Gillian A. Geffin

Relation between ionized calcium concentration and ventricular pump performance in the dog under hemodynamically controlled conditions

The effect of plasma ionized calcium concentration on left ventricular function was studied in the canine heart on right heart bypass. Stroke volume, mean arterial pressure and heart rate were controlled. Plasma ionized calcium was lowered to 0.58 +/- 0.01 mM by citrate infusion and raised to 1.70 +/- 0.01 mM by calcium chloride infusion in random order in each dog. Left ventricular function at each of these ionized calcium levels was compared with that in an immediately preceding normocalcemic period. At a constant stroke work (16.9 +/- 0.2 g-m), sustained hypercalcemia was associated with a small decrease in left ventricular end-diastolic pressure (1.7 +/- 0.7 cm H2O, p less than 0.05) despite a marked increase in peak left ventricular dP/dt (first derivative of ventricular pressure) averaging 34 percent (p less than 0.001). Coronary blood flow, tension-time index and myocardial oxygen consumption were not significantly altered. Stroke work determined at a left ventricular end-diastolic pressure of 14 cm H2O, by interpolation in left ventricular function curves, was 11 +/- 4.4 percent above that at control normocalcemia (p less than 0.05). At a constant stroke work (16.9 +/- 0.2 g-m), sustained hypocalcemia was associated with a marked depression of left ventricular function as demonstrated by a substantial increase (from 4.9 +/- 0.3 to 12.7 +/- 1.1 cm H2O, p less than 0.0001) in left ventricular end-diastolic pressure (p less than 0.0001), decreased mean systolic ejection rate (p less than 0.01) and decreased peak left ventricular dP/dt (p less than 0.0001). Coronary blood flow increased (p less than 0.05) whereas myocardial oxygen consumption did not change significantly. A marked displacement of left ventricular function curves to the right (compared with curves obtained during normocalcemia) was observed, and stroke work determined at a left ventricular end-diastolic pressure of 14 cm H2O was 52 +/- 5.4 percent below control level (p less than 0.001). It appears that hypercalcemia, when initiated from a normal control level, provides only a small enhancement of ventricular pump performance (as indexed by the stroke work-left ventricular end-diastolic pressure relation) despite a marked increase in peak left ventricular dP/dt, whereas marked improvement of left ventricular performance may be expected when calcium infusion is initiated from an ionized calcium level that is below normal.

The Superiority of Cold Oxygenated Dilute Blood Cardioplegia

It has been clearly shown, both in a laboratory model and in humans, that oxygenation of crystalloid cardioplegic solutions markedly enhances myocardial preservation. The addition of a small volume of red cells to a crystalloid perfusate improves capillary perfusion. Based on these results, we have changed our cardioplegic solution from cold crystalloid to cold oxygenated dilute blood. In the present study we retrospectively evaluate the results of 400 operative procedures to determine whether the addition of oxygenation and a small volume of blood to the cardioplegic solution enhances myocardial protection in the clinical setting. Two hundred consecutive patients who underwent operation with cardioplegic arrest using a cold crystalloid cardioplegic solution (group 1) were compared with a subsequent 200 patients who underwent operation with cold oxygenated dilute blood cardioplegia (group 2). Patients in group 2, who received cold oxygenated dilute blood cardioplegia, had a significantly reduced need for postoperative intraaortic balloon pump counterpulsation and for atrioventricular pacing. Also, patients in group 2 had a lower incidence of perioperative myocardial infarction and had improved early outcome. None of the 200 patients in group 2 had electrocardiographic evidence of perioperative infarction. We conclude that cold oxygenated dilute blood cardioplegia provides better preservation than does a nonoxygenated crystalloid solution during elective ischemic arrest, because a cold crystalloid solution is able to deliver oxygen and the red cells are able to enhance capillary perfusion.

