Hypervolemic hemodilution: an alternative to acute normovolemic hemodilution? A mathematical analysis.

BACKGROUND: Hypervolemic hemodilution has been proposed as an alternative to normovolemic hemodilution to reduce homologous blood transfusions. So far, convincing data supporting this concept are unknown. MATERIALS AND METHODS: We therefore present a mathematical model calculating the efficacy of hypervolemic, normovolemic, and "no" hemodilution. Hypervolemic hemodilution constituted volume expansion (20% of estimated blood volume) maintained throughout surgery. Normovolemic hemodilution contained isovolemic exchange of blood (40% of estimated blood volume) vs colloid as well as retransfusing blood plus colloid to maintain minimal acceptable hematocrit, e.g., transfusion trigger. To determine the efficacy of each technique maximal allowable blood loss and final postoperative hematocrit were calculated. Maximal allowable blood loss referred to the amount of blood lost during surgery after which homologous blood transfusion became necessary. RESULTS: Recalculating published clinical data strongly validated the formulas used for our model. Hypervolemic hemodilution always revealed lowest maximal allowable blood losses. Normovolemic hemodilution constantly ensured highest maximal allowable blood losses. For blood losses <40% of blood volume, hypervolemic and normovolemic hemodilution provided almost identical final postoperative hematocrits. But in contrast to normovolemic hemodilution, hypervolemic hemodilution did not carry the risk of severe transient, retransfusion-induced hypervolemia. "No" hemodilution always gave lowest final postoperative hematocrits. CONCLUSIONS: Thus, hypervolemic hemodilution cannot replace normovolemic hemodilution to reduce homologous transfusions, but for blood losses <40% of blood volume hypervolemic hemodilution appears to be superior.     

Present state of intentional hemodilution

Preoperative intentional hemodilution is induced by isovolemic exchange of whole blood with colloid solutions in order to gain autologous blood while maintaining normovolemia. The basic mechanism that compensates for the fall of oxygen capacity of the diluted blood is the rise in cardiac output, and organ blood flow, factors that result from the improved fluidity of blood at lower hematocrits. Normal tissues maintain adequate oxygenation during hemodilution through the enhanced redistribution of blood. In ischemic tissues this effect is enhanced, and causes an increase in the oxygenation of ischemic tissues. Limited preoperative and intraoperative hemodilution are alternatives to donor blood transfusion in patients undergoing elective surgery. In shock patients the hemodilution achieved with red cell free primary volume substitutes is an effective treatment for shock-induced microcirculatory disorders; furthermore, intentional hemodilution is the most effectual hemorheological therapy for the treatment of ischemic disease.     

A technique for rapid exchange of continuous renal replacement therapy

Re-initiation of continuous renal replacement therapy (CRRT) in neonates and young infants weighing less than 15 kg often necessitates a blood prime of the blood circuit path or a concurrent packed red blood cell (PRBC) transfusion to avoid causing hemodynamic instability due to acute hemodilution. The significant amount of time required for a routine CRRT circuit change can be associated with worsening electrolyte and acid–base abnormalities, fluid retention, greater hemodynamic instability and reducing effective hemofiltration time. In an attempt to limit the time without CRRT and to eliminate the requirement for additional blood exposure, a new technique, rapid exchange of continuous renal replacement therapy (RECRRT), was developed. Rapid exchange of continuous renal replacement therapy is a sequential technique that transfers citrated blood from one CRRT machine to another machine connected in series. The technique effectively negates the requirement for CRRT circuit path blood priming or PRBC transfusion. The amount of time without CRRT is markedly reduced by RECRRT to 2–3 min. The RECRRT technique has been utilized more than 30 times for at least 15 patients without an adverse event. RECRRT may benefit children who weigh less than 15 kg and in those patients who experience hemodynamic or clinical instability while CRRT is discontinued for only a brief period.     

