Combined Platelet and Erythrocyte Salvage: Evaluation of a New Filtration-based Autotransfusion Device.

BACKGROUND: The SAME device (i-SEP, France) is an innovative filtration-based autotransfusion device able to salvage and wash both red blood cells and platelets. This study evaluated the device performances using human whole blood with the hypothesis that the device will be able to salvage platelets while achieving a erythrocyte yield of 80% and removal ratios of 90% for heparin and 80% for major plasma proteins without inducing signification activation of salvaged cells. METHODS: Thirty healthy human whole blood units (median volume, 478 ml) were diluted, heparinized, and processed by the device in two consecutive treatment cycles. Samples from the collection reservoir and the concentrated blood were analyzed. Complete blood count was performed to measure blood cell recovery rates. Flow cytometry evaluated the activation state and function of platelets and leukocytes. Heparin and plasma proteins were measured to assess washing performance. RESULTS: The global erythrocyte yield was 88.1% (84.1 to 91.1%; median [25th to 75th]) with posttreatment hematocrits of 48.9% (44.8 to 51.4%) and 51.4% (48.4 to 53.2%) for the first and second cycles, respectively. Ektacytometry did not show evidence of erythrocyte alteration. Platelet recovery was 36.8% (26.3 to 43.4%), with posttreatment counts of 88 × 109/l (73 to 101 × 109/l) and 115 × 109/l (95 to 135 × 109/l) for the first and second cycles, respectively. Recovered platelets showed a low basal P-selectin expression at 10.8% (8.1 to 15.2%) and a strong response to thrombin-activating peptide. Leukocyte yield was 93.0% (90.1 to 95.7%) with no activation or cell death. Global removal ratios were 98.3% (97.8 to 98.9%), 98.2% (96.9 to 98.8%), and 88.3% (86.6 to 90.7%) for heparin, albumin, and fibrinogen, respectively. The processing times were 4.4 min (4.2 to 4.6 min) and 4.4 min (4.2 to 4.7 min) for the first and second cycles, respectively. CONCLUSIONS: This study demonstrated the performance of the SAME device. Platelets and red blood cells were salvaged without significant impact on cell integrity and function. In the meantime, leukocytes were not activated, and the washing quality of the device prevented reinfusion of high concentrations of heparin and plasma proteins.

How do I perform cell salvage in obstetrics?

Maternal mortality in the United States is increasing. The leading cause of death is hemorrhage. Maternal hemorrhage can be profound, with entire blood volumes being lost. In most major blood loss surgery, autotranfusion (also known as cell salvage, cell saving, and intraoperative blood collection and readministration) is a technique that has been used to minimize allogeneic transfusion. Historically, autotransfusion has been considered contraindicated in the face of maternal hemorrhage because of a fear of incorporating amniotic fluid in the salvaged blood. Recent data suggests that this fear is unfounded, with several medical societies now recommending that autotransfusion be used during maternal hemorrhage. In this review, autotransfusion during maternal hemorrhage is discussed, and suggestions are made for how to make it most successful.

A comparison of haemostatic biomarkers during low-risk patients undergoing cardiopulmonary bypass using either conventional centrifugal cell salvage or the HemoSep device.

