Harold Feinberg

Direct evidence for intracellular divalent cation redistribution associated with platelet shape change

Abstract Chlortetracycline was used as a fluorescent probe to monitor shifts in divalent cation distribution when blood platelets were induced to change shape. Human platelets in their native plasma were incubated at 25°C with 50 μM chlortetracycline. It was found that when platelet shape change was stimulated by ADP or the divalent cation ionophore A 23187, a significant decrease in platelet-chlortetracycline fluorescence occurred. This fluorescence shift was consistent with the time course for the change in platelet shape. ATP, which inhibits ADP-induced shape change, also inhibited the decrease in platelet-chlortetracycline fluorescence.

Chronic Hypoxemia Depresses Global Ventricular Function and Predisposes to the Depletion of High-Energy Phosphates during Cardioplegic Arrest: Implications for Surgical Repair of Cyanotic Congenital Heart Defects

Persistence of impaired ventricular function after repair of cyanotic congenital heart defects may be due to previous exposure to chronic hypoxemia or to perioperative ischemic injury. Clarification of this phenomenon was sought in a canine model of cyanotic cardiovascular disease (Group I), in which the left atrium was anastomosed proximal to the banded pulmonary artery. Animals that had pulmonary artery banding alone (Group II) or no prior surgical intervention (Group III) served as controls. All Group I animals became cyanotic during the study period (arterial oxygen tension, 38 +/- 4 mm Hg; hematocrit, 55 +/- 5%). Radionuclide-determined ejection fractions performed three months after operation showed significant depression of global biventricular function by 16 to 29% (p less than 0.05) compared with groups II and III. On cardiopulmonary bypass, all hearts were subjected to 4 degrees C potassium cardioplegic arrest and reperfusion with serial assays for myocardial adenosine triphosphate (ATP) and creatine phosphate (CP) levels. The ATP and CP stores in each ventricle were similar at all sampling intervals, and preischemic levels were comparable in cyanotic and control groups. However, ATP levels were significantly depressed 37 to 43% from preischemic levels (p less than 0.02) after arrest and reperfusion in cyanotic dogs, but they were preserved in Groups II and III. During ischemia, CP stores were depleted to 27% of preischemic values in Group I but only to 46 to 63% of preischemic levels in the control groups (p less than 0.05). These data indicate that chronic hypoxemia impairs global ventricular function and predisposes to the accelerated depletion of high-energy phosphates during cardioplegic arrest.(ABSTRACT TRUNCATED AT 250 WORDS)

Prevention of the hypoxic reoxygenation injury with the use of a leukocyte-depleting filter

OBJECTIVES Recent studies have shown that an injury occurs when the hypoxic heart is suddenly reoxygenated (as occurs with cardiopulmonary bypass), resulting in myocardial depression, impaired oxygenation, and increased pulmonary vascular resistance. We hypothesize that this injury is, in part, due to oxygen-derived radicals produced by activated white cells and may therefore be ameliorated by limiting leukocytes in the bypass circuit. METHODS Fifteen neonatal piglets underwent 60 minutes of ventilator hypoxia (inspired oxygen fraction 8% to 10%), followed by reoxygenation with cardiopulmonary bypass at an inspired oxygen fraction of 100% for 90 minutes. In nine piglets (group 1) our routine bypass circuit was used with no modifications, and in six piglets (group 2) a leukocyte-depleting filter (Pall BC-1; Pall Biomedical Products Corporation, Glencoe, N.Y.) was inserted in the arterial line to lower the neutrophil count. Six additional piglets underwent 90 minutes of bypass without hypoxia (cardiopulmonary bypass controls). Postbypass myocardial and pulmonary function was assessed by pressure volume loops, arterial/alveolar ratio, and pulmonary vascular resistance index. Results are expressed as a percentage of control. RESULTS By comparison with group 1 piglets (reoxygenation without a filter), hypoxic piglets undergoing reoxygenation with a leukocyte-depleting filter (group 2) had improved myocardial systolic function (88% vs 52%; p < 0.05), diastolic compliance (175% vs 275%; p < 0.05), and preload recruitable stroke work (91% vs 54%; p < 0.05); had better preservation of the arterial/alveolar ratio (97% vs 74%; p < 0.05); and had less increase in pulmonary vascular resistance (229% vs 391%; p < 0.05). Furthermore, leukocyte filtration prevented adenosine triphosphate depletion or a change in tissue antioxidants. Conversely, unprotected piglets (group 1) exhibited lower levels of adenosine triphosphate and significant loss of tissue antioxidants. Indeed, the results in the leukocyte-filtered piglets (group 2) were nearly identical to those of piglets subjected to bypass without hypoxia (controls). CONCLUSIONS (1) This study demonstrates that a major component of the injury that occurs when the hypoxic heart is abruptly reoxygenated is caused by oxygen radicals produced by white blood cells; (2) this injury can be prevented by a leukocyte-depleting filter; and (3) avoidance of this injury improves postbypass myocardial and pulmonary function. These data suggest that leukocyte depletion should be used routinely in all children undergoing operations for cyanotic heart disease or extracorporeal membrane oxygenation.

