Potential greater than additive vasorelaxant actions of milrinone and nitroglycerin on human conduit arteries

Antispastic Effect of Fasudil and Cocktail of Fasudil and Nitroglycerin in Internal Thoracic Artery

BACKGROUND

Spasm of arterial grafts in coronary artery bypass grafting is a clinical problem and can occasionally be lethal. Perioperative spasm in the internal thoracic artery (ITA) and coronary arteries occurs in 0.43% of patients. This study aimed to investigate the antispastic effect of a RhoA/Rho-kinase (Rho-associated coiled-coil-containing protein kinase [ROCK]) inhibitor (fasudil) with and without nitroglycerin in combination in the ITA.

METHODS

Isolated human ITA rings taken from 68 patients who were undergoing coronary bypass were studied in a myograph. Cumulative concentration-relaxation curves for fasudil (-9 to -3.5 log M) were established in the ITA, which was precontracted with potassium chloride or U46619. The inhibitory effect of fasudil (-6.3 or -5.3 log M) or fasudil in combination with nitroglycerin were also tested. The ROCK2 protein was measured by Western blot.

RESULTS

Fasudil caused similar relaxation in ITA rings contracted by potassium chloride or U46619. Pretreatment with -5.3 log M fasudil significantly depressed contraction induced by potassium chloride (P = .004 vs control; P = .017 vs -6.3 log M) and U46619 (P = .010 vs control; P = .041 vs. -6.3 log M). Fasudil in combination with nitroglycerin had more effect and more rapid and sustained relaxation than either vasodilator alone. Fasudil caused a decrease of ROCK2 protein content (P = .014).

CONCLUSIONS

Fasudil fully relaxes some vasoconstrictor-induced contraction and decreases ROCK2 protein content in the ITA. The combination of fasudil and nitroglycerin has a superior effect than either vasodilator alone. The new cocktail solution composed of fasudil and nitroglycerin (pH 7.4) has effective antispastic action and may prove to be a new antispastic method for arterial conduits during coronary bypass surgery.

Combined effect of left stellate ganglion blockade and topical administration of papaverine on left internal thoracic artery blood flow in patients undergoing coronary revascularization

Background:

Left stellate ganglion blockade (LSGB) may have additive effect to topical administration of papaverine on prevention of vasospasm of left internal thoracic artery (LITA).

Aims:

This study aims to compare LITA blood flow with topical application of papaverine alone or in combination with LSGB.

Setting:

Tertiary care hospital.

Design:

Prospective randomized controlled study.

Materials and Methods:

A total of 100 patients operated for coronary revascularization were randomly and equally allocated into two groups. In control Group-C, papaverine was applied topically during the dissection of LITA. In Group-S, the additional LSGB was performed. Blood flow was measured from cut end of the LITA for 15 s. Primary objectives of the evaluation were to observe differences in the LITA blood flow. Observing incidence of radial-femoral arterial pressure difference after cardiopulmonary bypass (CPB) was secondary objective.

Statistical Analysis:

Student's unpaired t-test and Fisher's exact test to find out a significant difference between the groups.

Results:

LITA flow in Group-S was insignificantly more (49.28 ± 7.88 ml/min) than Group-C (47.12 ± 7.24 ml/min), (P = 0.15). Radio-femoral arterial pressure difference remained low for 40 min after termination of CPB in the Group-S compared to the Group-C (−0.99 ± 1.85 vs. −1.92 ± 2.26).

Conclusion:

Combining LSGB with papaverine does not increase the LITA blood flow compared to when the papaverine is used alone. However, ganglion blockade reduces radial-femoral arterial pressure difference after CPB. Blockade can be achieved successfully under the ultrasound guidance without any complications.