BACKGROUND: Cardiac surgery using cardiopulmonary bypass (CPB) is associated with a coagulopathy due to haemodilution, thrombocytopenia and platelet dysfunction and the activation of coagulation and fibrinolysis, despite the use of large doses of unfractionated heparin. Conventional red cell salvage may exacerbate post-operative bleeding as plasma containing haemostatic factors is discarded. We hypothesized that a novel cell salvage device (HemoSep) may attenuate haemostatic changes associated with red cell salvage. We studied haemostatic markers following autologous transfusion from conventional cell salvage or the HemoSep device. METHODS: This randomised, controlled trial compared haemostatic markers in patients undergoing coronary artery bypass grafting or aortic valve replacement who received autologous blood returned from cell salvage (control) or HemoSep (study). Blood samples were taken pre-operatively, end of CPB, post-transfusion of salvaged blood and 3 hours post-operatively and analysed for full blood count (FBC), prothrombin time (PT), activated partial thromboplastin time (aPTT), fibrinogen, D-dimer and endogenous thrombin potential (ETP). RESULTS: Fifty-four patients were recruited (n=28 control, n=26 study). Processed blood volume for transfusion was significantly (p<0.001) higher in the HemoSep group. In the HemoSep group, the PT was shorter (18.7±0.3 vs 19.9±0.3 sec; p<0.05) post-operatively and the aPTT was longer (48.6±3.8 vs 37.3±1.0 sec; p<0.01) following autologous transfusion. In the control group, D-dimer and ETP levels were higher (1903±424 vs.1088±151; p<0.05 and 739±46 vs. 394±60; p<0.001, respectively) following autologous transfusion. CONCLUSIONS: Although centrifuged cell salvage is known to adequately haemoconcentrate and remove unwanted substrates and bacteriological contamination, the process can exacerbate coagulopathy. The HemoSep device demonstrated some increase in haemostatic markers when used in low-risk cardiac surgery patients.

Platelet sequestration with a new-generation autotransfusion device.

BACKGROUND: Autologous platelet-rich plasma (PRP) can be used either to prevent platelets (PLTs) from lesions during extracorporeal circulation or for wound therapy, when processed into PLT gel. The aim of this study was to evaluate the PLT sequestration abilities of a new-generation autotransfusion device. STUDY DESIGN AND METHODS: In this experimental study the discontinuous, new-generation autotransfusion device XTRA was evaluated using fresh donor blood. The blood was processed in four different size bowls (X55, X125, X175, X225 [bowls' size in mL]) using the device's built-in "PLT sequestration program." PLT functionality was tested using aggregometry; for PLT activation, ß-thromboglobulin (ß-TG) and soluble P-selectin levels were determined. Cell damage was assessed by a morphology score and hypotonic shock response. Additionally, PLTs were tested after 6 hours to identify storage lesions. RESULTS: Platelet recovery in the PRP ranged from 39% to 64% and averaged 6.2-fold PLT enrichment as defined by the increase in PLT concentration. The preparation caused minimal cell damage and a decrease in cell function by only 10%, but a slight activation was observed amounting to 9% of the maximal ß-TG release. The efficiency of the preparation, represented by the PLT recovery rate, increased in a linear fashion with the increasing bowl sizes being tested. After 6 hours of storage the prepared PLTs showed an additional 9% loss in function, but only 4% decrease in viability. CONCLUSION: The autotransfusion device XTRA was capable of high-quality perioperative PRP preparation, and the bowl size was found to have an influence on the efficiency of the preparation.

Cell salvage using the continuous autotransfusion device CATSmart - an observational bicenter technical evaluation.

BACKGROUND: The use of cell salvage and autologous blood transfusion has become an important method of blood conservation. So far, there are no clinical data about the performance of the continuous autotransfusion device CATSmart. METHODS: In total, 74 patients undergoing either cardiac or orthopedic surgery were included in this prospective, bicenter and observational technical evaluation to validate red cell separation process and washout quality of CATSmart. The target of red cell separation process was defined as a hematocrit value in the packed red cell unit of 55-75% and of washout quality of 80-100% removal ratio. RESULTS: Hematocrit values measured by CATSmart and laboratory analysis were 78.5% [71.3%; 84.0%] and 73.7% [67.5%; 75.5%], respectively. Removal ratios for platelets 94.7% [88.2%; 96.7%], free hemoglobin 89.3% [85.2%; 94.9%], albumin 97.9% [96.6%; 98.5%], heparin 99.9% [99.9%; 100.0%], and potassium 92.5% [90.8%; 95.0%] were within the target range while removal of white blood cells was slightly worse 72.4% [57.9%; 87.3%]. CONCLUSION: The new autotransfusion device enables sufficient red cell separation and washout quality.

[Effect of autologous blood transfusion device on preventing blood loss in primary total knee arthroplasty using comprehensive hemostatic methods].