Detrimental Effects of Cardiopulmonary Bypass in Cyanotic Infants: Preventing the Reoxygenation Injury

BACKGROUND Recent experimental studies have shown that acute hypoxia followed by abrupt reoxygenation using cardiopulmonary bypass (CPB) results in an unintended injury mediated by oxygen free radicals, which can be modified by initiating CPB at a lower fraction of inspired oxygen (FiO2) or by leukocyte filtration. However, the clinical relevance of these experimental studies has been questioned because chronic hypoxia may allow compensatory changes to occur. METHODS Seven acyanotic infants had CPB initiated at an FiO2 of 1.0. Of 21 cyanotic infants, 7 (group 1) had CPB initiated at an FiO2 of 1.0, 6 (group 2) at an FiO2 of 0.21, and 8 (group 3) underwent CPB using leukocyte filtration. Biopsy of right atrial tissue was performed before and 10 to 20 minutes after the initiation of CPB. The tissue was incubated in 4-mmol/L t-butylhydroperoxide (a strong oxidant), and the malondialdehyde (MDA) level was measured to determine the antioxidant reserve capacity. The more MDA produced, the greater was the depletion of tissue antioxidants secondary to oxygen free radical formation during reoxygenation. RESULTS There was no difference in the prebypass antioxidant reserve capacity between cyanotic and acyanotic hearts (492 +/- 72 versus 439 +/- 44 nmol MDA/g protein). However, after the initiation of CPB without leukocyte filtration, MDA production rose markedly in the cyanotic (groups 1 and 2) as compared with the acyanotic hearts (322% versus 40%; p < 0.05), indicating a depletion of antioxidants. In cyanotic hearts, initiating CPB at an FiO2 of 1.0 (group 1) resulted in increased MDA production (407% versus 227%) as compared with hearts in which CPB was initiated at an FiO2 of 0.21 (group 2), indicating a greater generation of oxygen free radicals in group 1. Conversely, there was only a minimal increase in MDA production in 8 of the 21 infants (group 3) in whom white blood cells were effectively filtered (19% versus 322%; p < 0.05). CONCLUSIONS First, increased amounts of oxygen free radicals are generated in cyanotic infants with the initiation of CPB. Second, this production is reduced by initiating CPB at an FiO2 of 0.21 or by effectively filtering white blood cells. Third, these changes parallel those seen in the acute experimental model, validating its use for future study.

Controlled Reperfusion After Lung Ischemia: Implications For Improved Function After Lung Transplantation

OBJECTIVES Despite improvements in organ preservation, reperfusion injury remains a major source of morbidity and mortality after lung transplantation. This pilot study was designed to investigate the effects of controlled reperfusion after lung ischemia. METHODS Twenty adult pigs underwent 2 hours of warm lung ischemia by crossclamping the left bronchus and pulmonary artery. In five (group 1), the clamp was simply removed at the end of ischemia (uncontrolled reperfusion). The 15 other pigs underwent modified reperfusion using blood from the femoral artery to perfuse the lung through the pulmonary artery (pressure 40 to 50 mm Hg) for 10 minutes before removing the pulmonary artery clamp. In five (group 2), the blood was mixed with crystalloid, resulting in a substrate-enriched, hypocalcemic, hyperosmolar, alkaline solution. In five (group 3), the blood was circulated through a leukocyte-depleting filter, and the last five (group 4) underwent reperfusion with both a modified solution and white blood cell filter. Lung function was assessed 60 minutes after reperfusion, and biopsy specimens were taken. RESULTS Controlled reperfusion with both a white blood cell filter and modified solution (group 4) completely eliminated the reperfusion injury that occurred with uncontrolled reperfusion (group 1), resulting in complete preservation of compliance (98% +/- 1% vs 77% +/- 1%; p < 0.001, and arterial/alveolar ratio (97% +/- 2% vs 27% +/- 2%; p < 0.001); no increase in pulmonary vascular resistance (106% +/- 1% vs 198% +/- 1%; p < 0.001); lowered tissue edema (82.1% +/- 0.4% vs 84.3% +/- 0.2%; p < 0.001), and myeloperoxidase activity (0.18 +/- 0.02 vs 0.35 +/- 0.02 deltaOD/min/mg protein; p < 0.001). In contrast, using either a white blood cell filter or modified solution separately improved but did not avoid the reperfusion injury, resulting in pulmonary function and tissue edema levels that were intermediate between group 1 (uncontrolled reperfusion) and group 4 (white blood cell filter and modified solution). CONCLUSION After 2 hours of warm pulmonary ischemia, (1) a severe lung injury occurs after uncontrolled reperfusion, (2) controlled reperfusion with either a modified reperfusion solution or white blood cell filter limits, but does not avoid, a lung reperfusion injury, (3) reperfusion using both a modified reperfusate and white blood cell filter results in complete preservation of pulmonary function. We therefore believe surgeons should control the reperfusate after lung transplantation to improve postoperative pulmonary function.