A technique for autologous priming of the veno-venous bypass circuit during liver transplantation

Orthotopic liver transplantations (OLT) have been associated with significant blood loss and hemodilution, necessitating significant homologous blood component replacement. Increasing administration of homologous blood products has been found to be inversely related to patient and graft survival. Various methods to reduce the amount of blood products patients receive during OLT, such as antifibrinolytic therapy, thromboelastography-guided transfusion, phlebotomy, reduced central venous pressures intraoperatively, and the use of the veno-venous bypass (VVB) circuit, have been explored.The asanguineous priming volume of the VVB circuit increases the likelihood of the patient receiving homologous blood products due to hemodilution. It was reasoned that autologous priming of the VVB circuit in OLT surgery was a plausible adjunctive blood conservation technique given its application to the extracorporeal circuit during cardiac surgery. We describe our technique of modifying the VVB circuit for autologous priming. This technique adds minimal risk and a small amount of cost to the procedure, requires slightly more communication among members of the surgical team, and with proper sequencing, adds no additional length to the surgical procedure. It is recommended that this technique be considered for addition to the arsenal of blood conservation techniques when VVB is used during OLT.     

Acute hemodilution in an anemic Jehovah's Witness during extensive abdominal wall resection and reconstruction

A 47-year-old anemic Jehovah's Witness with Gardner's syndrome presented with a large abdominal wall desmoid tumor requiring extensive resection with a musculocutaneous flap reconstruction. At surgery a technique of acute limited normovolemic hemodilution (ALNH) was used to minimize blood loss and avoid blood transfusions. Complications that follow transfusions of homologous blood are reviewed, and a recommendation is made to use ALNH because of its advantages in those patients in whom significant blood loss is expected.     

Artificial oxygen carriers. Alternatives to homologous blood transfusion?]

The expected explosion of costs in transfusion medicine due to the shortfall of healthy donors and the more frequent treatment of transfusion-associated complications (chronic hepatitis, cirrhosis, wound infection, tumor recurrence) increases the socio-economic importance of the development of safe and effective synthetic oxygen carriers as an alternative to the transfusion of homologous red blood cells. Currently two types of artificial oxygen carriers are experimentally and clinically investigated for their capacity to ensure adequate tissue oxygenation in the case of severe anemia. In addition to their oxygen transport capacity solutions based on free human or bovine hemoglobin provide vasoconstrictor properties. Their hyperoncotic properties make them particularly attractive for the treatment of severe hemorrhagic shock. Perfluorocarbon (PFC) emulsions allow an increase of the physically dissolved portion of arterial oxygen content. Due to their particulate nature (emulsion droplets) PFC may only be infused in low doses. Otherwise there is risk of overload and malfunction of phagocytic cells of the reticulo-endothelial system. In the case of an intraoperative blood-loss in preoperatively hemodiluted patients, bolus infusion of PFC represents an effective means to avoid immediate retransfusion of autologous blood and allows for further, extreme hemodilution without risking tissue hypoxia.     

Hemodilution and autotransfusion in pediatric cardiac surgery

Better understanding and advances in the management of neonates undergoing cardiac surgery have increased their survival. Twenty neonates were studied to evaluate the technique of acute hemodilution in open cardiac surgery. They were premedicated by rectal barbiturate, anesthetized and monitored for all vital signs and blood chemistry. Patients operated upon with hemodilution suffered less respiratory acidosis during bypass. They showed marked drop in pH which was rapidly corrected in the postoperative period. No significant change in blood pressure from the expected was observed. These neonates (with hemodilution) had more tendency to fluid retention, which is not of appreciable clinical significance. The technique of acute hemodilution in neonates undergoing open cardiac surgery with extracorporeal circulation proved to be successful.     

Intraoperative normovolemic hemodilution

We have studied the cardiopulmonary hemodynamics of acute hemodilution in a group of patients with cancer. The majority of patients had multisystem disease; including chronic lung disease, liver disease, sepsis, and malnutrition. The only patients who were excluded were those with a recent history of myocardial ischemia. Acute intraoperative hemodilution to a hematocrit of 22% was well tolerated provided blood volume was maintained with crystalloid solution. Hemodilution led to improved cardiac output by enhancing venous return which helped to compensate for the diminished oxygen content of the blood. There were no adverse cardiopulmonary effects in hemodiluted patients compared to patients undergoing similar operations without hemodilution. Acute normovolemic hemodilution is an effective clinical means of reducing the use of bank blood and avoiding the risks of blood transfusion in patients undergoing major surgery.     

