The effectiveness of myocardial protection of cardioplegia has been a matter of debate for decades. This study was designed to compare cardiac and endothelial protection of 3 clinically used cardioplegias: del Nido cardioplegia (DNC), histidine-tryptophan-ketoglutarate (HTK) and blood cardioplegia (BC) followed by HTK (BC + HTK) in a rat model of ischaemia/reperfusion (I/R).

Sixty male Wistar rats were subjected to either 120 min of global ischaemia at 4°C followed by 90 min of reperfusion (I/R) at 37°C or no I/R (control) in a Langendorff apparatus and were randomly allocated to 5 groups: control, I/R, DNC, HTK and BC + HTK. Cold cardioplegia solutions were administered at doses of 20 ml/kg for DNC and HTK or 10 ml/kg for BC followed by HTK. Haemodynamic parameters were continuously recorded using an intraventricular balloon. The endothelium-dependent relaxation to acetylcholine was measured in the left anterior descending artery using a myograph. Protein expression of cardiac troponin T (cTnT) and creatine kinase MB was determined by western blot.

During reperfusion, HTK had higher left ventricular systolic pressure whereas DNC had lower left ventricular end-diastolic pressure, better left ventricular developed pressure and best +dp/dtmax and -dp/dtmax than the other 2 groups but the differences disappeared at the end of the reperfusion. HTK or BC + HTK preserves the acetylcholine-induced endothelium-dependent relaxation better than DNC (Emax = 48.2 ± 8.0% in DNC vs 75.0 ± 8.0% in HTK, P < 0.05; vs 96.9 ± 3.5% in BC + HTK, P < 0.001). The protein levels of cTnT and creatine kinase MB were downregulated in the 3 groups.

All 3 cardioplegias prevented myocardial damage against I/R injury at the end of reperfusion. DNC demonstrated better preserved diastolic function of the left ventricle whereas HTK or BC + HTK showed better preserved coronary endothelial function. These findings may suggest that currently no 'perfect' cardioplegia exists and that exploration for the 'perfect' cardioplegia is needed.

Hyperkalemia is a recognized and potentially life-threatening complication of heart transplantation. In the complex biosystem created by transplantation, recipients are susceptible to multiple mechanisms for hyperkalemia which are discussed in detail in this manuscript. Hyperkalemia in heart transplantation could occur pre-transplant, during the transplant period, or post-transplant. Pre-transplant causes of hyperkalemia include hypothermia, donor heart preservation solutions, conventional cardioplegia, normokalemic cardioplegia, continuous warm reperfusion technique, and ex-vivo heart perfusion. Intra-transplant causes of hyperkalemia include anesthetic medications used during the procedure, heparinization, blood transfusions, and a low output state. Finally, post-transplant causes of hyperkalemia include hemostasis and drug-induced hyperkalemia. Hyperkalemia has been studied in kidney and liver transplant recipients, but there is limited data on the incidence, causes, management, and prevention in heart transplant recipients. Hyperkalemia is associated with an increased risk of hospital mortality and readmission in these patients. This review describes the current literature pertaining to the causes, pathophysiology, and treatment of hyperkalemia in patients undergoing heart transplantation and focuses primarily on post-heart transplantation.

Cardioplegic solutions were first developed to preserve heart function during cardiac surgeries and heart transplants but have application in the nonclinical setting. Due to lack of lab space in the vivarium, cardioplegic solution was used to conserve cardiac function for ex-vivo studies performed in a separate building. All studies in this report were conducted with isolated female rabbit hearts (IRHs) via retrograde perfusion using the Langendorff apparatus to investigate if cardioplegia usage affects cardiac function.

Cardioplegia was achieved with a hyperkalemia (27 mM KCL) solution kept at 4 °C. Cardiac function was assessed by measuring ECG parameters, left ventricular contractility, and coronary flow under constant perfusion pressure. IRHs were cannulated with Krebs Henseleit buffer (KH) either fresh or after cardioplegic solution storage (C-IRH). Three comparisons were performed with and without cardioplegia; (i) direct side-by side studies of cardiac function; (ii) pharmacological responses to typical ion channels blockers, dofetilide, flecainide, and diltiazem; (iii) retrospective evaluation of cardiac functions in a large sample of hearts.

In the side-by-side comparisons, cardioplegia-stored IRHs (C-IRH; storage time 90 min) had similar electrocardiographic (ECG) and hemodynamic parameters to fresh-cannulated hearts with KH buffer (KH-IRH). In addition, responses to dofetilide, flecainide, and diltiazem, were similar for C-IRH and KH-IRH hearts. Over the years (2006-2011), baseline data was collected from 79 hearts without cardioplegia and 100 hearts with cardioplegia (C-IRH; storage time 15 min), which showed no meaningful differences in a retrospective analysis.

Cardiac function was preserved after cardioplegic treatment, however, coronary flow rates were decreased (-19.3%) in C-IRH hearts which indicated an altered coronary vascular tone. In conclusion, storage in cardioplegic solution preserves rabbit cardiac function, a practice that enables heart tissues to be collected at one site (e.g., vivarium) and transported to a laboratory in a separate location.