Rapid cooling contracture with cold cardioplegia

BACKGROUND Cold cardioplegia can induce rapid cooling contracture. The relations of cardioplegia-induced cooling contracture to myocardial temperature or myocyte calcium are unknown. METHODS Twelve crystalloid-perfused isovolumic rat hearts received three 2-minute cardioplegic infusions (1 mmol/L calcium) at 4 degrees, 20 degrees, and 37 degrees C in random order, each followed by 10 minutes of beating at 37 degrees C. Finally, warm induction of arrest by a 1-minute cardioplegic infusion at 37 degrees C was followed by a 1-minute infusion at 4 degrees C. Indo-1 was used to measure the intracellular Ca2+ concentration in 6 of these hearts. Additional hearts received hypoxic, glucose-free cardioplegia at 4 degrees or 37 degrees C. RESULTS After 1 minute of cardioplegia at 4 degrees, 20 degrees, and 37 degrees C, left ventricular developed pressure rose rapidly to 54% +/- 3%, 43% +/- 3%, and 18% +/- 1% of its prearrest value, whereas the intracellular Ca2+ concentration reached 166% +/- 23%, 94% +/- 4%, and 37% +/- 10% of its prearrest transient. Coronary flow was 5.7 +/- 0.2, 8.7 +/- 0.3, and 12.6 +/- 0.6 mL/min, respectively. Warm cardioplegia induction at 37 degrees C reduced left ventricular developed pressure and [Ca2+]i during subsequent 4 degrees C cardioplegia by 16% (p = 0.001) and 34% (p = 0.03), respectively. Adenosine triphosphate and phosphocreatine contents were lower after 4 degrees C than after 37 degrees C hypoxic, glucose-free cardioplegia. CONCLUSIONS Rapid cooling during cardioplegia increases left ventricular pressure, [Ca2+]i and coronary resistance, and is energy consuming. The absence of rapid cooling contracture may be a benefit of warm heart operations and warm induction of cardioplegic arrest.

Myocardial preservation related to magnesium content of hyperkalemic cardioplegic solutions at 8 °C

Abstract This study investigates whether the addition of magnesium to a hyperkalemic cardioplegic solution containing 0.1 mM ionized calcium improves myocardial preservation, and whether there is an optimal magnesium concentration in this solution. Isolated perfused rat hearts were arrested for two hours by this cardioplegic solution, which was fully oxygenated and infused at 8 °C every 15 minutes to simulate clinical conditions. The cardioplegic solution contained either 0, 2, 4, 8, 16, or 32 mM magnesium. At end-arrest, the myocardial creatine phosphate concentration (nanomoles per milligram of dry weight) was 20.7 ± 2.1, 22.9 ± 1.7, 24.8 ± 2.0, 31.3 ± 1.4, 33.1 ± 1.8, and 31.6 ± 0.8, respectively, in hearts given cardioplegic solution containing these magnesium concentrations. Thus, the concentration of creatine phosphate was significantly higher at end-arrest when the cardioplegic solution contained 8, 16, or 32 mM than 0 or 2 mM magnesium ( p p p

Oxygenated cardioplegia: The metabolic and functional effects of glucose and insulin

Reports differ as to the efficacy of glucose and insulin as cardioplegic additives. Although deliberate oxygenation of crystalloid cardioplegic solutions improves myocardial protection, little is known about the protection afforded by glucose and insulin in such oxygenated solutions. In the isolated working rat heart, we studied the addition of oxygen, glucose, and insulin, separately and together, to a cardioplegic solution. The solution was equilibrated with O2 or N2, with glucose added as a substrate or sucrose as a nonmetabolizable osmotic control, with or without insulin. Hearts were arrested for 2 hours at 8 degrees C by multidose infusions. Oxygenation decreased lactate production and improved high-energy phosphate and glycogen preservation during arrest, prevented ischemic contracture, and improved functional recovery. The addition of glucose to the oxygenated solution increased the level of adenosine triphosphate at end-arrest from 10.5 +/- 0.5 to 13.9 +/- 0.6 nmol/mg dry weight and glycogen stores from 18.7 +/- 2.5 to 35.7 +/- 5.5 nmol/mg dry weight. The further addition of insulin did not better preserve these metabolites. Improvements in functional recovery due to glucose or insulin in the oxygenated solution attained statistical significance when both additives were included. Glucose increased lactate production significantly only when the solution was nitrogenated. Insulin added to the nitrogenated glucose-containing solution increased adenosine triphosphate and glycogen levels after 1 hour of arrest; and, although insulin did not prevent ischemic contracture from developing during the latter part of arrest with profound depletion of these metabolites, functional recovery was improved. The mechanism of improved functional recovery by insulin is not clear.(ABSTRACT TRUNCATED AT 250 WORDS)

Relation of myocardial protection to cardioplegic solution pH: Modulation by calcium and magnesium

