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Meeting Abstracts  |   December 1996
Sevoflurane Inhibits Human Platelet Aggregation and Thromboxane A2Formation, Possibly by Suppression of Cyclooxygenase Activity
Author Notes
  • (Hirakata) Staff-Anesthesiologist, Kitano Hospital.
  • (Ushikubi) Associate Professor of Pharmacology, Kyoto University Faculty of Medicine.
  • (Toda) Staff-Anesthesiologist, Kyoto University Hospital.
  • (Nakamura) Associate Professor of Anesthesia, Kyoto University Hospital.
  • (Sai) Clinical Fellow, Kitano Hospital.
  • (Urabe) Chief-Anesthesiologist, Kitano Hospital.
  • (Hatano) Professor and Chairman of Anesthesiology, Wakayama Medical College, Wakayama, Japan.
  • (Narumiya) Professor and Chairman of Pharmacology, Kyoto University Hospital.
  • (Mori) Professor and Chairman of Anesthesia, Kyoto University Faculty of Medicine.
  • Received from the Department of Anesthesia, Kitano Hospital, Tazuke Kofukai Foundation Medical Research Institute, Osaka, and the Departments of Anesthesia and Pharmacology, Kyoto University, Faculty of Medicine, Kyoto, Japan. Submitted for publication January 29, 1996. Accepted for publication August 12, 1996. Presented, in part, at the annual meeting of the American Society of Anesthesiologists, Atlanta, Georgia, October 21-25, 1995. Supported in part by a grant-in-aid from the Fujiwara Medical Research Foundation.
  • Address reprint requests to Dr. Hirakata: Department of Anesthesia, Kitano Hospital, Kamiyama-cho 13-3, Kita-ku, Osaka 530, Japan.
Article Information
Meeting Abstracts   |   December 1996
Sevoflurane Inhibits Human Platelet Aggregation and Thromboxane A2Formation, Possibly by Suppression of Cyclooxygenase Activity
Anesthesiology 12 1996, Vol.85, 1447-1453.. doi:
Anesthesiology 12 1996, Vol.85, 1447-1453.. doi:
Key words: Anesthetic, volatile: sevoflurane; halothane; isoflurane. Eicosanoids: thromboxane A2; prostaglandin G2; arachidonic acid. Blood: platelets, aggregation.
Anesthesia with halothane increases bleeding time [1,2] and inhibits platelet aggregation in vivo [3,4] and in vitro. Studies in vitro found that halothane, which shows stronger antiaggregatory effects than do enflurane and isoflurane, inhibits adenosine diphosphate (ADP)- and epinephrine-induced secondary aggregation without altering primary aggregation significantly. [5-8] Because secondary aggregation is caused primarily by thromboxane A2(TXA2) secreted by stimulated platelets, we examined the effect of halothane on platelet TXA2receptors and found that it had a strong suppressive effect on the binding affinity of TXA2for its receptors. [9] 
The present study, which compared the effects of volatile anesthetics on platelet aggregation, showed that sevoflurane has strong antiaggregatory effects, even at subanesthetic concentrations, and halothane exerts such effects only at anesthetic concentrations, whereas isoflurane does not exert antiaggregatory effect in the range of clinical concentrations. To identify the mechanism(s) responsible, the effects of sevoflurane on platelet aggregation induced by a TXA2analog and the TXA2precursors arachidonic acid (AA) and prostaglandin G2(PGG sub 2) were examined, and a radioligand-binding assay of platelet TXA2receptors and a radioimmunoassay of the TXB2levels of stimulated platelets were performed.
Materials and Methods
In accordance with the human research standards of our institutional ethics committees, venous blood was obtained from six healthy volunteers (who, for at least 2 weeks, took no drugs known to affect platelet aggregation) and placed in tubes containing a 10% volume of 3.8% wt/vol trisodium citrate. The blood was centrifuged at 160g for 10 min to prepare platelet-rich plasma (PRP) or at 1,600g for 30 min to prepare platelet-poor plasma (PPP). The platelet count of the PRP was adjusted to 300,000/mm3by adding PPP, and then PRP and PPP were stored at room temperature. To prepare washed platelets, a 10% volume of 100 mM EDTA (pH 7.4) was added to PRP and the mixture was centrifuged at 900g for 15 min. The platelet pellet was suspended in buffer A (composed of 8 mM Na2HPO4, 2 mM NaH2PO4, 10 mM EDTA, 5 mM KCl, and 135 mM NaCl [pH 7.2]) and recentrifuged at 900g for 15 min. The platelet pellet was finally suspended in buffer B (composed of 25 mM Tris-HCl, 1 mM EGTA, 5 mM MgCl2, and 138 mM NaCl [pH 7.5]), and the platelet count was adjusted to 1,000,000/mm3by adding buffer B for the binding assay. Washed platelets were stored in Calcium2+ -free buffer at 0 degree Celsius for 1-3 h until a few minutes before being used. Platelet-rich plasma was used for the aggregation study and radioimmunoassay, and washed platelets were used for the binding assay.