Vascular endothelium plays a critical role in the control of blood flow by producing vasoactive factors to regulate vascular tone. Ion channels, in particular, K(+) channels and Ca(2+)-permeable channels in endothelial cells, are essential to the production and function of endothelium-derived vasoactive factors. Impairment of coronary endothelial function occurs in open heart surgery that may result in reduction of coronary blood flow and thus in an inadequate myocardial perfusion. Hyperkalemic exposure and concurrent ischemia-reperfusion during cardioplegic intervention compromise NO and EDHF-mediated function and the impairment involves alterations of K(+) channels, that is, KATP and KCa, and Ca(2+)-permeable TRP channels in endothelial cells. Pharmacological modulation of these channels during ischemia-reperfusion and hyperkalemic exposure show promising results on the preservation of NO and EDHF-mediated endothelial function, which suggests the potential of targeting endothelial K(+) and TRP channels for myocardial protection during cardiac surgery.

Endothelial dysfunction has been implicated as a key factor in the development of a wide range of cardiovascular diseases, but its definition and mechanisms vary greatly between different disease processes. This review combines evidence from cell-culture experiments, in vitro and in vivo animal models, and clinical studies to identify the variety of mechanisms involved in endothelial dysfunction in its broadest sense. Several prominent disease states, including hypertension, heart failure, and atherosclerosis, are used to illustrate the different manifestations of endothelial dysfunction and to establish its clinical implications in the context of the range of mechanisms involved in its development. The size of the literature relating to this subject precludes a comprehensive survey; this review aims to cover the key elements of endothelial dysfunction in cardiovascular disease and to highlight the importance of the process across many different conditions.

Cardiac transplantation remains the first choice for the surgical treatment of end stage heart failure. An inadequate supply of donor grafts that meet existing criteria has limited the application of this therapy to suitable candidates and increased interest in extended criteria donors. Although cold storage (CS) is a time-tested method for the preservation of hearts during the ex vivo transport interval, its disadvantages are highlighted in hearts from the extended criteria donor. In contrast, transport of high-risk hearts using hypothermic machine perfusion (MP) provides continuous support of aerobic metabolism and ongoing washout of metabolic byproducts. Perhaps more importantly, monitoring the organ's response to this intervention provides insight into the viability of a heart initially deemed as extended criteria. Obviously, ex vivo MP introduces challenges, such as ensuring homogeneous tissue perfusion and avoiding myocardial edema. Though numerous groups have experimented with this technology, the best perfusate and perfusion parameters needed to achieve optimal results remain unclear. In the present review, we outline the benefits of ex vivo MP with particular attention to how the challenges can be addressed in order to achieve the most consistent results in a large animal model of the ideal heart donor. We provide evidence that MP can be used to resuscitate and evaluate hearts from animal and human extended criteria donors, including the non-heart beating donor, which we feel is the most compelling argument for why this technology is likely to impact the donor pool.

The cardiac venous system possesses up to 30% of total coronary vascular resistance and the effect of hypoxia-reoxygenation (H-R) and St Thomas (ST) cardioplegic solution on the vein is unknown. We investigated the effects of H-R, with or without ST, on endothelium-derived hyperpolarizing factor (EDHF)-mediated relaxation in porcine cardiac microveins under clinically relevant temperatures.

The microveins (diameter 200 to 450 microM) mounted in a myograph were subjected to hypoxia (Po2 < 5 mm Hg) for 30 minutes in Krebs solution (n = 8) or for 60 minutes in Krebs (n = 8) or in ST at 37 degrees C (n = 8) or 4 degrees C (n = 8), followed by 30-minute reoxygenation. The microvein was precontracted with thromboxane A2 mimetic U46619 (-7 log M) and the EDHF-mediated relaxation was induced by bradykinin (-10 to -6 log M) in the presence of indomethacin, NG-nitro-L-arginine, and oxyhemoglobin before and after H-R.

The maximal EDHF-mediated relaxation was significantly reduced after 30-minute hypoxia (38.7 +/- 2.0% vs 61.1 +/- 2.3%, n = 8, p < 0.001) or 60-minute hypoxia in either Krebs or ST at 37 degrees C (Krebs: 27.8 +/- 1.2% vs 56.6 +/- 2.5%, n = 8, p < 0.001; ST: 23.8 +/- 4.1% vs 57.1 +/- 1.5%, n = 8, p < 0.001). The relaxation was significantly less after prolonged H-R in Krebs (p < 0.001). Incubation in Krebs or ST at 4 degrees C also reduced the EDHF-mediated relaxation (Krebs: 25.3 +/- 3.3%, n = 8, p < 0.001; ST: 29.1 +/- 4.4%, n = 8, p < 0.001) and there were no significant differences between Krebs and ST regarding the relaxation at either 37 degrees C or 4 degrees C (p > 0.05).

We conclude that (1) H-R impairs EDHF-mediated relaxation in the coronary microveins with more severe injury during prolonged H-R and (2) ST does not provide protection to the EDHF-mediated relaxation impaired by H-R at either 37 degrees C or 4 degrees C.

We investigated a relatively new organ preservation (Celsior) solution regarding its effect on the endothelium-derived hyperpolarizing factor (EDHF)-mediated function with comparison to St. Thomas Hospital (ST) solution.