Pharmacologic Management of Acute Heart Failure: A Review

Because of improved social and medical standards in the western world, the average age of the population continues to increase. This altering demographic profile has its impact on the surgical population, resulting in a dramatic increase in the number of patients with exten sive cardiovascular disease, presenting for either car diac or noncardiac surgery. As a result, the incidence of perioperative acute congestive heart failure (CHF) is a major clinical problem at the present time. For the pharmacologic management of acute CHF, the β-adreno ceptor agonists continue to be the mainstay of therapy, due to their short duration of action and hemodynamic controlability by continuous intravenous infusion. Mono therapy with the phosphodiesterase type III (PDE) inhibi tors appears to be the treatment of choice in selected patients with high systemic vascular resistance or re sidual β-adrenoceptor blockade. Combination therapy especially deserves attention, because this approach allows the enhancement of contractile force, possibly without the side effects associated with the administra tion of high concentrations of one agent alone. New developments including ultrashort-acting PDE inhibi tors, calcium-dependent calcium sensitizers, and cal cium promotors are anxiously awaited.

Antispastic Management in Arterial Grafts in Coronary Artery Bypass Grafting Surgery

Arterial grafts have long-term patency superior to vein grafts but have a tendency to develop spasm that can lead to potentially life-threatening complications. A perfect antispastic protocol should include advanced surgical technique and adequate pharmacologic methods. All pharmacologic vasodilator drugs relax the vessel through specific mechanisms, and therefore, there is no perfect, single best vasodilator to prevent or treat spasm of the arterial graft against all mechanisms of contraction. One of the choices is to use a combination of pharmacologic vasodilators targeting different mechanisms of spasm to obtain the reliable and best effect.

Arterial grafts: clinical classification and pharmacological management

In comparison with standard saphenous vein grafts, use of the internal mammary artery (IMA) as a coronary artery bypass graft has achieved superior long-term results. This is related to the differences in the biological characteristics between the venous and arterial grafts. However, even arterial grafts are not uniform in their biological characteristics. The variation in the perioperative behavior of the grafts and in their long-term patency may be related to different characteristics. These factors should be taken into account in the use of arterial grafts, some of which are subjected to more active pharmacological intervention during and after the operation to obtain satisfactory results. To better understand the biological behavior of the grafts, their common features and their differences, a clinical classification may be useful for a practicing surgeon. Based on experimental studies of their vasoreactivity combined with anatomical, physiological and embryological considerations, we have proposed a functional classification for arterial grafts that may be useful clinically. Our classification suggests that there are three types of arterial grafts: Type I-somatic arteries; Type II-splanchnic arteries; and Type III-limb arteries. Type I arteries have enhanced endothelial function and release more nitric oxide and other relaxing factors. Type II arteries, such as the gastro-epiploic artery, and Type III arteries, such as the radial artery (RA), have higher pharmacological reactivity to vasoconstrictors. This classification explains why the IMA has the best long-term patency. Because Type II and III arteries are prone to spasms due to higher contractility, they require more active pharmacological interventions. Furthermore, the harvesting technique of the conduits, including the saphenous vein and IMA, are described and discussed in this article. Prevention of spasms using two cocktails of medications (verapamil + nitroglycerin and nicardipine + nitroglycerin) during harvesting of the conduits is described. These solutions have been demonstrated to be clinically effective.

The effect of milrinone on the right ventricular function in patients with reduced right ventricular function undergoing off-pump coronary artery bypass graft surgery

This investigation evaluated the effect of continuous milrinone infusion on right ventricular (RV) function during off-pump coronary artery bypass graft (OPCAB) surgery in patients with reduced RV function. Fifty patients scheduled for OPCAB, with thermodilution RV ejection fraction (RVEF) <35% after anesthesia induction, were randomly allocated to either milrinone (0.5 microg/kg/min) or control (saline) group. Hemodynamic variables and RV volumetric data measured by thermodilution method were collected as follows: after anesthesia induction (T1); 10 min after heart displacement for obtuse marginal artery anastomosis (T2); after pericardial closure (T3). Cardiac index and heart rate increased and systemic vascular resistance significantly decreased in milrinone group at T2. Initially lower RVEF of milrinone group was eventually comparable to control group after milrinone infusion. RVEF did not significantly change at T2 and T3 in both groups. RV end-diastolic volume in milrinone group consistently decreased from the baseline at T2 and T3. Continuous infusion of milrinone without a bolus demonstrated potentially beneficial effect on cardiac output and RV afterload in patients with reduced RV function during OPCAB. However, aggressive augmentation of intravascular volume seems to be necessary to maximize the effect of the milrinone in these patients.