Aggregation Study
A 200-micro liter aliquot of PRP was placed into a siliconized glass tube, warmed to 37 degrees Celsius for a few minutes before analysis, and stirred continuously before and during the experiments. An aliquot of halothane (0.16, 0.49, 0.98, and 1.25 mM), sevoflurane (0.13, 0.26, 0.65, 0.91, and 1.3 mM) and isoflurane (0.28, 0.56, 0.84, 1.12, and 1.4 mM) were added directly to the PRP-containing tubes, the tops of which were immediately sealed tightly with parafilm to minimize evaporation of the anesthetics, and incubated at 37 degrees Celsius for 10 min. To test the reversibility of the effect of sevoflurane, three tubes of platelet suspension with sevoflurane (0.26 mM) were sealed and incubated for 10 min, then unsealed and incubated for another 45 min before inducing platelet aggregation. Platelet aggregation induced by adding 1 micro Meter (+)-9,11-epithia-11,12-methano-TXA2(STA2), 1 mM AA, 15 micro Meter PGG2, 1-10 micro Meter ADP, and 1-20 micro Meter epinephrine was measured at 37 degrees Celsius by recording the increase in light transmission using an eight-channel aggregometer (MCM Hematracer VI; MC Medical, Tokyo, Japan) (n = 3 each). The light transmission of untreated PPP was taken as 100%.
Binding Assay
Each anesthetic was added directly to test tubes containing 100 micro liter washed platelets and 700 micro liter buffer B, and each tube was sealed immediately. After incubation for 10 min at 37 degrees Celsius, [sup 3 Hydrogen]-labeled TXA2, receptor antagonist (5Z-7-(3-endo-([ring-4-sup 3 Hydrogen] phenyl) sulphonylamino-[2.2.1.] bicyclohept-2-exo-yl) heptenoic acid, [sup 3 H]S145) (5 nM) was added and incubation at 37 degrees Celsius was continued for 30 min. The reaction was terminated by adding 5 ml of 5 mM Tris-HCl buffer (pH 7.4) which had been precooled to 0 degree Celsius. Each mixture was then filtered in vacuo through a Whatman GF/C filter, which was washed three times with 5 ml precooled Tris-HCl buffer, and the radioactivity on the filter (n = 3 for each agent) was determined by a liquid scintillation analyzer (Tri-Carb 1900 CA; Packard Instruments, Meriden, CT). For Scatchard analysis, the samples were incubated with various concentrations (1.25-20 nM) of [sup 3 H]S145 in the absence and presence of halothane (3.3 mM) or sevoflurane (3 mM).
Radioimmunoassay of Thromboxane B sub 2
Platelet aggregation was induced by epinephrine, ADP or AA, in the presence or absence of an inhalational anesthetic. Seven minutes after adding an aggregating agent, the reaction was terminated by adding one-tenth volume of 100 mM EDTA precooled to 0 degree Celsius, and the suspension was immediately placed in an ice bath. The suspension was centrifuged at 10,000g at 4 degrees Celsius for 2 min to prepare platelet-free plasma, which was stored at -20 degrees Celsius until levels of TXB2were determined. The levels of TXB2, a stable metabolite of TXA2, in platelet-free plasma were determined using a commercially available radioimmunoassay kit.
The drugs used were halothane (Takeda Pharmaceutical, Osaka, Japan), sevoflurane (Maruishi Pharmaceutical, Osaka, Japan), isoflurane (Dainabot, Osaka, Japan), epinephrine hydrochloride (Sigma Chemical, St. Louis, MO), ADP (Sigma Chemical), arachidonic acid (Nacalai Tesque, Kyoto, Japan), and prostaglandin G2(Cayman Chemical, Ann Arbor, MI). [sup 3 H]S145 was a gift from Shionogi Research Laboratories (Osaka, Japan), and STA2was a gift from Ono Pharmaceuticals (Osaka, Japan). GF/C filters were obtained from Whatman International (Maidstone, UK), and the radioimmunoassay kit used was a thromboxane B2[sup 3 Hydrogen] assay system, code TRK 780 (Amersham International, Buckinghamshire, UK).