OBJECTIVE: To analyze the conventional application of using comprehensive hemostatic methods during the perioperative period, and the effect of autologous blood transfusion (ABT) device compared with non-negative pressure drainage on preventing blood loss and allogenic blood transfusion after primary total knee arthroplasty (TKA). METHODS: A total of 131 patients (131 knees) with severe knee osteoarthritis who underwent unilateral primary TKA by the same surgeon in Peking University Third Hospital from June 2014 to June 2015 were enrolled in this study. The patients were divided into ABT group (64 patients) and control group (67 patients). ABT devices were used for drainage and blood transfusion in the ABT group while the control group used the non-negative pressure drainage only. The results of the drainage fluid volume, the decrease of hemoglobin, the total blood loss, the hidden blood loss and blood transfusion after TKA were compared between the two groups. RESULTS: The drainage fluid volume in ABT group was significantly higher than that in control group [515 mL (80-1 610 mL) vs. 260 mL (40-670 mL), P<0.001]. The autologous blood transfusion in ABT group was 245 mL (60-1 070 mL). There were no significant differences between the two groups in the value of hemoglobin decrease 1 day after surgery (P=0.340) and 3 days after surgery (P=0.524). There were no significant differences in the total blood loss (P=0.101) and the hidden blood loss (P=0.062) between the two groups either. There were 9 patients in the 131 patients who received allogeneic blood transfusion, of whom 5 in the ABT group (5/64, the blood transfusion rate was 7.8%) and 4 in the control group (4/67, the blood transfusion rate was 6.0%), and no significant differences in the blood transfusion rate between the two groups (P=0.943). CONCLUSION: With the conventional application of using comprehensive hemostatic methods during perioperative period, the ABT device did not show the effective result of controlling postoperative blood loss and failed to reduce the rate of allogeneic blood transfusion in patients with unilateral primary TKA. However, the ABT device could increase the drainage fluid volume and improve the patient's hospitalization expenses. Therefore, there is no need for routine application of ABT device in unilateral primary TKA.

Development of a portable blood salvage and autotransfusion technology to enhance survivability of personnel requiring major medical interventions in austere or military environments.

INTRODUCTION: Uncontrolled haemorrhage is the leading cause of death on the battlefield, and two-thirds of these deaths result from non-compressible haemorrhage. Blood salvage and autotransfusion represent an alternative to conventional blood transfusion techniques for austere environments, potentially providing blood to the casualty at point of injury. The aim of this paper is to describe the design, development and initial proof-of-concept testing of a portable blood salvage and autotransfusion technology to enhance survivability of personnel requiring major medical interventions in austere or military environments. METHOD: A manually operable, dual-headed pump was developed that removes blood from site of injury to a collection reservoir (upper pump) and back to casualty (lower pump). Theoretical flow rate calculations determined pump configuration and a three-dimensionally printed peristaltic pump was manufactured. Flow rates were tested with fresh bovine blood under laboratory conditions representative of the predicted clinical environment. RESULTS: Mathematical modelling suggested flow rates of 3.6 L/min and 0.57 L/min for upper and lower pumps. Using fresh bovine blood, flow rates produced were 2.67 L/min and 0.43 L/min. To mimic expected battlefield conditions, upper suction pump flow rate was calculated using a blood/air mixture. CONCLUSION: The authors believe that this technology can potentially enhance survivability for casualties in austere and deployed military settings through autotransfusion and cell concentration. It reduces negative effects of blood donation on the conventional donor pool, and potentially negates the logistical constraints associated with allogenic transfusions.

The role of intraoperative cell salvage system on blood management in major orthopedic surgeries: a cost-benefit analysis.