The EDHF-mediated relaxation was induced by bradykinin (BK, -10 to -6.5 logM) in the presence of inhibitors of nitric oxide and prostacyclin in porcine small resistance coronary arteries, before and after incubation in ST (Group Ia, n=11), Celsior (Group Ib, n=13), or Krebs (Group Ic, control, n=12) at 4 degrees C for 4 hr. The EDHF-mediated hyperpolarization of the membrane potential of smooth muscle cells was measured by microelectrode with simultaneous relaxation after cold storage in ST (IIa, n=7), Celsior (IIb, n=6), or Krebs (IIc, control, n=6), or followed by washout with Krebs (ST: IIIa, n=6, Celsior: IIIb, n=6).

The EDHF-mediated relaxation was significantly decreased in Group Ia (56.4+/-7.2% vs. 71.2+/-5.3%, P<0.05) and Ib (44.8+/-4.9% vs. 74.7+/-3.3%, P<0.05) but not in Ic. The sensitivity to BK was also significantly decreased (Ia: -7.51+/-0.14 vs. -7.76+/-0.12 log M, P<0.05; Ib: -7.36+/-0.09 vs. -7.60+/-0.09 logM, P<0.05). The resting membrane potential was depolarized in IIa (-44.3+/-1.9 mV, n=7, P<0.05) and IIb (-33.0+/-2.2 mV, n=6, P<0.05) compared with IIc (-57.1+/-1.5 mV, n=6). The EDHF-mediated hyperpolarization decreased significantly in IIa and IIb (3.4+/-0.3 and 3.0+/-0.2 vs. 6.3+/-0.5 mV, P<0.05) and partially restored in IIIa (5.0+/-0.2 vs. 3.4+/-0.3 mV, P<0.05) and IIIb (4.1+/-0.3 vs. 3.0+/-0.2 mV, P<0.05).

Storage with Celsior and ST solutions reduces the EDHF-mediated endothelial function (hyperpolarization and associated relaxation) in porcine small resistance coronary arteries.

We investigated effects of hypoxia-reoxygenation (H-R) with and without St. Thomas solution under clinically relevant temperatures and effects of nicorandil on endothelium-derived hyperpolarizing factor (EDHF)-mediated relaxation in porcine coronary microarteries.

In a myograph, rings of porcine microarteries (diameter 200 to 450 microm) were subjected to hypoxia (PO2 < 5 mm Hg) for 30 minutes in Krebs at 37 degrees C, or for 60 minutes in Krebs and St. Thomas solution with or without nicorandil (0.1 microM) at 37 degrees C or 4 degrees C, followed by 30-minute reoxygenation. The EDHF-mediated relaxation by bradykinin (-10 to approximately -6 logM) with inhibitors of nitric oxide and prostacyclin was studied.

The maximal EDHF-mediated relaxation was reduced after hypoxia for 30 minutes (59.9%% +/- 1.6% versus 81.2%% +/- 3.5%, p < 0.05) or 60 minutes (44.4% +/- 6.0% versus 82.7% +/- 7.4%, p < 0.001) in Krebs or St. Thomas (28.9% +/- 1.8% versus 78.1% +/- 3.0%, p < 0.001) at 37 degrees C and at 4 degrees C (Krebs: 49.3% +/- 3.0%, p < 0.001; ST: 43.1% +/- 2.6%, p < 0.001) and it was less in St. Thomas solution at 37 degrees C than at 4 degrees C (p < 0.001). The reduced relaxation was recovered by nicorandil (Krebs at 37 degrees C: 81.7% +/- 3.4%, p < 0.001; St. Thomas at 37 degrees C: 71.0% +/- 7.9%, p <0.001; St. Thomas at 4 degrees C: 85.3% +/- 3.3%, p < 0.001).

We conclude that (1) H-R impairs EDHF-mediated relaxation in the coronary microarteries with more injury during prolonged H-R, and this can be partially eliminated by St. Thomas at 4 degrees C but not at 37 degrees C; and (2) as an additive, nicorandil may fully restore EDHF-mediated endothelial function after prolonged H-R.

Cardioplegic (and organ preservation) solutions were initially designed to protect the myocardium (cardiac myocytes) during cardiac operation (and heart transplantation). Because of differences between cardiac myocytes and vascular (endothelial and smooth muscle) cells in structure and function, the solutions may have an adverse effect on coronary vascular cells. However, such effect is often complicated by many other factors such as ischemia-reperfusion injury, temperature, and perfusion pressure or duration. To evaluate the effect of a solution on the coronary endothelial function, a number of points should be taken into consideration. First, the overall effect on endothelium should be identified. Second, the effect of the solution on the individual endothelium-derived relaxing factors (nitric oxide, prostacyclin, and endothelium-derived hyperpolarizing factor) must be distinguished. Third, the effect of each major component of the solution should be investigated. Lastly, the effect of a variety of new additives in the solution may be studied. Based on available literature these issues are reviewed to provide information for further development of cardioplegic or organ preservation solutions.

Coronary endothelial dysfunction occurs early after heart transplantation and predicts the development of cardiac allograft vasculopathy. Cardioplegic solutions may cause endothelial injury. The present study aimed to assess the effects of cardioplegic solutions (crystalloid, blood and Celsior) used at the time of graft harvesting on endothelial function and intimal hyperplasia 1 month after heart transplantation.