The relationship between myocardial preservation and cardioplegic solution pH was assessed in isolated, perfused rat hearts. A base solution without calcium or magnesium and the same solution containing 0.2 mmol/L ionized calcium or 16 mmol/L magnesium or both ions were studied at several values of pH between 6.8 and 8.7. Hearts were arrested at 8 degrees C by multidose infusions of these bicarbonate-buffered solutions bubbled with oxygen and a varying percentage of carbon dioxide to control pH. Diastolic tone (left ventricular balloon) and adenosine triphosphate (ATP) depletion during arrest both increased as the cardioplegic solution became more alkaline. Calcium increased these effects of pH. Magnesium weakened the effect of pH on diastolic tone, maintained ATP at all pH levels, and inhibited the effects of calcium on the relationships of pH to diastolic tone and ATP. When data from all solutions were considered together, ATP depletion was shown to be linearly related to diastolic tone. Calcium depressed functional recovery (left ventricular developed pressure during reperfusion expressed as a percentage of its prearrest value) at all pH levels. With the other solutions, recovery was similar and best within a broad and relatively alkaline pH range. With the solution containing calcium and magnesium, at pH levels of 8.28 +/- 0.02, 7.87 +/- 0.03, 7.58 +/- 0.02, 7.41 +/- 0.01, 7.06 +/- 0.02, and 6.80 +/- 0.01, recovery at 5 minutes of reperfusion was 101.4% +/- 3.7%, 102.9% +/- 2.8%, 107.3% +/- 3.7%, 102.8% +/- 2.9%, 91.8% +/- 3.6%, and 94.3% +/- 3.5%, respectively. This effect of alkalinity was short-lived. Extreme alkalinity of the base, acalcemic solution produced the calcium paradox, as reported previously. Good preservation of ATP by the most acid solutions did not predict good functional recovery. Magnesium increased the persistence of frequent extrasystoles during early reperfusion, but the effect was attenuated by calcium. The data support the inclusion of magnesium in cardioplegic solutions, particularly when they contain calcium, show that cardioplegic solution pH can have major effects on the arrested heart, and suggest that a relatively alkaline pH may modestly benefit functional recovery.

Cardioplegia and ischemia in the canine heart evaluated by 31P magnetic resonance spectroscopy

BACKGROUND Warm continuous blood cardioplegia provides excellent protection, but must be interrupted by ischemic intervals to aid visualization. We hypothesized that (1) as ischemia is prolonged, the reduced metabolic rate offered by cooling gives the advantage to hypothermic cardioplegia; and (2) prior cardioplegia mitigates the deleterious effects of normothermic ischemia. METHODS Isolated cross-perfused canine hearts underwent cardioplegic arrest followed by 45 minutes of global ischemia at 10 degrees C or 37 degrees C, or 45 minutes of normothermic ischemia without prior cardioplegia. Left ventricular function was measured at baseline and during 2 hours of recovery. Metabolism was continuously evaluated by phosphorus-31 magnetic resonance spectroscopy. RESULTS Adenosine triphosphate was 71% +/- 4%, 71% +/- 7%, and 38% +/- 5% of baseline at 30 minutes, and 71% +/- 4%, 48% +/- 5%, and 39% +/- 6% at 42 minutes of ischemia in the cold ischemia, warm ischemia, and normothermic ischemia without prior cardioplegia groups, respectively. Left ventricular systolic function, left ventricular relaxation, and high-energy phosphate levels recovered fully after cold cardioplegia and ischemia. Prior cardioplegia delayed the decline in intracellular pH during normothermic ischemia initially by 9 minutes, and better preserved left ventricular relaxation during recovery, but did not ameliorate the severe postischemic impairment of left ventricular systolic function, marked adenosine triphosphate depletion, and creatine phosphate increase. Left ventricular distensibility decreased in all groups. CONCLUSIONS When cardioplegia is followed by prolonged ischemia, better protection is provided by hypothermia than by normothermia. Prior cardioplegia confers little advantage on recovery after prolonged normothermic ischemia but delays initial ischemic metabolic deterioration, which would contribute to the safety of brief interruptions of warm cardioplegia.

Protection of the hypertrophied myocardium by crystalloid cardioplegia.

Patients with left ventricular hypertrophy (LVH) have a worse outcome after cardiac surgery than those without hypertrophy. We studied protection of hearts with LVH in an isolated rat heart model using multidose, cold, oxygenated cardioplegia. LVH was produced by banding the abdominal aorta in young rats. Six weeks after banding, this produced a 31% increase in the left ventricular dry weight/body weight ratio compared to two age-matched control groups comprising sham-operated and nonoperated animals. The recovery of cardiac output after arrest was higher in LVH (82 +/- 4% of prearrest) than in sham-operated (69 +/- 4%) or nonoperated (66 +/- 3%) control groups. The improved functional recovery in LVH occurred although there were no differences among the groups in myocardial adenosine triphosphate (ATP) and phosphocreatine (PCr) prior to arrest, at the end of arrest, or after reperfusion. Glycogen levels were also similar among the three groups prior to arrest and after reperfusion but were highest in LVH after arrest. Myocardial oxygen consumption (MVO2) and efficiency, expressed as cardiac output/MVO2, were similar among the groups prior to arrest. Myocardial efficiency after reperfusion declined in all groups but was best preserved in LVH. We also compared the sensitivity of hypertrophied and control hearts to the deleterious effects of calcium in cardioplegia. Calcium in the cardioplegia increased myocardial lactate production during arrest in a dose-related fashion and depressed myocardial levels of ATP, PCr, and glycogen at end arrest in all groups. Cardiac output recovery was also depressed by calcium but was still best in LVH. We conclude that the hypertrophied myocardium is well protected by standard cardioplegia and that calcium in cardioplegia does not preferentially depress recovery in LVH.

