Is early decline of cardiac function in ischaemia due to carbon-dioxide retention?

Association between mortality and serum uric acid levels in non-diabetes-related chronic kidney disease: An analysis of the National Health and Nutrition Examination Survey, USA, 1999-2010

The relationship between serum uric acid (SUA) and cardiovascular (CV) mortality in patients with chronic kidney disease (CKD) has been described as either a J- or U-shaped function. However, its effect in non-diabetic CKD (and varying severities of CKD) remains unclear. We analyzed the database of the National Health and Nutrition Examination Survey, USA, from the years 1999 to 2010. We then grouped the subjects into 4 categories according to their SUA levels: (a) < 5 mg/dl, (b) 5-7 mg/dl, (c) 7-9 mg/dl and (d) ≥ 9 mg/dl. For mortality comparison purposes (CV related, cancer related and all-cause mortality), we set the SUA group of 5-7 mg/dl as the reference. We also separated this population into moderate (stage 3) and severe (stages 4 and 5) CKD. A total of 1860 participants were included in this study. Results showed that the group with the lowest SUA levels (< 5 mg/dl), were the least male gender (19.25%), had the lowest body mass index (26.41(95% CI = 25.66-27.16) kg/m2), highest systolic blood pressure (139.02 (95% CI 135.72-142.32) mmHg), highest high-density cholesterol (59.55 (95% CI 57.37-61.74) mg/dl), lowest blood glucose (95.46 (95% CI 93.16-97.76) mg/dl), highest total cholesterol (210.31 (95% CI 203.36-217.25) mg/dl), lowest serum albumin (4.09 (95% CI 4.04-4.14) g/dl), highest estimated glomerular filtration rate (eGFR) (47.91 (95% CI 45.45-50.49) ml/min/1.732m2), least history of hypertension (54.4%), and least total energy intake (1643.7 (95% CI 1536.13-1751.27) kcal/day). In the group with SUA ≥ 9 mg/dl, patients had higher all-cause mortality (HR = 2.15) whatever their baseline CVD status. In non-DM CKD patients with a CVD history, the group with SUA ≥ 9 mg/dl had the highest all-cause mortality (HR = 5.39), CVD mortality (HR = 8.18) and CVD or cancer (HR = 8.25) related mortality. In non-DM patients with severe CKD (eGFR < 30 ml/min/1.732m2), the group with SUA < 5 had a significantly increased all-cause mortality. On the contrary, in non-DM patients with moderate CKD (eGFR = 30-60 ml/min/1.832m2), the group with SUA ≥ 9 had a significantly increased all-cause mortality. In moderate non-DM CKD, SUA ≥ 9 mg/dl is associated with higher all-cause mortality. However, once progressing to severe non-DM CKD, SUA < 5 mg/dl is associated with higher all-cause mortality (even though it has the least risk factors for metabolic syndrome).

A review of ventilation in adult out-of-hospital cardiac arrest

Out-of-hospital cardiac arrest continues to be a devastating condition despite advances in resuscitation care. Ensuring effective gas exchange must be weighed against the negative impact hyperventilation can have on cardiac physiology and survival. The goals of this narrative review are to evaluate the available evidence regarding the role of ventilation in out-of-hospital cardiac arrest resuscitation and to provide recommendations for future directions. Ensuring successful airway patency is fundamental for effective ventilation. The airway management approach should be based on professional skill level and the situation faced by rescuers. Evidence has explored the influence of different ventilation rates, tidal volumes, and strategies during out-of-hospital cardiac arrest; however, other modifiable factors affecting out-of-hospital cardiac arrest ventilation have limited supporting data. Researchers have begun to explore the impact of ventilation in adult out-of-hospital cardiac arrest outcomes, further stressing its importance in cardiac arrest resuscitation management. Capnography and thoracic impedance signals are used to measure ventilation rate, although these strategies have limitations. Existing technology fails to reliably measure real-time clinical ventilation data, thereby limiting the ability to investigate optimal ventilation management. An essential step in advancing cardiac arrest care will be to develop techniques to accurately and reliably measure ventilation parameters. These devices should allow for immediate feedback for out-of-hospital practitioners, in a similar way to chest compression feedback. Once developed, new strategies can be established to guide out-of-hospital personnel on optimal ventilation practices.