INTRODUCTION: The aim of this study was to compare the efficiency and cost of cell salvage systems with allogeneic blood transfusions in patients who had major elective orthopedic surgeries. MATERIALS AND METHODS: Consecutive 108 patients who had intraoperative cell saver (CS) performed routinely constitute the study group. In control group, consecutive 112 patients who were operated without intraoperative CS were investigated. Hemoglobin (Hb) level less than 8 mg/dL was regarded as the absolute transfusion indication. The patients were evaluated for age, gender, body mass index, operation period, mean intraoperative estimated blood loss (EBL), postoperative hemovac drainage volume; preoperative, postoperative first day and discharge Hb levels, allogeneic blood transfusion (ABT) volume, hospitalization and cost parameters. RESULTS: The mean intraoperative EBL was 507 mL in the study group and 576 mL in control group. The mean ABT was 300 mL in the study group and 715 mL in control group. In the study group, intraoperative EBL, ABT usage and hospitalization period were significantly lower compared with the control group (p = 0.009, p = 0.000 and p = 0.000; p < 0.05, respectively). The mean cost was 771 Turkish liras (TL) in the study group and 224 TL in control group. In the study group, the cost was significantly higher than the control group (p = 0.000). The postoperative first day Hb level was significantly higher in the study group (p = 0.010). CONCLUSION: Although CS usage was determined to increase the costs in this study, it significantly decreases intraoperative and postoperative ABT requirements. We believe that the increase in cost may be neglected when the complications and prolonged hospitalization due to ABT usage were regarded.

The impact of bowl size, program setup, and blood hematocrit on the performance of a discontinuous autotransfusion system.

BACKGROUND: Cell salvage is an essential element in the concept of blood management. Modern devices provide different bowl sizes and sensor-directed programs to optimally adjust to varying clinical situations. STUDY DESIGN AND METHODS: In an experimental performance study, the discontinuous autotransfusion device XTRA (LivaNova/Sorin) was evaluated using fresh donor blood anticoagulated with heparin 5 U/mL and adjusted to a hematocrit of 10% or 25%, representing orthopedic or cardiac surgery. Test blood was processed with the autotransfusion device XTRA in four different bowls (55 mL, 125 mL, 175 mL, and 225 mL) and in three different program modes (a standard program, an optimized program, and an emergency program). RESULTS: Processing speed increased with bowl size and with the emergency program (range, 6.4-29.8 mL red blood cells [RBCs]/min). The RBC recovery rate exceeded 90% for all bowls and programs except the 55-mL bowl with the emergency program. Plasma elimination exceeded 95% for all bowls and programs except the 225-mL bowl with the emergency and standard programs. Maximal RBC recovery (range, 94.7%-97.6%) and plasma elimination (range, 98.7%-99.5%) were obtained with the medium-sized bowls (125 mL and 175 mL) and the optimized program. Elimination rates for potassium or plasma free hemoglobin were consistently lower than for protein or albumin and were highest for heparin. CONCLUSIONS: Increased hematocrit and RBC recovery rates are obtained with the optimized program Popt with the discontinuous autotransfusion device. The emergency program Pem speeds up the process but leads to RBC loss and reduced plasma elimination rates; therefore, it should be restricted to emergency situations. All four different sized bowls have high performance. Plasma elimination is represented best by protein or albumin elimination rates.

Performance of a new-generation continuous autotransfusion device including fat removal and consequences for quality controls.

BACKGROUND AND OBJECTIVES: Cell salvage plays a key role in blood conservation. To maintain high performance, quality management is recommended. Accordingly, a new-generation autotransfusion device was tested for its performance and compared with its predecessor. Two different calculations of quality parameters were applied. MATERIALS AND METHODS: In an experimental study, the continuous autotransfusion devices CATSmart and Continuous Autotransfusion System (C.A.T.S) plus were tested using banked blood adjusted to a haematocrit of 20% and anticoagulated with heparin 5 U/L. Test blood was processed using an emergency programme, a high-quality programme/smart wash programme and a low-volume wash programme. Samples were taken after the production of 200 mL of red blood cells (RBC) and after the final emptying of the separation chamber. In an additional set of tests, blood containing 1·25% fat was processed with both devices to examine fat removal. RESULTS: Both devices demonstrated an equally high performance with regards to product hematocrit (Hct); RBC recovery; and elimination rates of protein, heparin and fat. The high fat elimination rate (>99·8%) reported for C.A.T.S plus was confirmed for CATSmart, regardless of the used programme. Samples taken during the ongoing process show a higher haematocrit and RBC recovery rate than samples taken after the final emptying of the separation chamber. Interface sensors were not affected by fat in the blood. CONCLUSIONS: The new-generation autotransfusion device CATSmart is not inferior to its predecessor and shows high performance with regards to RBC recovery, plasma and fat elimination in all programme modes. Samples for quality controls should be taken during blood processing.