Movement of sodium into human platelets induced by ADP.

1. In normal human platelets the concentrations of Na+ and K+ were 42.1 +/- 4.3 and 98.8 +/- 3.7 mequiv/l of platelet water respectively (mean +/- S.E. of 22 samples). 2. When platelet-rich plasma was incubated with 22Na+ at 37 degrees C for 2-3 h an increase in platelet Na+ concentration was found which was significant after 210 min. Platelet K+ concentration did not change significantly. The platelet 22Na+ radioactivity increased faster than did the total Na+ suggesting a Na+o-Na+ exchange process in unactivated platelets. 3. Addition of ADP to platelet-rich plasma resulted in platelet aggregation and a rapid rise (within seconds) in 22Na+-radioactivity within the platelets and after 300 s this increase diminished toward control levels. 4. Under the same experimental conditions, ADP did not bring about an increase of 36Cl- in the platelets. 5. Ouabain (10-(6) M) added to platelet-rich plasma induced an increase in Na+ concentration and 22Na+ radioactivity in the platelets, as well as a decrease in K+ concentration. ADP produced a further increase in 22Na+, which did not return toward control values, in the presence of ouabain. 6. The association of an increase in 22Na+ but not of 36Cl- accompanying aggregation by ADP suggests a selective mechanism for the movement of Na+ into platelets rather than a movement of NaCl together with water under an osmotic gradient.

Myocardial protection in normal and hypoxically stressed neonatal hearts: The superiority of hypocalcemic versus normocalcemic blood cardioplegia ☆ ☆☆ ★ ★★ ♢ ♢♢ ♦

OBJECTIVES The ideal cardioplegic calcium (Ca+2) concentration in newborns continues to be debated. Most studies examining cardioplegia calcium concentrations have been done with a nonclinical model (i.e., isolated heart preparation), the results of which may not be clinically applicable, and they have not examined the effect of calcium concentration in a clinically relevant stressed (hypoxic) heart. METHODS Twenty neonatal piglets 5 to 18 days old were placed on cardiopulmonary bypass, and their aortas were crossclamped for 70 minutes with hypocalcemic or normocalcemic multidose blood cardioplegic infusions. Group 1 (n = 5; low Ca+2, 0.2 to 0.4 mmol/L) and group 2 (n = 5; normal Ca+2, 1.0 to 1.3 mmol/L) were nonhypoxic (uninjured) hearts. Ten other piglets were first ventilated at an FiO2 of 8% to 10% (O2 saturation 65% to 70%) for 60 minutes (i.e., causing hypoxia) and then reoxygenated at an FiO2 of 100% with cardiopulmonary bypass, which produces a clinically relevant stress injury. They then underwent cardioplegic arrest (as described above) with a hypocalcemic (n = 5, group 3) or normocalcemic (n = 5, group 4) blood cardioplegic solution. Myocardial function was assessed with pressure volume loops and expressed as a percentage of control values. Coronary vascular resistance was measured during each cardioplegic infusion. All values were reported as the mean +/- standard error. RESULTS In nonhypoxic hearts (groups 1 and 2), good myocardial protection was achieved at either concentration of cardioplegia calcium, as demonstrated by preservation of postbypass systolic function (104% vs 99% end-systolic elastance), minimally increased diastolic stiffness (152% vs 162%), no difference in myocardial water (78.9% vs 78.9%), and no change in adenosine triphosphate levels or coronary vascular resistance. Low-calcium blood cardioplegia solution repaired the hypoxic reoxygenation injury in stressed hearts (group 3), resulting in no statistical difference in myocardial function, coronary vascular resistance, or adenosine triphosphate levels compared with nonhypoxic hearts (groups 1 and 2). Conversely, when a normocalcemic cardioplegia solution was used in hypoxic hearts (group 4), there was marked reduction in postbypass systolic function (49% +/- 4% end-systolic elastance; p < 0.05), increased diastolic stiffness (276% +/- 9%; p < 0.05), increased myocardial water (80.1% +/- 0.2%; p < 0.05), rise in coronary vascular resistance (p < 0.05), and lower adenosine triphosphate levels compared with groups 1, 2, and 3. CONCLUSIONS This study demonstrates that, in the clinically relevant, intact animal model, good myocardial protection is independent of cardioplegia calcium concentration in nonhypoxic (noninjured) hearts; hypoxic (stressed) hearts are extremely sensitive to the cardioplegic calcium concentration; and normocalcemic cardioplegia is detrimental to neonatal myocardium subjected to a preoperative hypoxic stress.