Phenoxybenzamine treatment is insufficient to prevent spasm in the radial artery: the effect of other vasodilators

OBJECTIVES

After its reintroduction as an arterial graft in coronary artery surgery, the radial artery is now established as an alternative arterial conduit, with good early and midterm patency. However, because of the concern about its vasospasticity, numerous vasodilator strategies have been used. Recently the use of the irreversible alpha-adrenergic antagonist phenoxybenzamine has been proposed. Although this treatment is effective in eliminating the vasoconstriction mediated by noradrenaline, the contribution of other circulating vasoconstrictors to vasospasm could be as important. This study investigates the response of radial arteries treated with phenoxybenzamine to vasoconstrictor stimuli and possible preventative strategies.

METHODS

In vitro, sections of radial artery, pretreated with phenoxybenzamine after harvesting, were stimulated with maximal concentrations of the vasoconstrictors noradrenaline, vasopressin, angiotensin II, KCl, and endothelin-1. In matched segments of artery, vasoconstrictor responses were recorded in the presence of diltiazem, glyceryl trinitrate, and papaverine and compared with phenoxybenzamine-treated samples.

RESULTS

Phenoxybenzamine-treated radial artery failed to respond to noradrenaline but did respond to vasopressin, angiotensin II, endothelin-1, and KCl. Diltiazem was largely ineffective against contractile stimuli apart from KCl. Glyceryl trinitrate and papaverine significantly reduced responses to all of the vasoconstrictors tested.

CONCLUSION

In phenoxybenzamine-treated sections of radial artery, circulating vasoconstrictor agonists may still contribute to the induction of spasm. Additional vasodilator strategies may be required to completely prevent vasospasm.

Intravenous milrinone in cardiac surgery

Phosphodiesterase inhibitors including milrinone produce positive inotropic effects by slowing the hydrolysis of cyclic adenosine monophosphate in the myocardium. With a loading dose of 50 microg/kg followed by an infusion of 0.5 microg x kg(-1) x min(-1), milrinone increases stroke volume index and left ventricular velocity of circumferential fiber shortening after weaning from cardiopulmonary bypass. Milrinone has potential for the treatment and prevention of internal mammary artery spasm because of its vasodilative effect, which is similar to that of papaverine, and is a potent pulmonary vasodilator for patients with right ventricular dysfunction and pulmonary vasoconstriction. Low-dose milrinone may have antiinflammatory properties and potentially can improve splanchnic perfusion.

Comparison of milrinone versus nitroglycerin, alone and in combination, on grafted internal mammary artery flow after cardiopulmonary bypass: effects of alpha-adrenergic stimulation

OBJECTIVES

To compare changes in blood flow in a grafted internal mammary artery (IMA) after cardiopulmonary bypass (CPB) in response to the administration of milrinone or nitroglycerin and to establish the effects of alpha-adrenergic stimulation.

DESIGN

Randomized study.

SETTING

A university medical center hospital and a Veterans Affairs Medical Center hospital.

PARTICIPANTS

Thirty consenting adults scheduled for elective coronary artery bypass graft surgery.

INTERVENTIONS

Patients were randomized to receive a 2 microg/kg/min infusion of nitroglycerin (n = 10), a loading dose of 50 microg/kg of milrinone (n = 10), or both drugs combined (n = 10) shortly after CPB. Intravenous phenylephrine was administered to increase mean arterial pressure by 20%. IMA flow was measured with a calibrated laser Doppler flow probe. Hemodynamic and flow measurements were obtained before and after every intervention.