Reinfusate Heparin Concentrations Produced by Two Autotransfusion Systems.

OBJECTIVES: Cell saver reinfusate ideally should contain low, clinically insignificant heparin concentrations. The American Association of Blood Banks has defined the clinically insignificant threshold as 0.5 IU/mL. Furthermore, there is uncertainty about the meaning of cell saver "heparin elimination rates." These concerns prompted the authors' independent investigation of reinfusate heparin concentrations of devices used in their institution. It was hypothesized that cell saver reinfusates contain clinically insignificant heparin concentrations. DESIGN: Two prospective, pragmatic, sequential, observational, single-center studies. SETTING: University teaching hospital. PARTICIPANTS: A total of 32 and 31 patients for on-pump cardiac surgery were enrolled in the Sorin (Dideco) Electa and Sorin Xtra studies, respectively. INTERVENTIONS: None. MEASUREMENTS AND MAIN RESULTS: Postcardiac surgery reinfusate heparin concentrations were measured using a modified anti-Xa chromogenic assay. Heparin concentrations above 0.5 IU/mL were present in 56% (95% confidence interval, 35% to 68%) of Sorin Xtra reinfusates. Heparin concentrations in the Sorin (Dideco) Electa reinfusates were lower than recommended in 29 of 32 reinfusates. Only 3 of 32 Sorin (Dideco) Electa reinfusates (9.4%; 95% confidence interval 3.2% to 24%) exhibited heparin concentrations exceeding 0.5 IU/mL. CONCLUSIONS: Sorin (Dideco) Electa reinfusates contained heparin concentrations below the American Association of Blood Banks recommended threshold in 90.6% of cases, while Sorin Xtra reinfusate heparin concentrations exceeded this recommendation in 56% of cases. Measurement of cell saver reinfusate heparin concentrations necessitates the use of a modified chromogenic assay. Studies explicitly should confirm that such a modification was indeed used. Periodic quality control of reinfusate composition is recommended.

In Vitro Evaluation of the Fresenius Kabi CATSmart Autotransfusion System.

Use of autotransfusion systems to collect, wash, and concentrate shed blood during surgical procedures is a widely used method for reducing postoperative anemia and the need for blood transfusions. The aim of this study was to evaluate the CATSmart Continuous Autotransfusion System wash program performance with small (200 or 700 mL) and large volumes (1,000 mL) of shed blood and to determine non-inferiority of the CATSmart to the C.A.T.S plus system. Human whole blood was collected in citrate phosphate dextrose, diluted, and divided into two aliquots to be processed as a pair using the C.A.T.S plus and CATSmart systems with their corresponding wash programs: low-volume, high quality/smart, or emergency wash. Final packed red cell product was analyzed for red blood cell (RBC), white blood cell, and platelet counts; hemoglobin; hemolysis; RBC recovery rates; and elimination of albumin, total protein, and potassium. The mean hematocrit (HCT) after processing with CATSmart and C.A.T.S plus systems were 59.63% and 57.71%, respectively. The calculated overall RBC recovery rates on the CATSmart and C.A.T.S plus systems were 85.41% and 84.99%, respectively. Elimination of albumin (97.5%, 98.0%), total proteins (97.1%, 97.5%), and potassium (92.1%, 91.9%) were also calculated for the CATSmart and C.A.T.S plus systems. The CATSmart and C.A.T.S plus systems both provided a high-quality product in terms of HCT, protein elimination, and hemolysis rates across the range of tested shed blood volumes and all wash programs. The study was able to confirm the CATSmart is non-inferior to the C.A.T.S plus system.

Fat removal during cell salvage: an optimized program for a discontinuous autotransfusion device.