The inhalational anesthetics were diluted with ethanol when necessary and the aliquot was added directly to test tubes. The final concentrations of ethanol in the reaction mixtures were less than 0.5% vol/vol, which does not affect platelet aggregation. [10,11] The concentrations of the volatile anesthetics in the liquid phase in each test tube were confirmed by gas chromatography (model 5890A; Hewlett-Packard, Palo Alto, CA). In a preliminary study, the concentrations of volatile anesthetics in platelet suspension in parafilm-sealed tubes were not significantly altered by 30 min of incubation at 37 degrees Celsius.
The data are expressed as means +/- SD and were analyzed by one-way analysis of variance and the Scheffe's test. Differences at P <0.05 were considered significant.
Results
Epinephrine (1-20 micro Meter) and ADP (1-10 micro Meter) induced primary aggregation, which was followed by secondary aggregation (Figure 1(A)). Pretreatment with sevoflurane (0.13-0.91 mM) and halothane (0.16-1.25 mM) did not significantly alter the primary aggregation induced by these agonists. However, the secondary aggregation induced by epinephrine (1-10 micro Meter) and ADP (1-10 micro Meter) were suppressed by sevoflurane (0.13-1.3 mM) and halothane (0.49-1.25 mM), but not by halothane (0.16 mM) and isoflurane (0.28-0.84 mM) (Figure 1(A) and Table 1). The secondary aggregation induced by a high concentration (20 micro Meter) of epinephrine was suppressed only by higher concentrations of sevoflurane (0.26-0.91 mM) and halothane (0.98-1.25 mM). Sevoflurane and isoflurane at higher concentrations (> 1 mM) suppressed platelet aggregation nonspecifically. Aggregation was not inhibited in the tubes to which sevoflurane (0.26 mM) was added and 10 min later were unsealed and incubated for 45 min more (n = 3), indicating that the effects of sevoflurane were reversible.
Figure 1. (A; top left and right) Typical recordings of epinephrine (3 micro Meter)- and adenosine diphosphate (ADP; 1 micro Meter)-induced platelet aggregation in the absence (control) and presence of sevoflurane (0.13 mM). (B) Typical recordings of STA2(1 micro Meter)-induced platelet aggregation in the absence (control) and presence of sevoflurane (0.26 mM) and halothane (0.49 mM).
Figure 1. (A; top left and right) Typical recordings of epinephrine (3 micro Meter)- and adenosine diphosphate (ADP; 1 micro Meter)-induced platelet aggregation in the absence (control) and presence of sevoflurane (0.13 mM). (B) Typical recordings of STA2(1 micro Meter)-induced platelet aggregation in the absence (control) and presence of sevoflurane (0.26 mM) and halothane (0.49 mM).
Figure 1. (A; top left and right) Typical recordings of epinephrine (3 micro Meter)- and adenosine diphosphate (ADP; 1 micro Meter)-induced platelet aggregation in the absence (control) and presence of sevoflurane (0.13 mM). (B) Typical recordings of STA2(1 micro Meter)-induced platelet aggregation in the absence (control) and presence of sevoflurane (0.26 mM) and halothane (0.49 mM).
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Table 1. The Concentrations of Drugs that Suppressed Aggregation Induced by Each Agonist
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Table 1. The Concentrations of Drugs that Suppressed Aggregation Induced by Each Agonist
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Sevoflurane (0.13 mM) completely inhibited platelet aggregation induced by AA (1 mM), whereas concentrations as much as 0.26 mM did not affect that induced by PGG2(15 micro Meter) or STA2(1 micro Meter) (Figure 1(B), Table 1and Table 2), and halothane (0.49 mM) inhibited both AA- and STA2-induced aggregation (Figure 1(B) and Figure 2(A)).