MEASUREMENTS AND MAIN RESULTS

Nitroglycerin and milrinone increased mean IMA flow, but the increase was greater with milrinone. Both drugs combined were superior to nitroglycerin alone but not to milrinone. The addition of phenylephrine to nitroglycerin increased IMA flow in 6 of 10 patients. IMA flow decreased in 4 of 10 patients, however. Phenylephrine significantly increased IMA blood flow in patients receiving milrinone or in those given both drugs combined.

CONCLUSION

After CPB, milrinone and nitroglycerin vasodilate the IMA; however, the combination of both drugs was not superior to milrinone alone. When using alpha-adrenergic stimulation, milrinone proved superior to nitroglycerin in preserving IMA flow.

Inhibition of vasoconstriction by AJ-2615, a novel calcium antagonist with alpha(1)-adrenergic receptor blocking activity in human conduit arteries used as bypass grafts

AIMS

Graft spasm may develop during coronary artery bypass grafting and reversal of spasm is still challenging. The purpose of this study was to investigate the in vitro vascular relaxant properties of AJ-2615 in human internal mammary artery (IMA).

METHODS

We studied 264 IMA rings taken from 65 patients undergoing coronary artery bypass grafting surgery with organ bath technique. The interaction between AJ-2615 and various vasoconstrictors was investigated in two ways.

RESULTS

AJ-2615 caused complete relaxation in methoxamine-contracted IMA rings (100.0+/-0.0%; n = 8) and nearly full relaxation in potassium chloride-contracted IMA rings (91.4+/-5.7%; n = 8) or noradrenaline-contracted IMA rings (89.3+/-2.8%; n = 8). AJ-2615 also induced remarkable relaxation in IMA rings contracted by other vasoconstrictors. In comparison with the alpha1-adrenoceptor antagonist prazosin, AJ 2615 showed similar maximal relaxation in IMA rings contracted by methoxamine or norepinephrine. On the other hand, incubation with AJ-2615 (0.1-1 microM) significantly inhibited all the vasoconstrictor-mediated vasoconstriction except endothelin-1 in a concentration-dependent manner.

CONCLUSIONS

The results suggested that in human IMA, AJ-2615 has an inhibitory effect on vasoconstriction mediated by a variety of vasoconstrictors and the mechanism of relaxation may be related to its calcium antagonism and alpha1-adrenergic receptor blocking activity. AJ-2615 may have important clinical implications for patients undergoing coronary artery bypass surgery for reversing and preventing graft spasm.

Role of BK(Ca) channels and cyclic nucleotides in synergistic relaxation of trachea

beta-Adrenoceptor agonists, nitric oxide (NO), and NO donors have been shown to mediate their effects through large conductance Ca(2+)-activated K(+) (BK(Ca)) channels. The mechanism of the synergistic effect of the beta(2)-adrenoceptor agonist, salbutamol, and an NO donor, sodium nitroprusside, was studied in guinea pig tracheal preparations. Salbutamol (0.1 nM) and sodium nitroprusside (0.33 microM) alone relaxed the acetyl-beta-methylcholine chloride (methacholine)-contracted preparations only by 0.5% and 28%, respectively, but their combination caused a maximum of 60% relaxation (at 3 min), which stabilized to 40% (at 10 min). Iberiotoxin, a selective inhibitor of the BK(Ca) channels, did not abolish the synergistic effect. 3-isobutyl-1-methylxanthine (IBMX) did not modify relaxation evoked by the drugs. Concentrations of cyclic nucleotides did not correlate with relaxations as a function of time. The mechanism of synergy remains to be clarified. The results show that NO is an important modulator in the relaxation of guinea pig trachea induced by beta(2)-adrenoceptor agonists in vitro.

Vasorelaxant effect of phosphodiesterase-inhibitor milrinone in the human radial artery used as coronary bypass graft

OBJECTIVE

The radial artery is a spastic coronary bypass graft. We investigated the effect of the phosphodiesterase III inhibitor milrinone on the human radial artery.