A porcine heterotopic heart transplantation model was used. Three experimental groups were studied: crystalloid, blood and Celsior solutions were used for induction of cardiac arrest. Epicardial coronary arteries of native and allograft hearts were studied 1 month after transplantation in organ chambers. Endothelium-dependent relaxations to serotonin, bradykinin and calcium ionophore were assessed. Coronary neointimal proliferation was evaluated using histomorphometric studies.

Endothelium-dependent relaxations to serotonin and to calcium ionophore were significantly decreased in all 3 experimental groups vs controls (p<0.05). Endothelium-dependent relaxations to bradykinin were significantly reduced in the crystalloid group compared with the Celsior and blood groups and controls (p<0.05). There was a significantly lower rate of severe intimal hyperplasia in the Celsior group compared to the crystalloid and blood groups (p<0.05).

Celsior cardioplegic solution represents the solution of choice in terms of preservation of endothelial function and lower incidence of severe coronary intimal hyperplasia following transplantation compared with crystalloid and blood cardioplegia solutions. These early results could translate into a reduction of the long-term incidence of cardiac allograft vasculopathy and improve graft survival.

Although the detrimental effect of hyperkalemia on coronary endothelium has been reported, there is no direct evidence regarding the effect of hyperkalemic exposure on nitric oxide (NO) release from the coronary endothelium. In addition, it is unclear whether nicorandil, a KATP channel opener, used as hyperpolarizing cardioplegia or added in hyperkalemic cardioplegic solution may protect endothelial function during cardiac surgery. The present study was designed to clarify NO release and the function of endothelium-derived hyperpolarizing factor (EDHF) in coronary circulation with respect to the effect of hyperkalemia and nicorandil.

Nitric oxide was measured by using a NO-specific electrode, and EDHF-mediated relaxation was investigated in a myograph. Substance P- and calcium ionophore A23187-induced NO release was compared in porcine left circumflex coronary arteries before and after 1-hour exposure to 20 mM potassium (K+) at 37 degrees C. In coronary microarteries (diameter 200 to 450 microm), precontracted with U46619, in the presence of indomethacin (7 microM), NG-nitro-L-arginine (300 microM), and oxyhemoglobin (20 microM), EDHF-mediated relaxation was induced by bradykinin (-10 to -6.5 log M) after incubation with Krebs (control) or 20 mM K+ with or without 10 microM nicorandil at 37 degrees C for 1 hour.

Neither substance P (58.8 +/- 5.0 versus 66.2 +/- 7.2 nmol/L) nor A23187 (86.6 +/- 9.0 versus 82.4 +/- 9.2 nmol/L in control) induced NO release was altered by hyperkalemic exposure (p > 0.05). In contrast, EDHF-mediated relaxation was decreased from 84.2% +/- 3.8% to 42.3% +/- 6.0% (p < 0.001) that was partially restored by nicorandil (50.7% +/- 5.5%, p < 0.05).

Exposure to potassium at 20 mM does not affect NO release but impairs EDHF-mediated relaxation in coronary arteries. Supplementation of nicorandil in hyperkalemic cardioplegia may provide a protective effect on EDHF-related endothelial function.

Vascular endothelium has multiple functions including regulating of vascular tone, preventing platelet aggregation, anti-proliferation, etc. An intact endothelial function is essential to the maintenance of an adequate vascular tone, to prevent platelet aggregation in the intimal surface of blood vessels, to prevent smooth muscle proliferation, and to prevent atherosclerosis. This review focuses on endothelial function related to the vascular tone in cardiac surgery. The review is composed by three sections. In the first section, normal endothelial function related to vascular tone is described. In the second section, coronary endothelial function related to cardiac arrest and cardioplegic exposure is reviewed. In the third section, the endothelial function in the coronary bypass grafts is summarised. It is particularly important to understand that coronary endothelial dysfunction may be one of the major causes of low perfusion of the myocardium after cardiac arrest or donor heart preservation. Further, endothelium plays a major role in the maintenance of vascular tone and in the long-term patency of CABG grafts. The characteristics of endothelium in arterial and venous grafts and the correlation to the long-term patency are now more understood. A number of methods have been suggested to protect endothelial function in either coronary circulation or in coronary artery bypass grafts during cardiac surgery but further investigations in this field are warranted.

Coronary endothelial dysfunction occurs early after heart transplantation and predicts the development of intimal thickening characteristic of cardiac allograft vasculopathy.

To assess the effects of removal of the endothelium by balloon injury of coronary arteries of allografts without rupture of the internal elastic lamina at the time of implantation and on coronary endothelial dysfunction, and to assess the development of accelerated atherosclerosis after heart transplantation.

A porcine model of heterotopic heart transplantation with preoperative immunologic typing, enabling progressive rejection without immunosuppression, was used to study the effect of endothelial removal on these 2 end points. Endothelium-dependent relaxations of epicardial coronary arteries from allografts submitted to endothelial denudation after harvest, arteries from allografts not undergoing denudation, and native coronary arteries were compared 30 days after graft implantation by using standard organ chamber experiments. Intimal thickening was measured by light microscopy with a semiquantitative scale (0 to 4+ grading).

Relaxations to serotonin and to bradykinin were significantly decreased in denuded arteries compared with nondenuded allograft arteries. There was a significant increase in the incidence of severe intimal hyperplasia in denuded arteries compared with nondenuded arteries, which were both significantly increased compared to native coronary arteries.