Circulatory effects of verapamil during normovolemic hemodilution in anesthetized rats

Patients who have undergone perioperative normovolemic hemodilution may require calcium channel blockers for the treatment of myocardial ischemia and/or supraventricular tachyarrhythmias. The purpose of this rodent study was to examine the effect of intravenous verapamil on the hyperdynamic circulatory response to acute normovolemic hemodilution (hematocrit 20%). Anesthetized animals were randomly divided into four groups equal in number: (1) controls (no hemodilution, no drug); (2) hemodilution only; (3) verapamil only; and (4) hemodilution followed by verapamil. Cardiac output was recorded using an electromagnetic flow probe. Pre- and afterload tests were performed, the former consisting of rapid infusion of blood adjusted for hematocrit, the latter consisting of an aortic clamp technique. Animals in group 2 had significantly (P less than 0.05) greater percent increases in cardiac index, stroke volume index, and dP/dt, and greater percent decreases in mean arterial pressure, systemic vascular resistance, and oxygen delivery than did control animals (group 1). Infusion of verapamil after hemodilution (group 4) did not interfere with the compensatory increases in cardiac index and stroke volume index seen in group 2, nor did it reduce the peak stroke volume index in response to preload stress, although it did reduce resting dP/dt, mean arterial pressure and systemic vascular resistance, and peak cardiac index and "left ventricular developed pressure" after preload and afterload stress, respectively. We conclude that reduced ventricular function after verapamil administration does not interfere with the compensatory increase in stroke volume index after normovolemic hemodilution.     

Effects of normovolemic hemodilution on blood flow in the rabbit ear.

The effect of isovolemic hemodilution using dextran-60 on arterial blood flow in the rabbit ear was investigated. The animals were anesthetized and an electromagnetic flow probe was applied around the central artery of the ear. Isovolemic hemodilution was performed during a 15 min exchange period. Two degrees of hemodilution were investigated [8.5 and 17 ml dextran-60/kg body weight (b.w.)] and compared with a nontreated control group. The two levels of hemodilution induced reductions in hematocrit to 29 and 21%, respectively, from the control level of about 40%. In all groups, blood pressure maintained constant levels throughout each experiment, which lasted 240 min. In the controls, ear artery blood flow was unchanged or decreased slightly during the experiment. The lower level of hemodilution caused a slight increase of blood flow after 4 h. In the group treated with 17 ml/kg b.w. dextran, blood flow gradually increased after 90 min following hemodilution. After 240 min, flow rates had increased to two- or threefold the initial rate in this group. Although other possibilities exist, the increased blood flow following hemodilution may be interpreted as reflecting a decreased resistance to flow in the tissue due to the decreased viscosity of the blood.     

Isovolemic hemodilution in experimental focal cerebral ischemia. Part 1: Effects on hemodynamics, hemorheology, and intracranial pressure

