Perfusion
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Serious pulmonary failure may be treated with extracorporeal membrane oxygenation (ECMO) when other treatment has failed. The aim of this study was to analyze pre-operative risk factors of early mortality in patients who underwent either veno-arterial (VA) ECMO or veno-venous (VV) ECMO for pulmonary failure. We studied a total of 26 risk factors in 72 patients with severe pulmonary insufficiency treated with ECMO. ⋯ It is, however, difficult to predict outcome when initiating ECMO. In this analysis, only pre-operative serum creatinine levels correlated with survival. None of the other parameters, including those which were used to select patients for ECMO treatment, could significantly predict the outcome.
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Comparative Study Retracted Publication
Treating pulmonary hypertension post cardiopulmonary bypass in pigs: milrinone vs. sildenafil analog.
Procedures using cardiopulmonary bypass (CPB) and aortic cross-clamping are associated with a variable degree of ischemia/reperfusion of the lungs, leading to acute pulmonary hypertension (PHT). The purpose of this study was to compare the effects of the sildenafil analog (UK343-664), a phosphodiesterase type V(PDEV) inhibitor, with milrinone, a PDE type III inhibitor, in a porcine model of acute PHT following CPB. After the pigs were anesthetized, pressure-tipped catheters were placed in the right ventricle and carotid and pulmonary arteries. ⋯ After administration of the drugs, mean pulmonary artery pressure decreased in all 3 groups; however, only in the sildenafil-analog group did pulmonary vascular resistance(PVR) decrease by 35%, from 820 to 433 dynes . cm . sec(-5) at 5 minutes (p<0.05), and continued to be decreased at 10 minutes by 26% (P<0.05). Pulmonary selectivity was demonstrated with sildenafil-analog, because there were no similar changes in systemic vascular resistance(SVR) and no significant changes in systemic hemodynamics. Sildenafil-analog, a PDEV inhibitor, shows a promising role for managing the PVR increases that occur following CPB.
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Cardiopulmonary bypass(CPB) is associated with fluid overload. We hypothesized that fluid gain during CPB could be reduced by substituting parts of a crystalloid prime with 7.2% hypertonic saline and 6% poly (O-2-hydroxyethyl) starch solution (HyperHaes). 14 animals were randomized to a control group (Group C) or to Group H. CPB-prime in Group C was Ringer's solution. ⋯ Hemodynamics and laboratory parameters were similar in both groups. Serum concentrations of sodium and chloride increased to maximum levels of 148 (1.5) and 112 (1.6) mmol/l in Group H. To conclude: addition of 7.2% hypertonic saline and 6% poly (O-2-hydroxyethyl) starch solution to crystalloid CPB prime reduces fluid needs and FER during tepid CPB.
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The volatile anesthetics are a class of general anesthetic drugs used by the perfusionist during cardiopulmonary bypass (CPB). These agents are used in low doses in combination with other anesthetics to produce complete anesthesia. During CPB, these agents are capable of safely anesthetizing the paitent. ⋯ At concentrations of 2% and greater, sevoflurane significantly reduced cardiac output, ejection fraction, fractional shortening, and increased end-diastolic and end-systolic volumes. Isoflurane-induced reduction of left ventricular function was much less in magnitude when compared with sevoflurane. These data underscore the importance of using lower concentrations of volatile anesthetics during CPB especially during periods of cardiac recovery after aortic cross-clamp removal.
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In this study, a patient simulator was designed and fabricated to train students to respond to various clinical situations associated with heart-lung bypass machine operation and to respond to changes in patient clinical parameters. The students will use the simulator to gain pre-clinical experience. The training system will initially simulate normal heart-lung bypass conditions. ⋯ Some of these problems are stopping of rotation of one of the roller pump heads, abnormal changes in the vital parameters, such as oxygenation level or biochemical values, high blood pressure, and occlusion in arterial or venous lines. The simulator will train students to respond properly to these situations, hence, allowing them to gain clinical experience without impacting patient safety and the outcome of real life procedures. The simulator can also be used for assessment of the students' competency levels.