METHODS

Radial artery segments (n = 76) taken from 15 patients were studied in an organ chamber. Concentration-relaxation curves for milrinone were established in the radial artery precontracted with 3 vasoconstrictors (phenylephrine, K(+), and U46619). In radial artery rings incubated with therapeutic plasma concentrations of milrinone (7 and 70 micromol/L) for 10 minutes, concentration-contraction curves for the 3 vasoconstrictors were constructed.

RESULTS

Milrinone caused a submaximal relaxation in phenylephrine- (98.6% +/- 1.4%), K(+)- (89.1 +/- 4.5%), or U46619- (74.2 +/- 8.0%) precontracted radial arteries at -4.5 log(10) M. The EC(50) was higher against K(+) (-5.85 +/- 0.24 log(10) M, P =.02) or U46619 (-5. 21 +/- 0.61 log(10) M, P =.03) than phenylephrine (-6.68 +/- 0.11 log(10) M). Pretreatment with milrinone depressed the contraction by phenylephrine from 70.0% +/- 7.9% to 23.5% +/- 9.3% (P =.003) and by K(+) from 138.6% +/- 5.8% to 73.0% +/- 13.9% (P =.006) and shifted the EC(50) 3.8-fold higher (P =.03) for phenylephrine and 2.2-fold higher for K(+) (P =.01). Milrinone reduced the U46619 contraction at low concentration (-8.5 log(10) M) but had little effect on the maximal contraction.

CONCLUSION

Milrinone is a potent vasodilator for the radial artery, with possibly higher potency in alpha-adrenoceptor- and depolarizing agent K(+)-mediated, but less potency in thromboxane A(2)-mediated, contraction. Because it also has a positive inotropic effect, this vasodilator may be particularly indicated for use in patients receiving radial artery grafts in coronary artery bypass grafting.

Interaction of L-arginine and phosphodiesterase inhibitors in vasodilation of the porcine internal mammary artery

We tested the hypothesis that L-arginine (the substrate for nitric oxide production)-combined with amrinone, milrinone (Type III phosphodiesterase [PDE] inhibitors), zaprinast, or sildenafil (Type V PDE inhibitors)-would vasodilate synergistically. Internal mammary artery segments were excised from anesthetized swine, divided into rings, and suspended in a tissue bath at 37 degrees C. Force of contraction was measured during dose-response testing of combinations of L-arginine and amrinone, milrinone, zaprinast, or sildenafil. Amrinone and milrinone were additive to L-arginine. N(G)-methyl-L-arginine (L-NMA) inhibited the effects of milrinone but not amrinone. The effective concentration of amrinone eliciting 50% relaxation (EC(50)) was 3.8E-05M (n = 6) when given alone and 4. 4E-05M (n = 6) with L-NMA. Milrinone had EC(50) = 6.0E-06M alone (n = 6) and 2.8E-05M (n = 6) with L-NMA. Zaprinast (EC(50) = 6.5E-05M, n = 6) and sildenafil (EC(30) = 1.8E-05M, n = 6) were synergistic with L-arginine. L-NMA blocked their effects, increasing the EC(50) for zaprinast to 9.9E-03M and the EC(30) for sildenafil to 6.1E+02M. In conclusion, L-arginine is additive to the vasodilation of the type III PDE inhibitors, amrinone and milrinone, but synergistic with the type V PDE inhibitors, zaprinast and sildenafil.

IMPLICATIONS

Amrinone and milrinone, Type III cAMP-dependent phosphodiesterase inhibitors, are additive to L-arginine-dependent vasodilation. Zaprinast and sildenafil, Type V cGMP-dependent phosphodiesterase inhibitors, are synergistic with L-arginine.

Effects of milrinone versus epinephrine on grafted internal mammary artery flow after cardiopulmonary bypass

OBJECTIVE

To compare changes on grafted internal mammary artery (IMA) flow after cardiopulmonary bypass in response to the administration of milrinone or epinephrine.

DESIGN

Prospective and randomized.

SETTING

University-affiliated hospital.