A total of 76 splenectomized dogs were entered in a study of the value and effects of isovolemic hemodilution. Of these, seven were not included in the analysis because of technical errors. Of the remaining 69 dogs, 35 were treated with hemodilution; 28 were subjected to a 6-hour period of temporary occlusion of the distal internal carotid artery and the proximal middle cerebral artery, and seven underwent a sham operation only, with arterial manipulation but no occlusion. The other 34 dogs were not subjected to hemodilution; 26 of these underwent temporary arterial occlusion and eight had a sham operation only. In each group the animals were about equally divided into 1) an acute protocol with regional cerebral blood flow measurements by a radioactive microsphere technique and sacrifice at the end of the acute experiment, and 2) a chronic protocol with survival for 1 week to permit daily neurological assessment and final histopathological examination but without blood flow measurements. Isovolemic hemodilution was performed about 1 hour after the arterial occlusion or sham operation and was accomplished by phlebotomy and infusions of low molecular weight dextran to bring the hematocrit to a level of 30% to 32%. This treatment resulted in a very significant reduction in viscosity and fibrinogen levels. The decrease in hematocrit lasted throughout the week in the animals in the chronic protocol. The decrease in viscosity correlated almost linearly with the decrease in hematocrit. There was a slight decrease in systemic arterial pressure with hemodilution but there were no significant changes in central venous pressure or in pulmonary arterial or wedge pressure. There was a slight decrease in cardiac index in both the hemodilution and control groups, which may have been due to the effects of barbiturate anesthesia. There was a slight increase in the measured blood volume in both groups, which was probably artifactual and related to the method of calculation. Intracranial pressure increased significantly with time in all animals subjected to arterial occlusion, but this increase was less severe in the hemodilution group. There was no significant change in intracranial pressure in sham-operated animals, whether hemodiluted or not. The results of cerebral blood flow measurements, assessment of neurological conditions, and measurement of infarct size are given in Part 2 of this report.     

Hemostasis and hemodilution: a quantitative mathematical guide for clinical practice

Quantitative changes of hemostasis during hemodilution remain unclear. With the increasing popularity of artificial blood substitutes (ABS), which solely provide oxygen-transport capacity, this issue becomes even more complex. We developed a mathematical model to quantitatively analyze hemostasis during hemodilution and validated it by recalculating patient data. We calculated and compared maximal allowable blood losses (MABL) related to minimal acceptable hematocrit, platelet concentration, and plasma fibrinogen concentration. MABL is the maximal blood loss that can be tolerated without any additional blood products. The variable with the smallest MABL thus limits hemodilution foremost. Hemodilution included isovolemic replacement of blood loss with colloid or acute normovolemic hemodilution (ANH) followed by isovolemic replacement of blood loss with colloid and ABS. We also related our findings to preoperative patient data (n = 204). The decline in platelet concentrations rarely (<2% of all patients) limits hemodilution. By contrast, critical plasma fibrinogen (< or =100 mg/dL) concentrations can often (< or =20% of all patients) limit hemodilution if their initial concentrations are within the lower normal range (<300 mg/dL). These findings become more frequent if ANH is combined with ABS. Under those circumstances ANH blood products are solely required for stabilization of hemostasis, thereby defeating the original purpose of combining ANH with ABS. IMPLICATIONS: The causes of quantitative changes of hemostasis during hemodilution, as well as their clinical effect and relevance, remain unclear. Using a validated, realistic mathematical model, we demonstrate that hemostasis, especially plasma fibrinogen, can limit the extent of hemodilution. This phenomenon is particularly prominent when acute normovolemic hemodilution is combined with artificial blood substitutes.     

Hemodilution during venous gas embolization improves gas exchange, without altering V(A)/Q or pulmonary blood flow distributions