Table 2. The Thromboxane B2Levels of Platelets, Stimulated with Arachidonic Acid (AA, 1 mM) in the Absence and Presence of Anesthetic
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Table 2. The Thromboxane B2Levels of Platelets, Stimulated with Arachidonic Acid (AA, 1 mM) in the Absence and Presence of Anesthetic
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Figure 2. (A) Typical recordings of arachidonic acid (1 mM)-induced platelet aggregation in the absence (control) and presence of sevoflurane (0.13 mM) and halothane (0.49 mM). (B) Typical recordings of prostaglandin G2(15 micro Meter)-induced platelet aggregation in the absence (control) and presence of sevoflurane (0.26 mM).
Figure 2. (A) Typical recordings of arachidonic acid (1 mM)-induced platelet aggregation in the absence (control) and presence of sevoflurane (0.13 mM) and halothane (0.49 mM). (B) Typical recordings of prostaglandin G2(15 micro Meter)-induced platelet aggregation in the absence (control) and presence of sevoflurane (0.26 mM).
Figure 2. (A) Typical recordings of arachidonic acid (1 mM)-induced platelet aggregation in the absence (control) and presence of sevoflurane (0.13 mM) and halothane (0.49 mM). (B) Typical recordings of prostaglandin G2(15 micro Meter)-induced platelet aggregation in the absence (control) and presence of sevoflurane (0.26 mM).
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The effect of indomethacin, a known cyclooxygenase inhibitor, was examined for comparison. Indomethacin (1 micro Meter) suppressed AA (1 mM)-induced platelet aggregation and platelet secondary aggregation induced by ADP and epinephrine without altering primary one and did not affect PGG2(15 micro Meter)- and STA2(1 micro Meter)-induced platelet aggregation. Table 1summarizes the aggregation study results.
Sevoflurane (3 mM) and isoflurane (2.5 mM) had minimal effects on [sup 3 H]S145 binding to platelets, whereas halothane (3.3 mM) suppressed it strongly. Scatchard analysis of [sup 3 H]S145 binding showed that sevoflurane affected neither the Bmaxnor Kd values, whereas Kd was increased markedly by halothane (3.3 mM) without significantly altering Bmax(Figure 3).
Figure 3. Scatchard analysis of [sup 3 H]S145 binding to washed platelets. B = bound; F = free.
Figure 3. Scatchard analysis of [sup 3 H]S145 binding to washed platelets. B = bound; F = free.
Figure 3. Scatchard analysis of [sup 3 H]S145 binding to washed platelets. B = bound; F = free.
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The TXB2level in the PRP supernatant was increased markedly by stimulation with AA (1 mM) from 102 +/- 49 pg/107platelets in basal level to 19,093 +/- 3,838 pg/107platelets (n = 5 each), and this increase was suppressed significantly by sevoflurane (0.26 mM) and halothane (0.98 mM), whereas isoflurane (0.56 mM) did not affect the TXB2level significantly (Table 2). Thromboxane B2levels in supernatant of PRP stimulated by AA under the presence of sevoflurane, halothane, and isoflurane were 4,354 +/- 2,081 pg/107platelets, 3,459 +/- 2,516 pg/107platelets, and 22,697 +/- 11,278 pg/107platelets, respectively.
Discussion
The binding of weak agonists, such as ADP and epinephrine, to platelets activates phospholipase A2to release AA, which is then converted to PGG2and finally to TXA2[12] (Figure 4), which plays an important role in the induction of secondary aggregation. Therefore the finding that sevoflurane and halothane inhibited secondary aggregation alone (Table 1) suggests that they suppressed the formation or function (or both) of TXA2. A receptor-binding assay using an isotope-labeled specific TXA2antagonist, [sup 3 H]S145, revealed that sevoflurane did not alter the binding affinity, [13,14] whereas halothane suppressed it significantly. These results indicate that inhibition of platelet aggregation by sevoflurane was not due to reduction of the ligand-binding affinity for platelet TXA2receptors. Furthermore, the fact that sevoflurane lacks the ability to affect platelet aggregation induced by STA2strongly indicates that sevoflurane does not affect the cascade after TXA2receptor activation to induce secondary platelet aggregation.
Figure 4. Thromboxane A2synthetic pathway.
Figure 4. Thromboxane A2synthetic pathway.
Figure 4. Thromboxane A2synthetic pathway.