Endothelial injury at implantation worsens the endothelial dysfunction as a result of rejection after heart transplantation and compounds the intimal thickening leading to cardic allograft vasculopathy. All efforts should be deployed to maintain a morphologically intact and functional endothelium at the time of graft implantation.

Inadequate right atrial myocardial preservation during cardioplegic arrest may promote postoperative supraventricular arrhythmias (SVA). We determined (1). if oxygenated St. Thomas Hospital Cardioplegia #2 (STH2) alone causes slow reaction pacemaker cell (SR) quiescence; and (2). if hypothermia, higher [K(+)], lower [Ca(2+)], and verapamil in STH2 suppresses SR electrical activity.

A glass microelectrode recorded SA node SR membrane action potentials (AP) in rabbits (n = 23, 1.93 +/- 0.45 kg) randomized to normothermic STH2 (33 degrees C, n = 6), hypothermia (20 degrees C, n = 4), hypothermic STH2 (22 degrees C, n = 3), lower calcium STH2 (n = 3), higher potassium STH2 (n = 4), and STH2 plus Verapamil (n = 3).

Normothermic STH2 depressed SR action potential amplitude and action potential duration (APD), but did not completely suppress action potential generation. Hypothermia alone prolonged APD and sinus cycle length and suppressed SR AP. STH2 with hypothermia (to 20 degrees C) completely suppressed propagating AP and STH2 plus 0.04 Ca(2+) mEq/L inhibited SR AP generation. STH2 plus 30 mEq K(+) and STH2 plus 2.5 mmol/L verapamil failed to generate SR AP.

STH2 cannot prevent SA node SR myocardial cells from low-amplitude AP autogeneration above 21 degrees C. STH2 with 30 mEq/L K(+), STH2 with 0.02 mEq/L Ca(2+), and STH2 plus 2.5 mmol/L verapamil can arrest AP generation in SR and potentially prevent postoperative SVA.

The University of Wisconsin (UW) solution is used widely in heart preservation but has been demonstrated to be detrimental to the endothelial function. The present study compares the effect of histidine-tryptophan-ketoglutarate (HTK) and UW solutions on endothelium-derived hyperpolarizing factor (EDHF)-mediated function in porcine small coronary arteries.

An isometric force study was performed in a myograph and the membrane potential of a single smooth muscle cell was measured electrophysiologically. Small coronary arteries (diameter 457 +/- 15 microm) were incubated with UW (n = 8), HTK (n = 7) or Krebs solution (n = 15) at 4 degrees C for 4 hours. After washout, in the presence of indomethacin (Indo; 7 micromol/liter), N(G)-nitro-l-arginine (l-NNA; 300 micromol/liter) and oxyhemoglobin (HbO; 20 micromol/liter), bradykinin (BK; -10 to -6.5 log M)-induced relaxation was compared in U46619 (-8 log M) pre-contraction. EDHF-mediated hyperpolarization was elicited by BK (-6.5 log M) in the presence of Indo, l-NNA and HbO.

BK-induced, EDHF-mediated relaxation was reduced from 93.6 +/- 2.8% to 79.7 +/- 4.6% after UW preservation (p = 0.01 by unpaired t-test and p = 0.005 by 2-way analysis of variance [ANOVA]), whereas HTK incubation did not decrease EDHF-mediated relaxation (87.0 +/- 6.5%, p = 0.3 by unpaired t-test and p = 0.6 by 2-way ANOVA, compared with control, and p = 0.001 by 2-way ANOVA, compared with UW). EDHF-mediated hyperpolarization (10.3 +/- 1.6 mV) was attenuated by UW exposure (3.4 +/- 0.6 mV, [p = 0.002] vs control), but not by HTK exposure (8.3 +/- 1.1 mV, [p = 0.3] vs control).

HTK is superior to UW solution in protecting EDHF-mediated endothelial function in porcine small coronary arteries. The present findings supports the use of HTK solution in heart preservation.

We examined the effect of 11,12-epoxyeicosatrienoic acid (EET(11,12)) added to St. Thomas' Hospital (ST) solution or University of Wisconsin (UW) solution on endothelium-derived hyperpolarizing factor (EDHF)-mediated relaxation under clinically relevant temperature and exposure time.

Porcine coronary microarteries (200 to 450 microm) were incubated with Krebs' solution (control), ST with or without EET(11,12) (300 nmol/L) at 22 degrees C for 1 hour as well as at 4 degrees C for 1 or 4 hours, and UW with or without EET(11,12) at 4 degrees C for 4 hours. The EDHF-mediated relaxation was induced by bradykinin (-10 to approximately -6.5 log M) in the precontraction evoked by U(46619) (10 nmol/L) or U(46619) (1 nmol/L) plus endothelin-1 (6 nmol/L).

The EDHF-mediated relaxation was reduced after exposure to UW (79.7% +/- 4.6% versus 93.6% +/- 2.8%, p = 0.01) at 4 degrees C for 4 hours. One-hour exposure to ST under 22 degrees C or 4 degrees C decreased the relaxation (75.2% +/- 7.6% versus 96.7% +/- 1.6%, p < 0.05) or the sensitivity to bradykinin (-8.04 +/- 0.15 versus -8.50 +/- 0.20 log M, p < 0.05). The relaxation increased to 86.8% +/- 5.3% by addition of EET(11,12) to ST (1 hour at 22 degrees C, p < 0.05) but was unchanged when added to either ST or UW at 4 degrees C for 1 or 4 hours.