BACKGROUND: Isovolemic anemia results in improved gas exchange in rabbits with normal lungs but in relatively poorer gas exchange in rabbits with whole-lung atelectasis. In the current study, the authors characterized the effects of hemodilution on gas exchange in a distinct model of diffuse lung injury: venous gas embolization. METHODS: Twelve anesthetized rabbits were mechanically ventilated at a fixed rate and volume. Gas embolization was induced by continuous infusion of nitrogen via an internal jugular venous catheter. Serial hemodilution was performed in six rabbits by simultaneous withdrawal of blood and infusion of an equal volume of 6% hetastarch; six rabbits were followed as controls over time. Measurements included hemodynamic parameters and blood gases, ventilation-perfusion (V(A)/Q) distribution (multiple inert gas elimination technique), pulmonary blood flow distribution (fluorescent microspheres), and expired nitric oxide (NO; chemoluminescence). RESULTS: Venous gas embolization resulted in a decrease in partial pressure of arterial oxygen (PaO2) and an increase in partial pressure of arterial carbon dioxide (PaCO2), with markedly abnormal overall V(A)/Q distribution and a predominance of high V(A)/Q areas. Pulmonary blood flow distribution was markedly left-skewed, with low-flow areas predominating. Hematocrit decreased from 30+/-1% to 11+/-1% (mean +/- SE) with hemodilution. The alveolar-arterial PO2 (A-aPO2) difference decreased from 375+/-61 mmHg at 30% hematocrit to 218+/-12.8 mmHg at 15% hematocrit, but increased again (301+/-33 mmHg) at 11% hematocrit. In contrast, the A-aPO2 difference increased over time in the control group (P < 0.05 between groups over time). Changes in PaO2 in both groups could be explained in large part by variations in intrapulmonary shunt and mixed venous oxygen saturation (SvO2); however, the improvement in gas exchange with hemodilution was not fully explained by significant changes in V(A)/Q or pulmonary blood flow distributions, as quantitated by the coefficient of variation (CV), fractal dimension, and spatial correlation of blood flow. Expired NO increased with with gas embolization but did not change significantly with time or hemodilution. CONCLUSIONS: Isovolemic hemodilution results in improved oxygen exchange in rabbits with lung injury induced by gas embolization. The mechanism for this improvement is not clear.     

Myocardial blood flow and oxygen consumption during isovolemic hemodilution alone and in combination with adenosine-induced controlled hypotension

Recent reports have proposed combining isovolemic hemodilution and controlled hypotension to limit blood loss during surgery. Before such a technique can be considered for clinical use, it must be demonstrated that it does not endanger maintenance of adequate myocardial oxygenation. Accordingly, measurements of left ventricular myocardial blood flow and oxygen consumption were obtained during isovolemic hemodilution alone and in combination with adenosine-induced controlled hypotension in ten pentobarbital-anesthetized, open chest dogs with normal coronary circulation. Hemodilution to a hematocrit of 21.7% was produced by isovolemic exchange of whole blood for 5% dextran. In the presence of hemodilution, adenosine was infused intravenously at a rate sufficient to decrease mean aortic pressure to 51 mm Hg. Myocardial blood flow was measured with radioactive microspheres and used to calculate global left ventricular myocardial oxygen consumption and oxygen supply. Hemodilution alone increased aortic blood flow (+43%) but had no effect on aortic pressure, left atrial pressure, heart rate, or left ventricular dP/dtmax; an increase in myocardial blood flow (+130%) maintained oxygen supply and consumption at the baseline level. Adenosine-induced hypotension during hemodilution decreased heart rate (-35%), left ventricular dP/dt max (-28%), and aortic blood flow (-14%). These systemic responses were accompanied by reduced myocardial oxygen consumption (-29%) and increased myocardial blood flow (+54%) and myocardial oxygen supply (+72%). These latter effects resulted in reduction in the coronary arteriovenous oxygen content difference and in an attendant rise in coronary sinus Po2 (+66%), which are signs of luxuriant myocardial perfusion.(ABSTRACT TRUNCATED AT 250 WORDS)     

In vitro and in vivo effects of hemodilution on kaolin-based activated clotting time predicted heparin requirement using a heparin dose–response technique

Purpose

The heparin dose–response (HDR) technique is based on activated clotting time (ACT) response to a fixed-dose heparin bolus, which varies substantially among patients. It is unclear, however, whether hemodilution-associated reductions in coagulation and anticoagulation factors affect the HDR slope.

Methods

For in vitro hemodilution, aliquots of whole blood from healthy volunteers were diluted 9:1 and 8:2 v/v with normal saline. For in vivo hemodilution, a prospective observational study was performed on 46 patients who underwent elective cardiovascular surgery with or without cardiopulmonary bypass. HDR slope, antithrombin (AT) activity, complete blood count, and other coagulation parameters were compared after induction of anesthesia and after hemodilution with 500 ml of intravenous fluid.

