio 1.37 +/- 0.14, to chronic doses, 1.23 +/- 0.13 (P less than 0.05), suggesting stereoselective inhibition of ring-oxidation of (-)-propranolol. This study demonstrates preferential presystemic hepatic removal of (-)-propranolol in the dog by a process, probably ring-oxidation, that becomes partially inhibited after chronic doses, leading to a stereoselective increase in the bioavailability of this enantiomer.     

Prostaglandin formation and platelet aggregation during fasting and linoleic acid intake

Prostaglandin formation, estimated by the determination of tetranorprostanedioic acid (TNPDA) in the urine, and platelet aggregation were investigated in seven healthy volunteers each day during fasting, and in three of them additionally during intake of carbohydrates (328kcal/day) or safflor oil (328 kcal, 20 g linoleic acid). Monitoring TNPDA in 8-h fractions of the urine showed a reduction during the night (23.00-07.00) by 70% on the average. During Days 1 and 2 of fasting the amount of TNPDA in 24-h urine was the same as under a conventional diet. On Day 3, TNPDA decreased in all experimental subjects to 162 micrograms/day on the average and was not changed by carbohydrate intake. A linoleic acid intake of 20 g/day increased TNPDA in 24-h urine to pre-experimental levels measured under free diet. Platelet aggregation did not change during the experiment. No relationship between prostaglandin formation and lipolysis in man was found.     

Glutathione peroxidase potentiates the inhibition of platelet function by S-nitrosothiols.

GSH peroxidase (Px) catalyzes the reduction of lipid hydroperoxides (LOOH), known metabolic products of platelets and vascular cells. Because interactions between these cells are modulated by nitric oxide (NO) and LOOH inactivate NO, we investigated the effect of GSH-Px on the inhibition of platelet function by the naturally occurring S-nitrosothiol, S-nitroso-glutathione (SNO-Glu). Concentrations of SNO-Glu that alone did not inhibit platelet function (subthreshold inhibitory concentrations) were added to platelet-rich plasma together with GSH-Px (0.2-20 U/ml); this led to a dose-dependent inhibition of platelet aggregation with an IC50 of 0.6 U/ml GSH-Px. In the presence of subthreshold inhibitory concentrations of SNO-Glu, the LOOH, 5-hydroperoxy-6,8,11,14-eicosatetraenoic acid, increased platelet aggregation, an effect reversed by GSH-Px. Glutathione and SNO-Glu were equally effective as cosubstrates for GSH-Px. Incubation of SNO-Glu with GSH-Px for 1 min led to a 48.5% decrease in the concentration of SNO-Glu. Incubation of SNO-Glu with serum albumin led to the formation of S-nitroso-albumin, an effect enhanced by GSH-Px. These observations suggest that GSH-Px has two functions: reduction of LOOH, thereby preventing inactivation of NO, and metabolism of SNO-Glu, thereby liberating NO and/or supporting further transnitrosation reactions.     

Cyclooxygenase 2 pathway and its therapeutic inhibition in superantigen-induced toxic shock

Bacterial superantigens are a family of exotoxins that are the most potent T-cell activators known. Because of their ability to induce strong immune activation, superantigens have been implicated in a variety of diseases ranging from self-limiting food poisoning to more severe toxic shock syndrome (TSS) and have the potential to be used as agents of bioterrorism. Nonetheless, the precise molecular mechanisms by which T-cell activation by superantigens lead to acute systemic inflammatory response, multiple organ dysfunction, and ultimately death are unclear. Inadequate understanding of the pathogenesis has resulted in lack of development of effective therapy for superantigen-induced TSS. To fill these deficiencies, we systematically dissected the molecular pathogenesis of superantigen-induced TSS using the humanized human leukocyte antigen-DR3 transgenic mouse model by microarray-based gene expression profiling. Splenic expression of prostaglandin-endoperoxide synthase 2 (PTGS-2; also called cyclooxygenase 2 or COX-2) gene was increased by several hundred folds shortly after systemic superantigen (staphylococcal enterotoxin B [SEB]) exposure. In addition, expressions of several genes associated with eicosanoid pathway were significantly modulated by SEB, as analyzed by dedicated software. Given the importance of the COX-2 pathway in inflammation, we examined whether therapeutic inhibition of COX-2 by a highly selective inhibitor, CAY10404, could be beneficial. Our studies showed that i.p. administration of CAY10404 (50 mg/kg) immediately after challenge with 10 microg of SEB was unable to inhibit SEB-induced in vivo cytokine/chemokine production or T-cell activation/proliferation and did not prevent superantigen-associated thymocyte apoptosis.     

Periods without agitation diminish platelet mitochondrial function during storage

BACKGROUND: Prolonged periods without agitation produce platelet (PLT) storage lesions that result in reduced in vitro assay parameters and an increase of apoptotic markers during storage. The aim of this study was to evaluate the influence of periods without agitation on PLT mitochondrial function, blood gases, and activation. STUDY DESIGN AND METHODS: Apheresis PLT units (n = 12) were collected using a cell separator and each was equally divided among five storage bags (50 mL of PLT suspension in 300‐mL nominal volume containers). Four bags were held without agitation for 24, 48, 72, and 96 hours in a standard shipping box at room temperature and the fifth bag was continuously agitated. PLTs were assayed for standard in vitro PLT assays as well as for mitochondrial membrane potential (MMP), accumulation of reactive oxygen species, Annexin V binding, mitochondrial mass, and activity of mitochondrial reduction power (MRP) immediately after removal of units from the shipping container on Days 1, 2, 3, 4, and 7. RESULTS: Increasing periods without agitation resulted in increased superoxide anion generation and PLT activation as well as reduced PLT MMP and MRP. Increasing periods without agitation resulted in increasing Annexin V binding. PLTs that had undergone periods without agitation showed increased oxygen and carbon dioxide levels immediately after storage without agitation. The superoxide anion generation was highly correlated with the loss of MMP, increasing Annexin V binding, and pH decline. CONCLUSIONS: PLTs, if stored without agitation, produce a lesion that leads PLTs to apoptosis. The severity of the lesion depends on the length of the period without agitation. Prolonged periods without agitation induce formation of superoxides and depolarization of MMP along with a presentation of apoptotic markers.     

Heparin inhibition of von Willebrand factor-dependent platelet function in vitro and in vivo.

The intravenous administration of heparin to patients before open heart surgery reduced ristocetin cofactor activity by 58% (P less than 0.01, t test), and this impairment of von Willebrand factor-dependent platelet function was closely related to plasma heparin levels (r2 = 0.9), but not to plasma von Willebrand factor (vWF) levels. We hypothesized that heparin may inhibit vWF-dependent platelet hemostatic functions by directly binding vWF in solution and interfering with vWF-GpIb binding. Using the in vitro techniques of ristocetin-induced platelet agglutination, fluorescent flow cytometric measurement of vWF-platelet binding, and conventional radioligand binding assays we observed that heparin inhibited both vWF-dependent platelet function and vWF-platelet binding in a parallel and dose-dependent manner. Heparin also inhibited platelet agglutination induced by bovine vWF and inhibited the binding of human asialo-vWF to platelets in ristocetin-free systems. The inhibitory potency of heparin was not dependent upon its affinity for antithrombin III, but was molecular weight dependent: homogeneous preparations of lower molecular weight were less inhibitory. Heparin impairment of vWF function may explain why some hemorrhagic complications of heparin therapy are not predictable based on techniques for monitoring the conventional anticoagulant effects of heparin.