As an additive to ST solution, EET(11,12) may partially restore EDHF-mediated endothelial function under moderate hypothermia but had no significant effect under profound hypothermia when added to either ST or UW solution. Further investigation is necessary to improve the effect.

Endothelium plays an important role in mediating the function of transplanted organs. The widely used University of Wisconsin solution impairs the endothelium-derived hyperpolarizing factor-mediated relaxation in coronary arteries, but little is known about effects of lung preservation on endothelium-derived hyperpolarizing factor-mediated endothelial function. This study examined the effect of organ preservation solutions on the endothelium-derived hyperpolarizing factor-mediated relaxation in the pulmonary microarteries (diameter 200 to 450 microm).

Two segments (1 as control) from the same microartery were allocated in 2 chambers of a myograph. After incubation with hyperkalemia (potassium 115 mmol/L), University of Wisconsin, or Euro-Collins solution (at 4 degrees C for 4 hours), the endothelium-derived hyperpolarizing factor-mediated relaxation was induced by bradykinin (-10 to -6.5 log M, n = 8) or calcium ionophore (A(23187), -9 to -5.5 log M, n = 7) in U(46619) (-7.5 log M) precontracted rings in the presence of indomethacin (7 micromol/L), N(G)-nitro-L-arginine (300 micromol/L), and oxyhemoglobin (20 micromol/L).

Exposure to hyperkalemia and storage with Euro-Collins or University of Wisconsin solution significantly decreased the relaxation to bradykinin (51.9 +/- 8.4% vs 60.3 +/- 6.1%, P =.02 or 49.3 +/- 7.3% vs 65.2 +/- 3.5%, P =.04) or A(23187) (12.5 +/- 0.02% vs 33.8 +/- 0.07%, P =.02 or 13.2 +/- 0.03% vs 31.0 +/- 0.05%, P =.03%).

Endothelium-derived hyperpolarizing factor plays an important role in porcine pulmonary microarteries, and the endothelium-derived hyperpolarizing factor-mediated relaxation is impaired when the lung is preserved with University of Wisconsin or Euro-Collins solution. This impairment may affect the lung function during the reperfusion period after lung transplantation.

Hyperkalemia in cardioplegia impairs the endothelium-derived hyperpolarizing factor (EDHF)-mediated function. This study examined the effect of procaine in cardioplegia on the EDHF-mediated response in porcine coronary arteries.

An isometric force study was performed in a myograph. Two rings taken from the same artery (diameter 200-450 microm) were incubated with Krebs solution (group I) or 20 mM K+ (group II) with/without procaine (1 mM) at 37 degrees C for 1 hour. The EDHF-mediated relaxation was induced by bradykinin (BK, -10 approximately -6.5 log M) after U46619 (-8 log M, in group I) or K+-precontraction (in group II) in the presence of indomethacin (7 microM), NG-nitro-L-arginine (300 microM), and hemoglobin (20 microM). The membrane potential of a single smooth muscle cell was measured by a microelectrode after superfusion with Krebs solution with/without procaine for 1 hour.

The EDHF-mediated relaxation was increased by the treatment with procaine with the EC50 shifted leftward (97.3 +/- 0.6% vs. 83.0 +/- 5.1% at -7 log M and 99.4 +/- 0.6% vs. 96.7 +/- 1.6% at -6.5 log M, p < 0.05; EC50: -8.57 +/- 0.24 vs. -7.92 +/- 0.23 log M, p < 0.05). Procaine decreased the BK-induced hyperpolarization from -72.3 +/- 0.7 mV to -68.8 +/- 0.8 mV (-6.5 log M, p < 0.01). The EDHF-mediated relaxation in arteries exposed to 20 mM K+ was not altered by procaine (49.9 +/- 7.4% vs. 55.8 +/- 7.6%, p > 0.05).

In the coronary arteries, procaine has a depolarizing effect but it enhances EDHF-mediated relaxation. Addition of procaine in cardioplegia did not change the EDHF-mediated endothelial function.

Hyperkalemia in cardioplegia impairs the function mediated by endothelium-derived hyperpolarizing factor. This study examined the effect and mechanism of magnesium ion on the relaxation mediated by endothelium-derived hyperpolarizing factor.

In the isometric force study, porcine coronary microarteries in a myograph (diameter 200-450 microm) were incubated in Krebs solution (subgroups Ia, IIa, and IIIa), potassium ion (20 mmol/L, subgroups Ib, IIb, and IIIb), magnesium ion (16 mmol/L, subgroups Ic, IIc, and IIIc), or potassium ion plus magnesium ion (subgroups Id, IId, and IIId) for 1 hour at 37 degrees C in group I or II, followed by washout for 45 minutes in group III (n = 8). Relaxation to bradykinin (groups I and III) or sodium nitroprusside (group II) in U(46619)-stimulated contraction was established. In the electrophysiologic study, the membrane potentials of single smooth muscle cells of arteries were measured by microelectrode after superfusion with the previously described solutions (subgroups IVa-IVc).