Results

In vitro 10 and 20 % hemodilution significantly increased the HDR slope relative to baseline, reducing the heparin requirement. Hemodilution of heparinized samples significantly prolonged ACT, whereas there was no significant change in non-heparinized blood. The percent changes in fibrinogen and AT activity were significantly greater at 20 % than those of the other coagulation variables. In vivo, hemodilution significantly increased the HDR slope and reduced heparin requirement. The percent change in fibrinogen due to hemodilution was significantly greater than the change in AT activity. Target ACTs of 300 and 450 s were not achieved in 83.3 and 53.8 % of patients, respectively.

Conclusion

In vitro and in vivo hemodilution significantly increased the HDR slope and reduced the requirement for heparin. In vitro, the HDR slope did not change in parallel but became steeper, depending on the degree of hemodilution.

     

Experimental studies on artificial blood usage for hemodilution during cardiopulmonary bypass.

BACKGROUND: Although hemodilution is usually utilized during cardiopulmonary bypass (CPB), hemodilution can cause adverse effects such as hypotension and hypoxia. The purpose of this study was to evaluate a novel perfluoro-octyl bromide (PFOB) emulsion, one of perfluorochemicals (PFCs) emulsions, administered during hemodilution CPB. METHODS: Fifteen dogs were subjected to CPB for 2 hours under mild hypothermia. Animals were divided into three groups; control group, hemodilution group and PFOB group. During the experiment, hemodynamics, complete blood count and blood chemistry were monitored. In addition, serum complement titer (CH50), bradykinin and histamine concentrations were also measured. RESULTS: Heart rate (HR) was markedly elevated in the hemodilution groups (p<0.05). Mean arterial pressure (MAP) did not change in the three groups. White blood cell (WBC) and platelet (PLT) count did not significantly differ among the three groups. Plasma lactate concentration was markedly elevated only in hemodilution group during late phase of CPB (p<0.05). In the hemodilution group, CH50, bradykinin and histamine, were markedly elevated during the CPB and just after CPB (p<0.05). CONCLUSIONS: The present study demonstrated possible benefits of the new PFC emulsion during cardiac surgery by counteracting the adverse effects of hemodilution during CPB.     

Isovolemic hemodilution in experimental focal cerebral ischemia. Part 2: Effects on regional cerebral blood flow and size of infarction

Seventy-six splenectomized dogs were entered in a study of the value and effects of isovolemic hemodilution. Of these, seven were not included in the analysis because of technical errors. Of the remaining 69 dogs, 35 were treated with hemodilution; 28 were subjected to a 6-hour period of temporary occlusion of the distal internal carotid artery and the proximal middle cerebral artery, and seven underwent a sham operation only, with arterial manipulation but no occlusion. The other 34 dogs were not subjected to hemodilution; 26 of these underwent temporary arterial occlusion and eight had a sham operation only. In each group the animals were about equally divided into 1) an acute protocol with regional cerebral blood flow measurements by a radioactive microsphere technique and sacrifice at the end of the acute experiment, and 2) a chronic protocol with survival for 1 week to permit daily neurological assessment and final histopathological examination but without blood flow measurements. The general experimental protocol, the hemodynamic and rheological measurements, and the changes in intracranial pressure are described in Part 1 of this report. In the animals with arterial occlusion, blood flow decreased significantly in the territory of the ischemic middle cerebral artery. This decrease was partially reversed by hemodilution in the animals so treated. When the changes in blood flow before and after hemodilution in treated animals are compared with the changes at equivalent times in animals without hemodilution, the increases in flow in the gray matter of the ischemic hemisphere brought about by hemodilution are statistically significant. The neurological condition of the animals in the chronic protocol (sacrificed 1 week after occlusion) with hemodilution, as evaluated by daily neurological assessment, was significantly better than that of the control animals. In the animals sacrificed acutely (8 hours after arterial occlusion), the volume of infarction as estimated by the tetrazolium chloride histochemical method was 7.36% of the total hemispheric volume in the control animals and 1.09% in the hemodiluted animals, showing a statistically significant difference (p less than 0.005). In the chronic animals these values were 9.84% and 1.26%, respectively (p less than 0.005), as calculated by fluorescein staining. By histopathological examination the volume of infarction in the chronic animals was calculated as 10.92% in the control animals and 1.20% in the hemodiluted animals (p less than 0.005).(ABSTRACT TRUNCATED AT 400 WORDS)     