PARTICIPANTS

Twenty consenting, adult patients undergoing CABG.

INTERVENTIONS

Patients were randomized to receive either milrinone, 50 microg/kg, or epinephrine, 0.03 microg/kg/min, immediately after cardiopulmonary bypass. IMA flow was measured with a laser Doppler flow probe before and after the administration of either drug.

MEASUREMENTS AND MAIN RESULTS

Baseline grafted IMA flow was similar for both groups (milrinone, 38+/-14 mL/min; epinephrine, 33+/-10 mL/min). In patients who received milrinone, flow increased by 24% to 50+/-17 mL/min, p<0.05; whereas with epinephrine, it remained essentially unchanged (33+/-10 v. 31+/-11 mL/min).

CONCLUSIONS

This study confirms that the vasodilatory effect of milrinone on the IMA is also present after its anastomosis, whereas low-dose epinephrine exhibits neither beneficial nor adverse effects. It is suggested that in the absence of excessive vasodilation, milrinone should be considered as a first-line inotrope after coronary artery bypass graft surgery, to achieve an increase in contractility and IMA artery flow.

Vasorelaxant actions of enoximone, dobutamine, and the combination on human arterial coronary bypass grafts

Enoximone (a type III-selective phosphodiesterase inhibitor) and dobutamine (a beta-receptor agonist) are positive inotropic drugs frequently used in the postoperative management of coronary bypass surgery. The purpose of this study was to characterize their relaxant effects on the human internal mammary artery (IMA) and the gastroepiploic artery (GEA) and to test the hypothesis that their combination may have greater than additive relaxant effects. In organ baths, the relaxant effects of enoximone and dobutamine were tested on rings of IMA (n = 86) precontracted with U46619 (a thromboxane A2 mimetic), norepinephrine (NE), or KCl. The relaxant effects of dobutamine and enoximone also were tested on rings of GEA (n = 42) precontracted with U46619 and NE. The effect of the combination of enoximone and dobutamine were tested on rings of IMA (n = 24) precontracted with U46619 or NE. With respect to maximal relaxations induced by papaverine (10(-4) M), enoximone (< or =10(-3) M) caused full relaxations of IMA precontracted with NE, U46619, or KCI. Dobutamine (< or =10(-3) M) caused full relaxations of IMA precontracted with NE or KCI but only 46% (95% CI, 27-65) relaxation in the rings precontracted with U46619. Similar patterns of relaxation were observed in GEA rings, with dobutamine inducing partial relaxation in GEA precontracted with U46619. The pD2 values of enoximone and dobutamine were both significantly lower in segments precontracted with U46619. The in vitro threshold relaxant concentrations were in the upper limits or over the range of therapeutic plasma concentrations. The relaxant effect of the combination was significantly more important than the theoretic additive effect in IMA contracted with U46619 or NE. Enoximone and dobutamine are potent in vitro vasodilators but exert weak relaxant effects in IMA and GEA at concentrations in the therapeutic range. There is, however, a greater than additive vasorelaxant effect of the combination, suggesting that the vasorelaxant effect of the combination, in addition to the additive inotropic effect, may be beneficial to patients undergoing coronary bypass grafting.

Inhibition of vasoconstriction by the thromboxane A2 antagonist GR32191B in the human radial artery

AIMS

The newly revived coronary bypass graft, the radial artery (RA), is more spastic than the internal mammary artery. Thromboxane A2 is a potent vasoconstrictor for arterial grafts. This study was therefore designed to determine whether the specific thromboxane A2 (TP) receptor antagonist, GR32191B, is effective in inhibition of prostanoid or nonprostanoid receptors in the RA.

METHODS

The effect of GR32191B was studied in human RA segments, taken from coronary bypass patients, in organ chambers. Two effects of GR32191B were tested: (1) the relaxation induced by GR32191B in the RA precontracted with the TP receptor agonists U46619 and PGF2alpha or nonprostanoid vasoconstrictors (noradrenaline [NA], angiotensin II [AII], and K+ ) and (2) the inhibitory effect of GR32191B on TP receptor agonists and nonprostanoid vasoconstrictors.