Biochemical Changes of Ischemia

Normothermic ischemic arrest by aortic cross-clamping, a widely used clinical technique, is associated with metabolic changes in the myocardium that are incompletely understood. The effects of aortic cross-clamping on glycolytic pathways as well as associated morphological changes are discussed. Emphasis is placed on the conservation of high-energy phosphate moieties during the period of cross-clamping as well as during reperfusion. A marked reduction in total high-energy phosphates (62%) and glycogen (63%) and an increase in lactate production (243%) denote a shift to anaerobic metabolism during the period of arrest. Despite reperfusion, total high-energy nucleotides remained depressed. The data suggest that persistent abnormal myocardial carbohydrate metabolism and low levels of high-energy nucleotides prevent recovery of contractility following normothermic ischemic arrest and reperfusion.

Alterations in phospholipid metabolism in the globally ischemic rat heart: Emphasis on phosphoinositide specific phospholipase C activity

The effect of global ischemia on myocardial ventricular membrane phospholipids was evaluated using a modified Langendorff preparation. Isolated rat hearts were perfused at 37 degrees C with oxygenated Krebs Ringer solution or rendered ischemic by cessation of perfusion (10 min to 3 h). Longer periods of ischemia were assessed by incubating preperfused (10 min) intact hearts in non-oxygenated Krebs (37 degrees C) for 6 to 18 h. Ischemia-induced alterations in phosphatidylinositol levels and phosphoinositide-specific phospholipase C (PI PLC) activity were assessed in detail, since inositol phospholipids and PI-PLC play putative roles in the regulation of cell function and Ca2+ homeostasis. Decreases in major membrane phospholipids (phosphatidylcholine, phosphatidylserine, cardiolipin and sphingomyelin) were demonstrated after long ischemic periods (6 to 18 h). While periods of ischemia (3 h or less) induced no change in structural phospholipids, an elevation in lysophosphatidylcholine and free fatty acids was found by 1 h. Notably a significant increase in phosphatidylinositol content and an accompanying decrease in cytosolic PI PLC activity was detected by 30 mins of ischemia. Reduced enzymic activity was not due to altered in vitro activation or deactivation of PI-PLC, to a change in the Ca2+ requirement of the enzyme, or to translocation of the enzyme from the cytosol to a membrane fraction. The isolated rat heart made globally ischemic for 30 mins under conditions described for this investigation shows signs of irreversible injury i.e. increased cell Ca2+ content and inability to initiate and maintain rhythmic contraction upon reperfusion. Therefore, it is possible that altered phosphoinositide metabolism may contribute to the evolution of ischemia-elicited irreversible cell injury.

The effect of D2O and chlortetracycline on ADP-induced platelet shape change and aggregation

Abstract The role of intracellular Ca 2+ in platelet shape change (SC) and aggregation was investigated by exchanging platelet H 2 O for D 2 O. Human platelets were isolated by D 2 O-albumin density gradient centrifugation and resuspended in D 2 O Tyrodes (37°C). Such treatment inhibited SC and aggregation in response to 10 −4 or 10 −5 M ADP, but did not inhibit the extent of aggregation induced by 10 −5 or 10 −6 M epinephrine. When platelets were incubated (37°C) with 500 μM chlortetracycline (CT), a divalent cation chelator, SC and aggregation in response to 10 −5 M ADP were inhibited. This inhibition could not be reversed by the addition of 5 mM CaCl 2 . CT incubation also resulted in inhibition of 10 −5 M epinephrine-induced aggregation, but, in this case, addition of CaCl 2 (5 mM) completely restored the epinephrine response to control levels. The above results are consistent with the contention that ADP initiates SC and aggregation by triggering an increase in cytoplasmic Ca 2+ .