Cody C. Trowbridge

Utilization of rapid-infuser devices for massive blood loss

Rapid volume replacement for severe hemorrhage continues to challenge the clinician involved in the care of the patient suffering hemorrhagic shock. We report on the development and utilization of two rapid-infuser systems for volume replacement in critically ill patients presenting in extremis. We have developed rapid-infusion circuits by using commercially available devices available at our institution. The primary pumping mechanism is either a centrifugal pump (Revolution™COBE Cardiovascular, Arvada, CO, USA), or the Myocar-dial Protection System (MPS™ - Quest Medical, Allen, TX, USA), and offers advantages over commercially available devices. Both circuits consist of a cardiotomy reservoir, a cardioplegia delivery set, assorted tubing and connectors, and a heater-cooler system. Between January and October of 2003, 15 procedures were performed which utilized one of these two devices. There were nine ruptured aneurysms, five traumas and one radical nephrectomy. The rapid infusion time averaged 228.59±105.7 min where 10.49±9.4 L of autotransfusion volume was processed, with 3.99±4.2 L of red cell volume reinfused. The allogeneic blood products that were transfused included packed red blood cells and fresh frozen plasma, as well as 5% albumin. There were no intraoperative deaths and the rapid-infuser was considered lifesaving in all instances. Mechanical rapid infusion systems may be lifesaving when severe hypovolemia or hemorrhagic shock is encountered. While both devices are able to meet the requirements of rapid fluid replacement, the MPS offers the most safety features and has become the standard of care at our institution.

The effect of priming techniques of ultrafiltrators on blood rheology: an in vitro evaluation.

The increased interest of using ultrafiltration during cardiopulmonary bypass (CPB) has mandated a re-evaluation of the hematological effects of this blood conservation process. ‘Rinse-free’ ultrafiltrators can be primed using either crystalloid or blood prior to use. It is unknown whether one priming technique results in superior results in ultrafiltration quality. An in vitro circuit was designed to evaluate the Sorin/COBE HC1400 (n=6), the Lifestream HC70 (n=6), and the Terumo/Sarns HC11 (n=6). All test conditions were conducted at a blood flow rate of 250 ml/min and a transmembrane pressure of 250 mmHg. Samples were drawn and analyzed at four distinct time points for hematocrit, total protein, plasma free hemoglobin, interleukin-6 (IL-6), interleukin-8 (IL-8), and tumor necrosis factor-α (TNFα). The HC11 had significantly greater percent increases in hematocrit under the blood priming protocol (29.2 ± 7.9) than either the HC1400 (11.0 ± 7.8, p<0.03) or the HC70 (11.9 ± 7.8, p<0.04). When crystalloid priming was compared to blood priming, the HC1400 and HC70 produced significant percent increases in hematocrit and total protein levels. The HC1400 devices produced significantly less plasma free hemoglobin when primed with crystalloid rather than blood (43.6 ± 38.3 vs 21.3 ± 5.6, p<0.01). There were no significant differences between devices or priming techniques for IL-6, IL-8 or TNF levels. In conclusion, the efficiency of the ultrafiltrators was elevated when primed with crystalloid before use. Cytokine levels were relatively unchanged with priming techniques, while plasma free hemoglobin levels were reduced with those devices previously primed with crystalloid.

Coagulation management of a patient with factor V Leiden mutation, lupus anticoagulant, and activated protein C resistance: a case report

Although patients undergoing cardiac surgery often present with diverse comorbidities, those with coagulation derangements are especially challenging. The present report describes the management of a patient who presented with a Factor V Leiden mutation, lupus anticoagulant, and acquired activated protein C resistance. A 42-year-old female presented with acute shortness of breath and chest pain. She was otherwise healthy 1 month prior to admission when she presented with dysfunctional uterine bleeding, resulting in the transfusion of three units of packed red blood cells. Coagulation evaluation revealed that the patient had lupus anticoagulant, factor V Leiden mutation and an activated protein C resistance. The patient presented with an acute myocardial infarction and was found to have 90% stenosis of her left main coronary artery, moderate mitral and tricuspid regurgitation, and a left ventricular ejection fraction of 25%. An emergent off-pump coronary artery bypass procedure with placement of a vein graft to the left anterior descending artery was completed. Intraoperative thrombophilia was encountered as evidenced by both an elevated thromboelastograph™ coagulation index (=3.6) and an acquired antithrombin-III deficiency. Postoperatively, the patient was placed on low molecular weight heparin, but developed heparin-induced thrombocytopenia and was switched to a direct thrombin inhibitor, argatroban. The following case report describes the coagulation management of this patient from the time of admission to discharge 43 days later, and the unique challenges this combination of hemostatic defects present to the clinicians.

An in vitro study of the effects of isoflurane on oxygen transfer.

A common anesthetic technique utilized during cardiopulmonary bypass (CPB) includes the use of various inhalation agents, such as isoflurane. The purpose of this study was to evaluate the effects of this agent on oxygen transfer during CPB. An in vitro model was designed using bovine blood. Blood flow was held constant at 2 l/min, while gas flow was manipulated at 1 and 3 l/min. The percentage of inspired oxygen (FiO2) was set at 50 and 100%, and isoflurane was manipulated to 1.0, 3.0 and 5.0%. Blood gas analysis, oxygen transfer, and inlet and outlet isoflurane concentrations were measured at each of the given conditions. A total of 12 trials with four oxygenators were conducted. In the four oxygenators used in our study, no significant differences in oxygenator performance were found. At conditions of 1 l/min gas flow, 50% FiO2 and 1% isoflurane, there were no significant changes in O2 transfer between baseline and measurements taken during isoflurane administration (100.18 ± 12.49 vs 102.35 ± 10.99 ml O2/min, p=0.8031). At 3 l/min gas flow, 100% FiO2 and 5% isoflurane, no significant differences were found (142.35 ± 10.76 vs 154.04 ± 8.95 ml O2/min, p=0.1459). The only significant differences found for oxygen transfer were between 50 and 100% FiO2, all other conditions being set equal (102.35 ± 10.99 vs 137.68 ± 8.62 ml O2/min, p=0.0023). In conclusion, increasing concentrations of isoflurane up to 5% does not affect the efficiency of oxygen transfer in an in vitro circuit. Further studies are necessary to evaluate the effects in an in vivo setting.