Maximal Oxygenation of Dilute Blood Cardioplegic Solution

Abstract The content of dissolved O 2 (the major source of O 2 far the myocardium) of dilute blood cardioplegic solution (dBCS) varied widely when oxygenated at 4 °C by surface flow of O 2 in a Bentley BCR-3500 cardiotomy reservoir. We have modified the system to consistently deliver maximally oxygenated dBCS to the heart. Laboratory studies indicated that bubbling O 2 through a 16-gauge intravenous catheter in a central Luer-Lok port of the cardiotomy reservoir provided contents of dissolved O 2 that were consistently near maximal. We then studied 17 patients in the operating room. The first 6 patients received dBCS oxygenated with 100% O 2 with a high dissolved O 2 content of 3.2 ± 0.2 ml/dl. However, the pH of the dBCS became highly alkaline (7.83 ± 0.11 at 37 °C). Therefore, in the remaining 11 patients, 2% CO 2 was added to the O 2 . The dissolved O 2 content remained high (3.3 ± 0.1 ml/dl), and the pH was in a more physiological range (7.35 ± 0.09 at 37 °C). We conclude that consistently maximal oxygenation of a dBCS at a more physiological pH can be achieved by this method.

Pulmonary Vascular Responses to Hypercalcemia and Hypocalcemia in the Dog

The pulmonary artery responses in the isolated whole-blood perfused canine lung to ionized calcium ([Ca++]) were quantified over a range of hypercalcemia and hypocalcemia values ([Ca++] = 0.23-1.88 mM) under conditions of controlled pulmonary blood flow and constant mean aortic and left atrial pressures. Calcium chloride, administered as bolus doses in the clinical range (5-15 mg.kg-1) at initial normocalcemia and without interventions producing vasoconstriction did not influence mean pulmonary artery pressure at constant pulmonary blood flow. Stable hypercalcemia ([Ca++] = 1.88 +/- 0.05 mM) did not influence the slope of the pulmonary artery pressure-flow plot. Because normal pulmonary vasomotor tone is low and cannot readily be lowered further, the possible vasodilator action of hypocalcemia was assessed by its ability to decrease the slope of the mean pulmonary artery pressure-flow plot, which had been first increased by alveolar hypoxia (AHX) or infusion of the prostaglandin endoperoxide analog U46619 (PG). During AHX (n = 5), a graded reduction from normocalcemia ([Ca++] = 1.08 +/- 0.02 mM) to moderate hypocalcemia ([Ca++] = 0.8 and 0.5 mM) did not alter the pulmonary artery pressure-flow plot, but severe hypocalcemia ([Ca++] = 0.26 +/- 0.01 mM) decreased the slope by 13 +/- 0.9 mmHg.l-1.min-1. The comparison of severe hypocalcemia ([Ca++] = 0.23-0.27 mM) versus a high dose of nifedipine (bolus of 10 micrograms/kg followed by continuous infusion at 40 micrograms.kg-1.h-1) on pulmonary vascular tone increased by either AHX or PG infusion indicated that both hypocalcemia and nifedipine decreased the slope of the relationship between mean pulmonary artery pressure and flow (during AHX: -16.1 +/- 1.38 and -23.3 +/- 1.73 mmHg.l-1.min-1, both P = 0.0001 vs. AHX alone, and during PG: -17.05 +/- 1.95 and -8.4 +/- 1.78 mmHg.l-1.min-1, P = 0.0001 vs. PG alone). Two principal conclusions emerge. First, the pulmonary vessels are minimally sensitive to changes in ionized calcium throughout the clinical hypercalcemia and hypocalcemia ranges; extreme hypocalcemia is required to produce vasodilation, which was reversed with calcium infusion. Second, whereas the pulmonary vasodilator effects of extreme hypocalcemia were independent of the intervention inducing pulmonary vasoconstriction (AHX vs. PG), those of nifedipine were much more pronounced with AHX.