RESULTS

In U46619 (10 nm, n=7) and PGF2alpha (1 microm, n=7) precontracted RA, GR32191B induced 100% relaxation (10-100 microm ) but not after precontraction with nonprostanoid stimuli (5.8% for K+, 25 mm, n=6, 24.4% for NA, 3 microm, n=8, and 53.2% for AII, 3 nm, n=5) (P<0.001). Treatment with GR32191B (30 nm ) significantly depressed the contraction with U46619 (from 160.1+/-11.0% to 116.8+/-13.1%, P<0. 05) or PGF2alpha (from 91.3+/-12.3% to 42.2+/-9.2%, P<0.01). The contraction was further abolished by 3 microm GR32191B. However, GR32191B at 3 microm did not significantly inhibit the contraction induced by either NA, AII, or K+.

CONCLUSIONS

GR32191B is a highly potent and specific TP receptor antagonist for the human RA. It may be particularly useful in inhibiting TXA2-mediated vasoconstriction and therefore in reducing the complications related to vasospasm in this graft.

Comparison of the vasorelaxant effect of nitroprusside and nitroglycerin in the human radial artery in vitro

AIMS

In recent years the radial artery (RA) has been re-introduced for coronary artery bypass grafting (CABG). However, the potential for vasospasm remains a clinical problem when this vessel is employed and effective vasodilator agents are required to combat vasospastic events. This in vitro study was designed to compare the vasodilator effects of sodium nitroprusside (SNP) and nitroglycerin (NTG) in the human RA.

METHODS

Human RA segments (n=70) were taken from vessels employed for grafting in patients undergoing CABG. Concentration-relaxation curves for SNP and NTG were established in RA which had been precontracted with various vasoconstrictors (potassium chloride [K+], the thromboxane A2 mimetic agent U46619 or endothelin-1 [ET-1]).

RESULTS

Both SNP and NTG caused complete relaxation and EC50s were similar except that NTG was 6.2-fold more potent than SNP in U46619-induced contraction (-7.50+/-0.16 vs -6. 71+/-0.38 log m, P=0.04). After treatment with verapamil and NTG solution during harvesting, the RA segments responded with reduced maximal relaxation to NTG (84.9+/-3.9%, compared with 98.8+/-0.8% in the control, P=0.004). The vessel became less sensitive to NTG (EC50: -6.29+/-0.4 vs -7.50+/-0.16 log m, P=0.01). In investigations carried out with SNP, tolerance was only seen in the magnitude of the relaxation (87.4+/-4.7% vs 99.2+/-0.6% in the control, P=0.03).

CONCLUSIONS

Both NTG and SNP are potent vasodilators in the RA. NTG may have more potent effects in certain situations (constriction related to thromboxane A2). However, tolerance to NTG may develop. A cross tolerance to SNP may exist but the effect is weak so that SNP may be preferable to NTG as a vasodilator in the RA postoperatively. Other vasodilators may be the drugs of choice under such circumstances.

Pharmacology of coronary artery bypass grafts

Spasm of arterial and venous graft conduits can occur both during harvesting and after the graft is connected. Attempts to overcome spasm during harvesting by probing or hydraulic distension can cause structural damage to the graft, which may impair short- and long-term patency. After a coronary artery bypass graft is connected, spasm can cause major problems with myocardial perfusion. To select the best pharmacologic agent to prevent or reverse vasoconstriction in a graft requires an understanding of the reactivity of that particular type of graft to vasoconstrictor and vasodilator agents. The pharmacologic reactivity of venous and arterial graft conduits has been documented through extensive studies of isolated vessels in the organ bath and of in situ grafts in the body. In this review we summarize the current state of knowledge of the reactivity of arterial and venous grafts to vasoconstrictor and vasodilator agents and describe the practical application of this knowledge in the operating room and in the postoperative period.