Acidosis and contractility of heart muscle

The contractility of heart muscle is sensitive to small and physiological changes of extracellular pH. The reduction of contractility associated with an acidosis is determined by the fall of pH in the intracellular fluid. The function of many organelles within the cardiac cell is affected by hydrogen ions. The tension generated by isolated myofibrils at a fixed calcium concentration is reduced at low pH. The dominant mechanism for the reduction of contractility in whole tissue is competitive inhibition of the slow calcium current by hydrogen ions. The reduction of the slow calcium current is similar when the same fall of developed tension is induced by acidosis or by a reduction of extracellular calcium concentration. Measurement of tissue pH with fast-responding extracellular electrodes show that, in myocardial ischaemia, tissue acidosis develops at the same time or only seconds before the onset of contractile failure. Much of the reduced contractility can be accounted for by the severity of the acidosis. Although a mild acidosis can delay or prevent damage to the myocardium from ischaemia or hypoxia, a severe acidosis is not beneficial and may even cause tissue necrosis.

Use of base in the treatment of severe acidemic states

Severe acidemia (blood pH < 7.1 to 7.2) suppresses myocardial contractility, predisposes to cardiac arrhythmias, causes venoconstriction, and can decrease total peripheral vascular resistance and blood pressure, reduce hepatic blood flow, and impair oxygen delivery. These alterations in organ function can contribute to increased morbidity and mortality. Although it seemed logical to administer sodium bicarbonate to attenuate acidemia and therefore lessen the impact on cardiac function, the routine use of bicarbonate in the treatment of the most common causes of severe acidemia, diabetic ketoacidosis, lactic acidosis, and cardiac arrest, has been an issue of great controversy. Studies of animals and patients with these disorders have reported conflicting data on the benefits of bicarbonate, showing both beneficial and detrimental effects. Alternative alkalinizing agents, tris-hydroxymethyl aminomethane and Carbicarb, have shown some promise in studies of animals and humans, and reevaluation of these buffers in the treatment of severe acidemic states seems warranted. The potential value of base therapy in the treatment of severe acidemia remains an important issue, and further studies are required to determine which patients should be administered base therapy and what base should be used.

Effect of NaHCO3 on cardiac energy metabolism and contractile function during hypoxemia

OBJECTIVE

To examine the impact of administration of NaHCO3 on contractility and energy metabolism of the myocardium during hypoxemia.

METHODS

Regional myocardial hypoxia was induced in the left anterior descending (LAD) artery myocardium in anesthetized, open-chest dogs, using a perfusion circuit between the right atrium and the LAD artery, and a membrane oxygenator. The rate of flow in LAD artery was maintained constant with the use of a roller pump. During hypoxia, eight dogs were administered isotonic NaHCO3 in the circuit and six other dogs received equimolar NaCl. Myocardial contractile function was assessed using sonomicrometry for measurement of percentage of systolic shortening and preload recruitable stroke work. Oxygen consumption and the rate of appearance of lactate were measured. Clamp-frozen tissue samples were obtained at the end of the experiment from the hypoxic LAD myocardium and the nonhypoxic circumflex myocardium for measurement of tissue lactate level.

RESULTS

During hypoxia, there was a significant decrease in oxygen consumption by the LAD myocardium (35 +/- 7 micromol/min in the NaCl group and 40 +/- 7 micromol/min in the NaHCO3 group during hypoxia vs. 131 +/- 11 micromol/min during aerobic perfusion). There was also a significant decrease in myocardial contractility as measured by percentage of systolic shortening (14 +/- 3% to -8 +/- 3%); NaHCO3 infusion during hypoxia did not improve myocardial contractility (-7 +/- 2%). Similar results were obtained with measurements of preload recruitable stroke work. The rate of production of lactate during hypoxia was substantially lower than expected, based on the calculated oxygen deficit, and was not significantly increased by the administration of NaHCO3 (33 +/- 9 micromol/min in the NaCl group and 51 +/- 5 micromol/min in the NaHCO3 group). Tissue lactate was not statistically different in the hypoxic myocardium supplied by the LAD artery and the nonhypoxic myocardium supplied by the circumflex artery in either group.