Giant hemangioma of the tongue: combined use of perioperative blood conservation procedures

A giant hemangioma of the tongue was resected in a 16-year-old otherwise healthy young man (ASA I). Despite a total blood loss of 4,300 ml, corresponding to 105% of the patients intravascular blood volume, no allogeneic red blood cells had to be transfused intraoperatively. Besides minimization of intraoperative blood loss with preoperative alcohol injections into the tumor, ligation of large tumor-perfusing arteries, application of fibrin glue, skillful surgical technique, positioning of the surgical field above the level of the heart, controlled hypotension and maintenance of normothermia, acute normovolemic hemodilution (augmented by preoperative administration of recombinant human erythropoetin - rhEpo) and autotransfusion of lost blood were used for recovery of autologous blood. Under the protection of hyperoxia, a decrease of the hemoglobin (Hb) concentration to 4.2 g/dl was bridged by extreme normovolemic hemodilution. No signs of immanent or manifest tissue hypoxia were encountered. Retransfusion of autologous red blood cells was only started when surgical control of bleeding was achieved. Additionally a total of 4 units of fresh frozen plasma were infused for stabilization of plasma coagulation.After a 9-hour surgical duration, the patient was transferred to the intensive care unit, normotensive (with low-dose infusion of norepinephrin) and normothermic with a Hb concentration of 5.6 g/dl. In the face of an increasing lactacidosis 2 units of packed red blood cells were transfused on post surgical day 1.     

Autotransfusion following cardiac operations: a randomized, prospective study.

To evaluate the safety and effectiveness of the collection and retransfusion of postoperatively shed mediastinal blood as part of a multifaceted approach to blood conservation following cardiac operation, 113 patients were randomized into either an autotransfusion group (54 patients) or a control group (59 patients). Intraoperative and postoperative hemodilution was practiced in all patients. The clinical safety of this technique was confirmed by the lack of septic, hematological, pulmonary, renal, or hepatic complications. However, in this setting where blood conservation is already aggressively practiced, the ability of the technique to further reduce the use of banked blood following cardiac surgical procedures was not demonstrated.     

Efficacy of Acute Normovolemic Hemodilution Assessed as a Function of Fraction of Blood Volume Lost

Background: It has been recommended that intraoperative acute normovolemic hemodilution (ANH) be considered for patients expected to experience surgical blood loss of 20% or more of their blood volume. Previous mathematical analyses have not evaluated the potential efficacy of ANH in terms of fraction of blood volume lost. Since decrease of oxygen-carrying capacity is a function of erythrocyte loss relative to blood volume, the purpose of this analysis was to provide an assessment of ANH applicable to all blood volumes and to determine whether this recommendation is appropriate.

Methods: Equations were developed to describe the fractional blood volume loss (blood volume loss/blood volume; VRem/VBld) required to reduce hematocrit below a "trigger" hematocrit with maintenance of isovolemia. This is also the minimum fractional blood volume loss required for initial erythrocyte savings by any conservation technique. Equations were also developed to describe the fractional surgical blood volume loss for which ANH will obviate the need for transfusion of erythrocytes from any source other than those removed by ANH, and the fractional surgical blood volume loss required for ANH to save a defined volume of erythrocytes.

Results: Acute normovolemic hemodilution can extend the allowable fractional surgical blood loss before erythrocyte transfusion is required. The VRem/VBld required to initiate erythrocyte savings is approximately 0.5-0.9. The efficacy of ANH in terms of erythrocytes saved cannot be expressed as a function of the fractional blood volume lost alone. To save 1 unit of erythrocytes requires a fractional surgical blood loss of approximately 0.7-1.2 for the usual surgical patient when the transfusion trigger hematocrit is 0.18-0.21.