BACKGROUND: Fat in wound blood observed in orthopedic or cardiac surgery might pose a risk for fat embolism during blood salvage. Fat removal was optimized in the washing process. STUDY DESIGN AND METHODS: In an experimental study blood from fresh donations was adjusted to a hematocrit (Hct) of 25% and an admixture of 1.25% human tissue fat. This blood was processed with the cell salvage device XTRA in a modified program mode. Volumetric quantification of fat was performed after centrifugation of blood samples in Pasteur pipettes. From the volumes, the Hct levels and the concentrations of fat and other variables elimination rates and RBC recovery were calculated. RESULTS: Pretests showed wash volume, wash flow, and process interruptions affecting fat elimination. With the new optimized fat elimination program Pfat removal rate of fat increased to 98.5 ± 0.9% for the 225-mL bowl. The product had a mean Hct of 48.7 ± 1.2% and a RBC recovery rate of 93.5 ± 2.3%. The program conserved the high elimination rates for albumin, heparin, potassium, and free plasma hemoglobin (98.8, 99.3, 95.3, and 94.9%, respectively). Similar high fat removal was also observed with bowls of smaller size, namely, 98.1% for the 175-mL bowl and 98.2% for the 125- and the 55-mL bowls. With test blood of Hct 10% a mean fat elimination of 99.6 ± 01% was observed. CONCLUSIONS: A special program modification Pfat involving extra washing and RBC concentration steps significantly improves fat removal by the Latham bowl-based autotransfusion device XTRA, thus yielding results equivalent to the continuous cell salvage system.

The Reinfusion of Autogenous Shed Blood After Unilateral Total Knee Arthroplasty Using the Perioperative Autologous Transfusion System OrthoPAT.

This study aims to explore the use of postoperative autogenous shed blood reinfusion using Orthopedic Perioperative Autotransfusion System (OrthoPAT) system in treating patients undergoing unilateral total knee arthroplasty (TKA). Fifty patients undergoing unilateral TKA were enrolled as the experimental group A and were treated with reinfusion of autologous shed blood within 6 hours after unilateral TKA using OrthoPAT. Accordingly, 50 patients undergoing unilateral TKA were selected as the experimental group B and were treated with allogeneic blood transfusion. Different indexes were observed at different times. Patients in both groups had relatively stable hemodynamics, and there was no postoperative coagulopathy. Prothrombin time, thrombin time, and activated partial thromboplastin time were lower, and fibrinogen was higher in group A than that in group B 24 hours after surgery (all P < 0.05). White blood cell, red blood cell, hemoglobin, hematocrit (Hct), and platelet count levels in group A were lower than those in group B 12 hours after surgery (all P < 0.05). The postoperative complications of the 2 groups have significant difference (P < 0.05). Postoperative autogenous shed blood reinfusion using OrthoPAT system in the treatment of patients undergoing unilateral TKA may improve the coagulation function of patients and reduce the rejection caused by standard allogeneic blood transfusion.

A Novel Centrifugation Method Using a Cell Salvage Device Offers an Alternative to the Use of Leukocyte-Depleting Filters for Autologous Blood Transfusions.

Autotransfusion protocols often use the use of costly filters, such as leukocyte-depleting filters (LDFs), to minimize reinfusion of activated leukocytes and inflammatory mediators associated with reperfusion injury (RI). LDFs are used extensively in hospital settings; however, they represent an additional capital expenditure for hospitals, as well as a constraint on the reinfusion rate of blood products for health-care providers. We compared a commonly used LDF to a novel centrifugation method employing a widely used cell salvage device. Complete blood counts and enzyme-linked immunosorbent assays (ELISAs) measuring tumor necrosis factor-α (TNF-α) and interleukin-2 (IL-2) were performed to compare the efficacy of these methodologies. The LDF removed, on average, 94% of all leukocytes, including 96% of neutrophils. The centrifugation method removed, on average, 89% of all leukocytes, including 91% of neutrophils and resulted in a highly concentrated red blood cell product. Our results suggest both methods offer equivalent leukocyte reduction. TNF-α was also comparably reduced following our novel centrifugation method and the LDF method and IL-2 levels were undetectable in all samples. These results indicate our novel centrifugation method may preclude the need for a LDF during select autotransfusion applications.