CONCLUSION

The response of the myocardium to hypoxia is to decrease its mechanical work and metabolic demand. The infusion of NaHCO3 did not enhance myocardial contractile function or flux in glycolysis during hypoxia. We speculate that this diminished mechanical work and metabolic demand may represent an adaptive response to preserve cellular integrity until oxygen delivery is restored.

Essential role of the beta subunit in modulation of C-class L-type Ca2+ channels by intracellular pH

Elevation of intracellular pH (pHi) enhances the activity of native L-type Ca2+ channels in cardiac and smooth muscle. We studied the modulation by pHi of expressed L-type Ca2+ channels comprised of either the alpha1c subunits alone or of alpha1c plus beta2a subunits. Ca2+ channels were expressed in human embryonic kidney cells (HEK 293) and pHi was increased from a basal level of 7.3 to 8.3 by exposure of cells to NH4Cl (20 mM) or by elevation of extracellular pH to 8.5. Elevation of pHi enhanced the activity of Ca2+ channels derived by coexpression of alpah1c and beta2a subunits. This alkalosis-induced stimulation of channel activity was mainly due to an increase in channel availability. Channels derived by expression of alpha1c alone were not affected by intracellular alkalosis. Our results demonstrate that the pHi sensitivity of L-type Ca2+ channels is conferred by the beta subunit of the channel complex.

Effect of ventilation on resuscitation in an animal model of cardiac arrest

BACKGROUND

The need for ventilation during the initial management of cardiac arrest is an important public health problem that is being debated. The present study was designed to determine whether ventilation affects return of spontaneous circulation from cardiac arrest in a swine model with an interval of untreated ventricular fibrillation of 6 minutes, as reported in witnessed out-of-hospital human cardiac arrest.

METHODS AND RESULTS

Twenty-four animals were randomly assigned to two groups: one that received ventilation during the first 10 minutes of chest compression and one that did not. Coronary perfusion pressure and minute ventilation were continuously recorded. Arterial and mixed venous blood gases were measured at intervals. Return of spontaneous circulation was defined prospectively as an aortic systolic blood pressure of > 80 mm Hg for > 5 minutes and was the primary outcome variable. All animals were anesthetized, paralyzed, and intubated. Ventricular fibrillation was induced and persisted for 6 minutes without chest compression, followed by mechanical chest compression for 10 minutes and then attempted defibrillation. Animals without return of spontaneous circulation were given epinephrine, ventilation, and chest compression for an additional 3 minutes. Defibrillation was again attempted, and animals were assessed for return of spontaneous circulation. There were no significant differences between the two groups in baseline prearrest mean cardiac index, coronary perfusion pressure, or arterial and mixed venous blood gases. However, after 9 minutes of chest compression, significant differences were noted between the ventilated and nonventilated groups. The nonventilated group had significantly (P < .05) lower mean arterial PO2 (38 +/- 17 mm Hg compared with 216 +/- 104 mm Hg) and higher PCO2 (62 +/- 16 mm Hg compared with 35 +/- 8 mm Hg), lower mixed venous PO2 (15 +/- 7 mm Hg compared with 60 +/- 7 mm Hg). Nine of 12 (75%) of the ventilated animals, and only 1 of 12 (8%) of the nonventilated animals had return of spontaneous circulation after cardiac arrest (P < .002).

CONCLUSIONS

In this animal model of cardiac arrest, ventilation was important for resuscitation. The importance of ventilation could be related to the prolonged duration of untreated ventricular fibrillation and the significantly greater hypoxia and hypercarbic acidosis found in the nonventilated animals.

Acid base changes in arterial and central venous blood during cardiopulmonary resuscitation

Twenty-seven patients in cardiopulmonary arrest had simultaneous measurements of arterial and central venous blood gases during cardiopulmonary resuscitation (CPR) with a pneumatic chest comparison and ventilation device. Mean central venous and arterial hydrogen ion concentrations, PCO2 and calculated bicarbonate concentrations were significantly different (P less than 0.01) at all sampling times (0, 10 and 20 min). Central venous blood samples predominantly showed a respiratory acidosis in contrast to a mixed disturbance in arterial samples inclined towards a metabolic acidosis. The mean difference between central venous PCO2 (pcv CO2) and arterial PCO2 (pa CO2) ranged from 5.18 to 5.83 kPa reflecting the low blood flow in patients undergoing CPR. Measurement of arterial Po2 indicated adequate oxygenation using the pneumatic device. Arterial blood gas analysis alone does not reflect tissue acid base status. Bicarbonate administration during CPR may have adverse effects and any decision as to its use should be based on central venous blood gas estimations.