In group I, 20-mmol/L potassium ion greatly reduced the bradykinin-induced relaxation (35.0% +/- 4.9% vs 86.0% +/- 5.3%, P <.001), which was significantly restored by magnesium ion (51.9% +/- 4.0%, P =.017). In groups II and III, the bradykinin- or nitroprusside-induced relaxation had no significant differences. In group IV, potassium ion depolarized the smooth muscle and decreased the bradykinin-induced hyperpolarization (-72.0 +/- 1.5 vs -61.7 +/- 0.7 mV, n = 7, P <.001), which was significantly restored by magnesium ion (-68.0 +/- 2.5 mV vs -72.5 +/- 1.5 mV, n = 6, P =.029).

Magnesium ion, either alone or added to hyperkalemic solutions, preserves or helps to restore the endothelial function mediated by endothelium-derived hyperpolarizing factor. The mechanism is related to preservation of the membrane hyperpolarization and reversal of the potassium-induced membrane depolarization of the smooth muscle cell.

We have investigated and compared nitric oxide (NO) release and endothelium-derived hyperpolarizing factor (EDHF)-mediated hyperpolarization in the human internal mammary artery (IMA), radial artery (RA), saphenous vein (SV), and coronary artery.

Vessel segments taken from coronary artery bypass grafting or heart transplantation patients were placed in an organ chamber. NO-sensitive electrode or intracellular glass microelectrode was used to study NO or EDHF in response to acetylcholine (ACh) and bradykinin (BK).

The resting membrane potential of the smooth muscle cells of IMA, RA, and SV was -58 +/- 0.84 (n = 61), -61 +/- 1.3 mV (n = 46, p = 0.03), and -62 +/- 0.9 mV (n = 23, p = 0.0001) respectively. BK- (10(-7) M) induced EDHF-mediated hyperpolarization (-10.9 +/- 1.5 mV, n = 7) in the IMA was significantly greater than that in RA (-5.8 +/- 0.9 mV, n = 6, p = 0.04) and SV (-5.1 +/- 0.5 mV, n = 8, p < 0.01). The basal release of NO in IMA (16.8 +/- 1.9 nM) was significantly higher than that in RA (11.1 +/- 1.0 nM, n = 12, p = 0.02) and in SV (9.9 +/- 2.8 nM, n = 13, p < 0.001). The stimulated release of NO to BK in IMA was significantly greater than that in RA (44.3 +/- 4.0 vs 25.8 +/- 3.6 nM, n = 8, p = 0.004). The duration of NO release was longer in IMA than in RA or in SV.

The basal and stimulated release of NO and EDHF-mediated hyperpolarization in the IMA are significantly greater than that in the RA and SV. EDHF exists in all these human vessels. This study reveals the differences among human vessels regarding the endothelial function that have implications in vasospasm, coronary protection, or long-term graft patency.

Preservation and storage techniques represent two major issues in routine cardiac surgery and heart transplantation. Historically, these methods were conceived to prevent ischemic injury to myocardium after cardiac arrest during heart operations. Evidence shows that endothelium plays a critical role in the maintenance of normal heart function after cardiac operation, mainly by controlling the coronary circulation. Methods for preservation and storage, developed initially to protect cardiomyocyte function, may be deleterious for vascular endothelium and compromise myocardial protection. In this review article the present knowledge about endothelial injury secondary to preservation and storage techniques is discussed.

Endothelial cells derive nitric oxide, prostacyclin, and endothelium-derived hyperpolarizing factor (EDHF). The cytochrome P-450-monooxygenase metabolites of arachidonic acid (epoxyeicosatrienoic acids [EETs]) have been suggested to be EDHF. This study was designed to examine the effect of EET(11,12) with regard to the possibility of restoring EDHF function when added into hyperkalemic cardioplegic solution.

Porcine coronary microartery rings were studied in a myograph. In groups 1 and 2, paired arteries were incubated in either hyperkalemic solution (K+ 20 mmol/L) or Krebs' solution (control). In group 3, the paired arteries were incubated in hyperkalemia plus EET(11,12) (1 x 10(-6.5) mol/L) or hyperkalemia alone (control) at 37 degrees C for 1 hour, followed by Krebs' washout and then precontracted with 1 x 10(-8.5) mol/L U46619. The EDHF-mediated relaxation to EET(11,12) (group 1) or bradykinin (groups 2 and 3) was studied in the presence of N(G)-nitro-L-arginine, indomethacin, and oxyhemoglobin.

After exposure to hyperkalemia, the EDHF-mediated maximal relaxation by bradykinin (72.5% +/- 7.8% versus 41.6% +/- 10.6%; p < 0.05), but not by EET(11,12) (18.4% +/- 3.3% versus 25.1% +/- 4.9%; p > 0.05) was significantly reduced. Incubation with EET(11,12) partially restored EDHF function (33.3% +/- 9.5% versus 62.0% +/- 8.5%; p < 0.05).

In coronary microarteries, hyperkalemia impairs EDHF-mediated relaxation, and EET(11,12) may partially mimic the EDHF function. Addition of EET(11,12) into cardioplegic solution may partially restore EDHF-mediated function reduced by exposure to hyperkalemia.

We examined the effect of St Thomas' Hospital solution on endothelium-derived hyperpolarizing factor-mediated function in the porcine coronary microarteries with emphasis on the effect of temperature and washout time.