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In this study, the level of TXB2, a stable breakdown product of TXA2, was subjected to radioimmunoassay to obtain estimated TXA2levels. In the absence of anesthetics, the TXB2level did not differ much from those reported previously. [15,16] The TXB2radioimmunoassay results of this study confirmed that sevoflurane and halothane, but not isoflurane, suppressed TXA2formation by platelets. Furthermore, the finding that sevoflurane inhibited AA-induced platelet aggregation but not that induced by PGG2or STA2(Table 1) suggests strongly that sevoflurane suppressed the conversion of AA to PGG2catalyzed by cyclooxygenase. We also confirmed that indomethacin, a known cyclooxygenase inhibitor, showed similar effect on platelet aggregation with sevoflurane. In contrast to sevoflurane, halothane suppressed both platelet TXA2receptor-binding affinity and TXA2synthesis, suggesting that the antiaggregatory effect of halothane is due to the reduction of platelet TXA2receptor-binding affinity, [9] the reduction of TXA2formation, or both.
The minimum alveolar concentration values of halothane, sevoflurane, and isoflurane, which were 0.75, 2, and 1.2 vol/%, respectively, correspond to 0.68, 0.49, and 0.66 mM. [17] Therefore the minimum concentrations of sevoflurane and halothane that suppressed platelet aggregation in the present study correspond to approximately 0.26 and 0.72 MAC, respectively, whereas isoflurane concentrations as great as 1.52 MAC had no significant effect. The present study also demonstrated the complete reversibility of the antiaggregatory effect of sevoflurane. Platelets once exposed to sevoflurane but left in unsealed tubes for 45 min to let sevoflurane evaporate spontaneously showed normal aggregability.
Sevoflurane and halothane, at clinically relevant concentrations, suppressed secondary aggregation of human platelets in vitro. This effect of sevoflurane appeared to be caused by suppression of cyclooxygenase activity, whereas suppression of TXA2synthesis and reduced TXA2receptor-binding affinity may contribute to the antiaggregatory effect of halothane.
REFERENCES
Fyman PN, Triner L, Schranz H, Hartung J, Casthely PA, Abrams LM, Keaney AE, Cottrell JE: Effect of volatile anesthetics and nitrous oxide-fentanyl anesthesia on bleeding time. Br J Anaesth 1984; 56:1197-1200.
Dalsgaard-Nielsen J, Risbo A, Simmelkjaer P, Gormsen J: Impaired platelet aggregation and increased bleeding time during general anesthesia with halothane. Br J Anaesth 1981; 53:1039-42.
Gibbs NM: The effect of anesthetics agents on platelet function. Anaesth Intensive Care 1991; 19:495-520.
Sweeney D, Williams V: The effect of halothane general anesthesia on platelet function. Anaesth Intensive Care 1987; 15:278-81.
Ueda I: The effects of volatile general anesthetics on adenosine diphasphate-induced platelet aggregation. Anesthesiology 1971; 34:405-8.
Walter F, Vulliemoz Y, Verosky M, Triner L: Effect of halothane on the cyclic 3,5-adenosine Monophosphate enzyme system in human platelet. Anesth Analg 1980; 59:856-61.
Dalsgaard-Nielsen J, Gormsen J: Effect of halothane on platelet function. Thromb Haemost 1980; 44:143-5.
Weber A, Hohlfeld T, Schror K: ADP-induced second wave aggregation in platelet rich plasma from hypercholesterolemic rabbits. Thromb Res 1991; 64:703-12.
Hirakata H, Ushikubi F, Narumiya S, Hatano Y, Nakamura K, Mori K: The effect of inhaled anesthetics on the platelet aggregation and the ligand-binding affinity of the platelet thromboxane A sub 2 receptor. Anesth Analg 1995; 81:114-18.
Rand ML, Gross PL, Barrow DV, Packham MA: Acute in vitro effects of ethanol on responses of platelets from cholesterol-fed and Watanabe heritable hyperlipidemic rabbits. Arterioscler Thromb 1992; 12:437-45.
Chabielska E, Malinowska B, Buczko W: Influence of ethanol and serotonin on rat platelet aggregation. Pharmacology 1990; 40:288-92.
Ware JA, Coller BS: Platelet morphology, biochemistry and function, Hematology. 5th ed. Edited by Beutler E, Lichtman MA, Coller BS, Kipps TJ. New York, McGraw-Hill, 1995, pp 1161-1201.
Ushikubi F, Nakajima M, Yamamoto M, Ohtsu K, Kimura Y, Okuma M, Uchino H, Fujiwara M, Narumiya S: [sup 3 H]S-145 and [sup 125 I]IS-145-OH: New radioligands for platelet thromboxane A sub 2 receptor with low non-specific binding and high binding affinity for various receptor preparations. Eicosanoids 1989; 2:21-7.