Cardiac effects of carbon dioxide-consuming and carbon dioxide-generating buffers during cardiopulmonary resuscitation

Recent studies have demonstrated an increase in carbon dioxide (CO2) tension (PCO2) in both mixed venous and coronary vein blood early in the course of cardiac arrest and cardiopulmonary resuscitation. Because increased PCO2 in the myocardium correlates with both ischemic injury and depression of contractile function, the effects of hypertonic solutions of either the CO2-"generating" sodium bicarbonate (NaHCO3) buffer, a mixture of sodium carbonate (Na2CO3) and sodium bicarbonate (carbicarb) acting as a CO2-"consuming" buffer, or saline placebo (NaCl) were compared during cardiopulmonary resuscitation in 25 healthy minipigs. Both buffer agents significantly increased the pH and HCO3- of arterial, mixed venous and coronary vein blood. Bicarbonate increased whereas carbicarb reduced blood PCO2 in the systemic circuit as anticipated. However, neither the PCO2 nor the lactate content of coronary vein blood was favorably altered by buffer therapy. Four of eight animals treated with bicarbonate, five of eight treated with carbicarb and six of nine placebo-treated animals were successfully resuscitated and had a comparable 24 h survival rate. Coronary perfusion pressure during precordial compression, a critical determinant of resuscitability, was transiently decreased by each of the hypertonic solutions. Accordingly, neither CO2-generating nor CO2-consuming buffers mitigated increases in coronary vein PCO2 or improved the outcome of cardiopulmonary resuscitation under these experimental conditions.

Selective venous hypercarbia during human CPR: implications regarding blood flow

Thirty-five patients presenting to the emergency department in cardiopulmonary arrest had simultaneous measurement of central venous (cv) and arterial (a) blood gases during CPR with a pneumatic chest compressor and ventilator. The mean cv, arterial pH, and PCO2 values were markedly different (P less than .001). The mean pH gradient (pHa - pHcv) was .31 +/- .10 units and the mean PCO2 gradient (PcvCO2 - PaCO2) was 60.5 +/- 23.6 torr. This selective venous hypercarbia is probably due to a cardiac output that is inadequate to eliminate the CO2 produced from both residual aerobic metabolism and the buffering of anaerobically produced lactic acid. Central venous blood gases are probably a better reflection of actual tissue environment during prolonged cardiac arrest than are arterial blood gases.

The relationships of high energy phosphates, tissue pH, and regional blood flow to diastolic distensibility in the ischemic dog myocardium