Efficacy of the RemoweLL cardiotomy reservoir for fat and leucocyte removal from shed mediastinal blood: a randomized controlled trial.

INTRODUCTION: Re-transfusion of lipid particles and activated leucocytes with shed mediastinal blood (SMB) can aggravate cardiopulmonary bypass-associated inflammation and increase the embolic load. This study evaluated the fat and leucocyte removal capacity of the RemoweLL cardiotomy reservoir. METHODS: Forty-five patients undergoing elective on-pump cardiac surgery were randomly allocated to filtration of SMB using the RemoweLL or the Admiral cardiotomy reservoir. The primary outcome was a drop in leucocytes and lipid particles obtained with the two filters. The effect of the filters on other blood cells and inflammatory mediators, such as myeloperoxidase (MPO), was also assessed. RESULTS: The RemoweLL cardiotomy filter removed 16.5% of the leucocytes (p<0.001) while no significant removal of leucocytes was observed with the Admiral (p=0.48). The percentage reductions in lipid particles were similar in the two groups (26% vs 23%, p=0.2). Both filters similarly affected the level of MPO (p=0.71). CONCLUSION: The RemoweLL filter more effectively removed leucocytes from SMB than the Admiral. It offered no advantage in terms of lipid particle clearance.

Haemoconcentration of residual cardiopulmonary bypass blood using Hemosep ®: a randomised controlled trial.

Cardiac surgery and cardiopulmonary bypass are associated with haemodilution, activation of haemostasis and blood transfusion. We undertook a randomised controlled trial that included 53 patients in order to compare autotransfusion of residual cardiopulmonary bypass blood with residual blood concentrated using the novel Hemosep(®) device. There was no difference in patients' mean (SD) haemoglobin concentration after autotransfusion of unprocessed blood compared with Hemosep; 103.5 (10.2) g.l(-1) vs 106.2 (12.4) g.l(-1), respectively, p = 0.40. The mean (SD) change in haemoglobin concentration after autotransfusion was 5.9 (5.3) g.l(-1) in the control group compared with 4.9 (6.3) g.l(-1) in the Hemosep group, p = 0.545. Adjusted for baseline haemoglobin concentrations, the estimated mean (95% CI) difference in change in haemoglobin concentration (control vs Hemosep) was 0.57 (-2.65 to 3.79) g.l(-1), p = 0.72. This was despite Hemosep's reducing the weight of the blood from a mean (SD) of 778.7 (243.0) g to 607.3 (248.2) g, p < 0.001. The haemoglobin concentration in the processed blood increased from a mean (SD) of 87.0 (15.1) g.l(-1) to 103.7 (17.4) g.l(-1), p < 0.001. We conclude that Hemosep is capable of haemoconcentration when employed to process residual cardiopulmonary bypass blood, but that this is insufficient to increase patient haemoglobin.

Evaluation of the minimum volume of salvage blood required for the successful use of two different autotransfusion devices.

BACKGROUND: Autotransfusion in pediatric anesthesia is beneficial in several clinical settings; however, more frequent usage is deterred by process-related costs and the fact that the absolute volume of blood returned may be minimal. OBJECTIVE: Two autotransfusion devices (CATS, Fresenius Kabi AG, and Sorin Xtra, Sorin GmbH) with different technologies were evaluated to determine the minimum volume necessary to efficiently process salvage blood. METHODS: Banked blood was diluted to simulate different clinical scenarios. Volume and red cell mass in returned blood were analyzed as a function of initial volume and red cell mass in the collection reservoir using incremental increases in the volume of blood added to the reservoir. RESULTS: The volume of the returned processed blood for infusion was dependent on degree of dilution and blood volume in the reservoir. The CATS required a smaller initial minimum volume to process and successfully return; however, the Xtra provided a more efficient recovery at low initial collected volumes. Using test blood of various degrees of dilution, the CATS and Xtra were able to return blood for retransfusion after a mean initial red cell mass of 48.7 ml (±4.9 ml) and 53.7 ml (±5.0 ml) were processed, respectively. CONCLUSIONS: Red cell mass rather than salvaged blood volume represents a reliable predictor of the successful use of an autotransfusion device. Measuring the hematocrit of the salvaged blood could improve the use of the devices. The investigated devices are likely to be roughly equivalent in effectiveness.