Ushikubi F, Nakajima M, Hirata M, Okuma M, Fujiwara M, Narumiya S: Purification of the thromboxane A sub 2/prostaglandin H sub 2 receptor from human blood platelets. J Biol Chem 1989; 264:16496-501.
Macconi D, Vigano G, Bisogno G, Galbusera M, Orisio S, Remuzzi G, Livio M: Defective platelet aggregation in response to platelet-activating factor in uremia associated with low platelet thromboxane A sub 2 generation. Am J Kidney Dis 1992; XIX:318-25.
Vacas MI, Del Zar MM, Martinuzzo M, Falcon C, Carreras LO, Cardinali DP: Inhibition of human platelet aggregation and thromboxane B sub 2 production by melatonin correlation with plasma melatonin levels. J Pineal Res 1991; 11:135-9.
Koblin DD: Mechanisms of action, Anesthesia. 4th ed. Edited by Miller RD. New York: Churchill Livingstone, 1994, pp 67-99.
Figure 1. (A; top left and right) Typical recordings of epinephrine (3 micro Meter)- and adenosine diphosphate (ADP; 1 micro Meter)-induced platelet aggregation in the absence (control) and presence of sevoflurane (0.13 mM). (B) Typical recordings of STA2(1 micro Meter)-induced platelet aggregation in the absence (control) and presence of sevoflurane (0.26 mM) and halothane (0.49 mM).
Figure 1. (A; top left and right) Typical recordings of epinephrine (3 micro Meter)- and adenosine diphosphate (ADP; 1 micro Meter)-induced platelet aggregation in the absence (control) and presence of sevoflurane (0.13 mM). (B) Typical recordings of STA2(1 micro Meter)-induced platelet aggregation in the absence (control) and presence of sevoflurane (0.26 mM) and halothane (0.49 mM).
Figure 1. (A; top left and right) Typical recordings of epinephrine (3 micro Meter)- and adenosine diphosphate (ADP; 1 micro Meter)-induced platelet aggregation in the absence (control) and presence of sevoflurane (0.13 mM). (B) Typical recordings of STA2(1 micro Meter)-induced platelet aggregation in the absence (control) and presence of sevoflurane (0.26 mM) and halothane (0.49 mM).
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Figure 2. (A) Typical recordings of arachidonic acid (1 mM)-induced platelet aggregation in the absence (control) and presence of sevoflurane (0.13 mM) and halothane (0.49 mM). (B) Typical recordings of prostaglandin G2(15 micro Meter)-induced platelet aggregation in the absence (control) and presence of sevoflurane (0.26 mM).
Figure 2. (A) Typical recordings of arachidonic acid (1 mM)-induced platelet aggregation in the absence (control) and presence of sevoflurane (0.13 mM) and halothane (0.49 mM). (B) Typical recordings of prostaglandin G2(15 micro Meter)-induced platelet aggregation in the absence (control) and presence of sevoflurane (0.26 mM).
Figure 2. (A) Typical recordings of arachidonic acid (1 mM)-induced platelet aggregation in the absence (control) and presence of sevoflurane (0.13 mM) and halothane (0.49 mM). (B) Typical recordings of prostaglandin G2(15 micro Meter)-induced platelet aggregation in the absence (control) and presence of sevoflurane (0.26 mM).
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Figure 3. Scatchard analysis of [sup 3 H]S145 binding to washed platelets. B = bound; F = free.
Figure 3. Scatchard analysis of [sup 3 H]S145 binding to washed platelets. B = bound; F = free.
Figure 3. Scatchard analysis of [sup 3 H]S145 binding to washed platelets. B = bound; F = free.
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Figure 4. Thromboxane A2synthetic pathway.
Figure 4. Thromboxane A2synthetic pathway.
Figure 4. Thromboxane A2synthetic pathway.
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Table 1. The Concentrations of Drugs that Suppressed Aggregation Induced by Each Agonist
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Table 1. The Concentrations of Drugs that Suppressed Aggregation Induced by Each Agonist
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Table 2. The Thromboxane B2Levels of Platelets, Stimulated with Arachidonic Acid (AA, 1 mM) in the Absence and Presence of Anesthetic
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Table 2. The Thromboxane B2Levels of Platelets, Stimulated with Arachidonic Acid (AA, 1 mM) in the Absence and Presence of Anesthetic
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