Myocardial ischemia due to increased oxygen demand (pacing tachycardia plus critical coronary stenoses) alters diastolic distensibility and relaxation more than ischemia of comparable duration due to coronary occlusion. To investigate the relationship between myocardial diastolic function and metabolism, we compared myocardial high energy phosphate content, tissue pH, and regional blood flow for these two types of ischemia in anesthetized open-chest dogs. Myocardial biopsies were done with a high-speed air-turbine biopsy drill, permitting rapid (less than 1-second) freezing of tissue samples from both nonischemic and ischemic areas, while myocardial pH was measured with a hydrogen ion-selective polymer membrane implanted in the subendocardium. After 3 minutes of pacing tachycardia in dogs with critical coronary stenoses (demand-type ischemia, n = 14), regional systolic function (% segment shortening by ultrasonic crystals) was mildly depressed (from 19 +/- 2% control to 13 +/- 2% post-pacing, P less than 0.01), while left ventricular diastolic pressure-segment length relations shifted upward, indicating decreased distensibility of the ischemic myocardial segment. Associated with these changes in function, subendocardial adenosine triphosphate decreased (from 31.3 +/- 1.5 to 27.9 +/- 1.0 nmol/mg protein, P less than 0.01), as did creatine phosphate (53.8 +/- 2.1 to 39.6 +/- 2.5 nmol/mg protein, P less than 0.01), while myocardial pH declined slightly (delta pH = -0.14 +/- 0.02, P less than 0.01). In contrast, at 3 minutes of coronary artery occlusion (primary ischemia, n = 14), regional segment shortening was replaced by systolic bulging (% shortening decreased from 17 +/- 2% to -2 +/- 1% during occlusion, P less than 0.01), while left ventricular pressure-segment length relations were not shifted upward, and there was no decrease in diastolic distensibility of the ischemic segment. With coronary artery occlusion, subendocardial adenosine triphosphate declined slightly (33.2 +/- 0.5 to 29.2 +/- 2.0 nmol/mg, P less than 0.05), while creatine phosphate decreased substantially (51.1 +/- 2.3 to 7.8 +/- 1.4 nmol/mg protein, P less than 0.01). Myocardial pH fell strikingly (delta pH = -0.33 +/- 0.03, P less than 0.01), and the decline was 236% of that seen with demand-type ischemia. Regional myocardial blood flow (microsphere technique) showed a decreased endocardial:epicardial (endo:epi) ratio (1.04 +/- 0.04 control vs. 0.40 +/- 0.05 during pacing, P less than 0.01) and absolute subendocardial flow (1.02 +/- 0.47 to 0.47 +/- 0.05 ml/min per g, P less than 0.01) with demand-type ischemia.(ABSTRACT TRUNCATED AT 400 WORDS)

Cyclic AMP and early contractile failure

Cyclic AMP was measured in the isolated rat heart during anoxia in an attempt to demonstrate if this nucleotide is in any way related to the extent and rate of contractile failure. Isolated rat hearts were subjected to 15 min of normoxia followed by periods of between 1 and 300 sec of anoxia. Contractile force and its failure were monitored throughout. Tissue samples were obtained at various times using high-speed freeze-clamping techniques, and the frozen samples were taken for extraction and cAMP analysis. The results showed a significant increase in the levels of cAMP during the first 5 sec of anoxia, followed by a return to control levels as contractile activity fell to 40% of control. A second and significant increase in cAMP occurred during the following 60 sec. These results indicate major changes in cAMP levels during the first minute of anoxia-induced contractile failure and suggest that increases in this nucleotide may be related to extent and rate of contractile failure.

The effect of pH on the transient-state kinetics of Ca2+-Mg2+-ATPase of cardiac sarcoplasmic reticulum. A comparison with skeletal sarcoplasmic reticulum

The effect of pH on the Ca2+-Mg2+-dependent ATPase of sarcoplasmic reticulum (SR) was investigated with a rapid mixing quench-flow apparatus capable of measuring phosphorylation and dephosphorylation at times as rapid as 4 msec. The rates of formation and decomposition of the phosphorylated intermediate (E approximately P) of the Ca2+-Mg2+-ATPase were studied in the pH range between 7.6 and 6.0. At pH 6.8, the rates of formation of the phosphorylated intermediate of the Ca2+-Mg2+-ATPase of sarcoplasmic reticulum are the same (t1/2 = 10 msec) for cardiac and skeletal sarcoplasmic reticulum preloaded with calcium, but decrease as the pH is lowered. The effect of acid pH (6.0) is more pronounced for cardiac sarcoplasmic reticulum (t 1/2 = 47 msec) than for skeletal sarcoplasmic reticulum (t 1/2 = 17 msec), in agreement with studies showing that acidosis has a more pronounced effect on cardiac muscle than on skeletal muscle. In addition, a decrease in pH results in a decrease in the rate of the E approximately P decomposition step (the slowest step in the SR reaction sequence). The E approximately P decomposition half-lives were observed to be 97 and 77 msec, respectively for cardiac and skeletal SR at pH 6.8. At pH 6.0, the half-lives were increased to 136 and 178 msec for cardiac and skeletal SR, respectively.