Electrolyte and acid/base changes in dogs undergoing autologous blood transfusion via a cell salvage device.

This study reports electrolyte and acid/base disturbances observed in clinical cases receiving autologous transfusion of blood processed by a cell salvage device. The records of 12 client-owned dogs that received an autologous transfusion via a cell salvage device with pre- and post-autologous transfusion blood work available were reviewed. Blood work from the 12 case dogs was compared to blood work from 12 control dogs with similar diseases. Control dogs received similar surgical treatment and were administered a similar volume per kg of packed red blood cells as case dogs, but did not undergo autologous transfusion. Case dogs that received autologous transfusion via a cell salvage device were significantly more likely to experience a decrease in ionized calcium and magnesium levels post-transfusion than were control dogs. Calcium and magnesium levels should be closely monitored during and after autologous transfusion. Calcium and/or magnesium supplementation may be required.

Changements électrolytiques et acido-basiques chez les chiens subissant une transfusion sanguine autologue à l'aide d'un dispositif de récupération des cellules. Cette étude signale les perturbations électrolytiques et acido-basiques observées dans des cas cliniques recevant une transfusion de sang autologue traitée à l'aide d'un dispositif de récupération des cellules. On a évalué les dossiers de 12 chiens, appartenant à des propriétaires, qui avaient reçu une transfusion autologue à l'aide d'un dispositif de récupération des cellules et avaient subi des analyses sanguines avant et après la transfusion autologue. Les analyses sanguines des 12 chiens ont été comparées aux analyses de 12 chiens témoins atteints de maladies semblables. Les chiens témoins ont reçu des traitements chirurgicaux semblables et un volume semblable par kg de concentré de globules rouges que les chiens du cas, mais n'ont pas subi la transfusion autologue. Il était significativement plus probable que les chiens du cas qui avaient reçu une transfusion autologue à l'aide d'un dispositif de récupération des cellules subissent une baisse du niveau de calcium ionisé et de magnésium après la transfusion que les chiens témoins. Le niveau de calcium et de magnésium devrait être étroitement surveillé durant et après la transfusion autologue. Des suppléments de calcium et/ou de magnésium pourront être requis.(Traduit par Isabelle Vallières).

Processing of small volumes in blood salvage devices.

BACKGROUND: New technical developments such as a small Latham bowl, a continuous autotransfusion system, and a dynamic disk designed for postoperative autotransfusion raise hopes for a possible application of blood salvage in young children. However, the minimal blood volume for effective processing under clinically relevant conditions has yet to be determined. STUDY DESIGN AND METHODS: Fresh blood from volunteer donations adjusted to a hematocrit (Hct) of 10% was used to test ELECTA (Sorin) equipped with a 55-mL bowl, C.A.T.S (Fresenius) in the pediatric program mode, and OrthoPAT (Haemonetics). Twenty-milliliter portions of red blood cells (RBCs) were added and processed under various conditions, including clinically relevant first filling and intermittent emptying. RBC recovery and availability and plasma elimination were calculated from the Hct, free hemoglobin, and total protein. RESULTS: The main impediment to recovery and availability was the first filling. There, RBC recovery was significantly reduced, while it subsequently varied between 93 and 98%. To produce the first 30 mL of RBCs, ELECTA required 42 mL and C.A.T.S and OrthoPAT 62 mL owing to the dead space of the separation chamber or reservoir, respectively. RBC availability was much higher in subsequent processes, with only minimal differences between the three devices. They all consistently provided high plasma elimination rates. CONCLUSION: The continuous system showed no advantage over a small Latham bowl. From the results it can be calculated that the limit for feasible cell salvage at present is an infant of 6 months. All three devices are suitable for the processing of small volumes, but have the scope for further optimization.