Microartery rings (diameter, 200-450 micrometers) were studied in myograph. The arteries were incubated in St Thomas' Hospital or Krebs solution (control) at 4 degrees C for 4 hours followed by 45 minutes (group Ia) or 90 minutes washout (group Ib) or at 22 degrees C for 1 hour followed by 45 minutes (group IIa) or 90 minutes washout (group IIb) and precontracted with -8.5 log M U 46619. The endothelium-derived hyperpolarizing factor-mediated relaxation to bradykinin was studied when endothelium-derived nitric oxide and prostaglandin I2 were inhibited with the presence of 7 micromol/L indomethacin and 300 micromol/L NG-nitro-L -arginine.

After exposure to St Thomas' Hospital solution, the maximal endothelium-derived hyperpolarizing factor-mediated relaxation (percentage of the precontraction) was significantly reduced at either temperature after washout for 45 minutes (group Ia, 42.7% +/- 3.5% vs 69.0% +/- 5.3%; n = 9; P =.000; and group IIa, 12.3% +/- 1.6% vs 56.1% +/- 4. 4%; n = 8; P =.000) but fully recovered after washout for 90 minutes. The U46619-induced contraction force was also significantly reduced after washout for 45 minutes (P <.001) but fully recovered at 90 minutes.

Under profound and moderate hypothermia, St Thomas' Hospital solution impairs endothelium-derived hyperpolarizing factor-mediated relaxation and smooth muscle contraction in the coronary microarteries. These effects exist during the reperfusion period for at least 45 minutes after exposure to St Thomas' Hospital solution and may account for the possible myocardial dysfunction during reperfusion.

University of Wisconsin solution is widely used to preserve organs for transplantation, but its effect on the individual endothelium-derived relaxing factors has not been studied. This study was designed to examine the effect of cold storage of the heart with University of Wisconsin solution on relaxation mediated by the endothelium-derived hyperpolarizing factor (EDHF).

Porcine coronary artery rings were studied in organ chambers. Relaxation in response to the EDHFs stimuli bradykinin and A23187 in U46619 (30 nmol/L)-induced precontraction after incubation with University of Wisconsin solution (either at 37 degrees C in the oxygenated organ chamber or at 4 degrees C in a refrigerator for 4 hours) was compared with the control.

During the incubation, the coronary tone initially increased transiently (4.8 +/- 0.8 gm) and was subsequently reduced by 10.9 +/- 1.2 gm. Under both normothermia and hypothermia, after the incubation, the relaxation mediated by EDHF significantly decreased (under normothermia: from 68.7% +/- 10.2% to 32.1% +/- 8%, n = 7, p = 0.001, for bradykinin and from 79.9% +/- 8.4% to 56.9% +/- 8.5%, n = 7, p = 0.01, for A23187; under hypothermia and hypoxia: to 18.9% +/- 5.6%, n = 9, p = 0.0005, for bradykinin and 52.7% +/- 7.5%, n = 9, p = 0.03, for A23187). The incubation at normothermia also impaired the coronary smooth muscle contractility to U46619, but this contractility was preserved by cold storage.

During cold storage, University of Wisconsin solution impairs the endothelium-dependent relaxation mediated by EDHF in the coronary circulation. This effect exists after the storage for at least 1 hour.

Hyperpolarizing cardioplegia has recently been proposed for myocardial protection. To compare the protective effect of hyperpolarizing cardioplegia and depolarizing (hyperkalemic) cardioplegia on coronary endothelium, we studied porcine coronary arteries in the organ chamber.

Relaxation mediated by the endothelium-derived hyperpolarizing factor (EDHF) was used as the index of endothelial function because (1) hyperkalemia without ischemia does not impair the nitric oxide-mediated function according to previous studies and (2) EDHF relaxes vessels by hyperpolarizing the membrane potential. Therefore depolarizing cardioplegia may inhibit this function, but hyperpolarizing cardioplegia may preserve it. EDHF-mediated relaxation was induced by bradykinin and the calcium ionophore A23187 with the presence of indomethacin (7 micromol/L; INN: indometacin), a cyclooxygenase inhibitor, and N(G)-nitro-L-arginine (300 micromol), a nitric oxide biosynthesis inhibitor in U46619 (30 nmol/L)-induced precontraction. The vessels were exposed to either hyperpolarizing cardioplegic solution (the potassium-channel opener aprikalim, 0.1 mmol/L) or depolarizing cardioplegic solution (high potassium concentration, 20 mmol/L for A23187 and 50 mmol/L for bradykinin experiments) for 1 hour with a constant supply of oxygen to exclude the effect of ischemia.

EDHF-mediated relaxation was significantly impaired in either A23187 or bradykinin studies (80.1% +/- 7.5% vs 24.9% +/- 14.2%, p = 0.004, n = 8 in each group for A23187, and 71.4% +/- 4.7%, n = 13, vs 40.5% +/- 12.9%, n = 7, p = 0.01, for bradykinin). The effective concentration causing 50% of maximal relaxation was significantly increased in the A23187 experiments with the treatment of hyperkalemia. In contrast, in aprikalim-treated arteries, the EDHF-mediated relaxation induced by either A23187 or bradykinin was unchanged.

We conclude that EDHF-mediated coronary endothelial function is maximally preserved by hyperpolarizing cardioplegia but impaired by depolarizing cardioplegia. These findings support the use of hyperpolarizing cardioplegia in cardiac operations.