The relative time course of early changes in mitochondrial function and intracellular pH during hypoxia in the isolated toad ventricle strip

Changes in the intracellular H+ ion concentration (pHi) and in the oxidation-reduction state of the respiratory chain were measured spectrophotometrically in the isolated ventricle strip from the toad (Bufo marinus). The relative time course of the delta pHi as indicated by changes in light absorption of the pH dye neutral red, cytochrome c, and peak isometric twitch tension were compared during transient hypoxic episodes. The first detectable change in pH occurred 4.5 minutes after the peak twitch tension began to decrease with the onset of hypoxia. The initial decrease in tension and reduction of cytochrome c occurred at a similar time prior to the change in pHi. On reoxygenation, cytochrome c rapidly became oxidized, and the pHi and tension recovered more slowly. During acidification by increasing superfusate PCO2, pHi and tension decreased together, and cytochrome c did not change significantly. Thus, although changes in pHi do affect mechanical performance, these results show that mechanical dysfunction pursuant to hypoxia is not directly attributable to intracellular acidification.

Oxygen deprivation and early myocardial contractile failure: a reassessment of the possible role of adenosine triphosphate

The precise mechanism responsible for early contractile failure after the onset of myocardial anoxia or ischemia has attracted speculation and controversy. The simple and attractive hypothesis that adenosine triphosphate (ATP) deficiency is responsible for this failure has often been dismissed on the basis of claims that there is only a small reduction in cell ATP content at a time when contractile activity is severely reduced. The premise of this article is that the changes in cell ATP content and distribution that theoretically should occur after oxygen depletion may not have been adequately considered and that previous measurements of cell ATP content may not have been carried out at the correct time. Using an isolated rat heart preparation and high speed freeze-clamping techniques it has been possible to demonstrate that a substantial decrease in myocardial ATP and creatine phosphate content occurs after the onset of anoxia but before the onset of contractile failure. Thus, during the first 5 seconds of anoxia contractile activity remains constant whereas ATP decreases by 25 percent and creatine phosphate by 50 percent. Thereafter, contractile failure occurs and the rate of utilization of high energy phosphates declines with the cell content at a plateau or possibly increasing. These results are assessed in the light of the dynamic changes in energy metabolism occurring in early anoxia and suggest that ATP depletion in a specific cell compartment may be the primary trigger for early contractile failure.

Blockade of myocardial slow inward current at low pH

The effect of low pH on the slow cationic inward current was studied in isolated perfused embryonic chick ventricles (16-21 days old). In order to study the slow current, the fast Na+ current was inactivated by partial depolarization to about -40 mV by elevation of K+ (25 mM). Subsequent exposure of the tissue to catecholamines or methylxanthines allowed slowly rising overshooting electrical responses (the "slow response") with with accompanying contractions to be elicited by electrical stimulation. These slow responses are insensitive to tetrodotoxin and are Na+- and Ca2+-dependent. It was found that the isoproterenol- and caffeine-induced slow responses were abolished at about pH 6.1; 50% inhibition occurred at about pH 6.5. The rate of rise of the normal action potential, which is dependent on a fast Na+ current, was only slightly affected at these same pH levels; however, electromechanical uncoupling occurred, as expected from inhibition of the slow current. Therefore, the slow current was blocked at an acid pH that did not block the fast Na+ current.

Graded global ischemia and reperfusion. Cardiac function and lactate metabolism

The effect of global ischemia of different degrees of severity and reperfusion was studied in the isolated working rat heart. Four degrees of ischemia were induced by reducing the control total coronary flow of 8 ml/min to 0, 0.04, 0.4, or 0.8 ml/min for 30 minutes, after which the coronary flow was returned to the control level. After severe ischemia (0 and 0.04 ml/min ischemic coronary flow groups), recovery of contractility was to less than 30% of the control, pre-ischemic value of ventricular developed pressure and dP/dt, and irreversible cardiac contracture and an increased pacing threshold occurred. After moderate ischemia (0.4 and 0.8 ml/min ischemic coronary flow groups), contractile function recovered completely, ischemic contracture was rapidly reversible and the pacing threshold did not increase. The moderately ischemic groups were able to function at a stable, low level of contractility for the 30 minute ischemic period, whereas the severely ischemic groups had no contractile activity. The amount of calculated tissue lactate accumulation correlated with the occurrence of irreversible ischemic injury; the severely ischemic groups which failed to recover with reperfusion accumulated 3-5 times as much lactate as the moderately ischemic groups which recovered completely. The results suggest that relatively small differences in the severity of the ischemic condition can markedly affect the degree of tissue injury.