Effects of drotrecogin alfa activated on microcirculatory alterations in patients with severe sepsis

OBJECTIVE: Microvascular alterations may play an important role in the development of sepsis-induced organ dysfunction. Drotrecogin alfa activated (DAA) improves outcome in patients with severe sepsis, but its precise mechanism of action is not entirely defined. We investigated whether DAA can influence microcirculatory alterations in patients with severe sepsis. DESIGN: Prospective, nonrandomized study. SETTING: A 31-bed, medico-surgical intensive care unit of a university hospital. PATIENTS: Forty adult patients with severe sepsis who met the EU criteria for DAA administration. INTERVENTIONS: Twenty patients received the drug (DAA) and 20 had a contraindication to DAA administration (control). MEASUREMENTS AND MAIN RESULTS: An orthogonal polarization spectral imaging technique was used to visualize the sublingual microcirculation. In all patients, measurements were obtained at baseline, 4 hrs later, and then every 24 hrs for up to 7 days. In patients receiving DAA, measurements were also obtained just before and 4 hrs after the end of DAA infusion. The two groups were well matched for severity of disease, number of failing organs, and the degree of microvascular alterations at baseline. The proportion of perfused capillaries increased in the DAA treated patients already at 4 hrs (from 64% [51-80%] to 84% [71-88%], p < .01) but not in the control group (from 67% [59-76%] to 68% [61-71%], p = not significant). Microvascular perfusion decreased transiently at the end of DAA infusion. The improvement in microvascular blood flow was associated with a more rapid resolution of hyperlactatemia. CONCLUSIONS: DAA administration rapidly improves sepsis-induced microvascular alterations, whereas its cessation is associated with a transient deterioration.     

Microvascular response to red blood cell transfusion in trauma patients

Trauma patients are often transfused allogeneic red blood cells (RBCs) in an effort to augment tissue oxygen delivery. However, the effect of RBC transfusion on microvascular perfusion in this patient population is not well understood. To this end, we investigated the effect of RBC transfusion on sublingual microvascular perfusion in trauma patients. Sublingual microcirculation was imaged at bedside with a sidestream dark-field illumination microscope before and after transfusion of one RBC unit in hemodynamically stable, anemic trauma patients. The perfused proportion of capillaries (PPC) before and after transfusion was determined, and the percent change in capillary perfusion following transfusion (ΔPPC) calculated. Sublingual microcirculation was observed in 30 patients. Mean age was 47 (SD, 21) years, mean Injury Severity Score was 29 (SD, 16), and mean pretransfusion hemoglobin was 7.5 (SD, 0.9) g/dL. No patients had a mean arterial pressure of less than 65 mmHg (mean, 89 [SD, 17] mmHg) or lactate of greater than 2.5 mmol/L (mean, 1.1 [SD, 0.3] mmol/L). Following transfusion, ΔPPC ranged from +68% to -36% and was found to inversely correlate significantly with pretransfusion PPC (Spearman r = -0.63, P = 0.0002). Pretransfusion PPC may be selectively deranged in otherwise stable trauma patients. Patients with relatively altered baseline PPC tend to demonstrate improvement in perfusion following transfusion, whereas those with relatively normal perfusion at baseline tend to demonstrate either no change or, in fact, a decline in PPC. Bedside sublingual imaging may have the potential to detect subtle perfusion defects and ultimately inform clinical decision making with respect to transfusion.     

Effects of diagnostic cardiac ultrasound on oxygen free radical production and microvascular perfusion during ischemia reperfusion

Diagnostic ultrasound (US) is reported to increase intracellular oxidative stress in vitro. Increased oxidative stress mediated ischemia-reperfusion injury in the microcirculation. To examine the effects of US in hamster cheek pouch microcirculation during baseline and ischemia and reperfusion (I/R), I/R injury was provoked in the cheek pouch under "sham" (transducer off, group 1) and active US irradiation (group 2) at baseline (15 min) and at the beginning (15 min) of the reperfusion after ischemia (30 min). US transmission was delivered in the harmonic mode (2.5 MHz) with 1.3 mechanical index (MI) and 2.0 peak negative pressure. Microvascular damage was evaluated by measuring arterial diameter, red blood cell velocity, wall shear stress, permeability, perfused capillary length and adherent leukocytes in venules. Lipid peroxides were determined in the systemic blood. US increased permeability (baseline: 0.04 +/- 0.02; after US 0.30 +/- 0.04, p < 0.01) and slightly decreased capillary perfusion by 7% during baseline (p < 0.01). Arteriolar diameter (35 +/- 7 microm vs. 20 +/- 5 microm, p < 0.05), RBC velocity (2.8 +/- 0.4 mm s(-1) vs. 0.75 +/- 0.05 mm s(-1), p < 0.05) and shear stress ( 0.76 +/- 0.09 Pa vs. 0.36 +/- 0.05 Pa, p < 0.05) decreased significantly after reperfusion. These parameters increased by 40, 64 and 33%, respectively after US. Leukocyte adhesion decreased by 31 % (p < 0.05) after US and lipid peroxides decreased by 26% and 51% during baseline and 15 min of reperfusion after US, respectively. In conclusion, diagnostic US increased microvascular permeability during baseline and reperfusion. Moreover, US enhanced wall shear stress and reduced oxidative stress during postischemic reperfusion; thus, increasing capillary perfusion.     

Microcirculatory effects of the transfusion of leukodepleted or non-leukodepleted red blood cells in patients with sepsis: a pilot study

Introduction

Microvascular alterations impair tissue oxygenation during sepsis. A red blood cell (RBC) transfusion increases oxygen (O₂) delivery but rarely improves tissue O₂ uptake in patients with sepsis. Possible causes include RBC alterations due to prolonged storage or residual leukocyte-derived inflammatory mediators. The aim of this study was to compare the effects of two types of transfused RBCs on microcirculation in patients with sepsis.

Methods

In a prospective randomized trial, 20 patients with sepsis were divided into two separate groups and received either non-leukodepleted (n = 10) or leukodepleted (n = 10) RBC transfusions. Microvascular density and perfusion were assessed with sidestream dark field (SDF) imaging sublingually, before and 1 hour after transfusions. Thenar tissue O₂ saturation (StO₂) and tissue hemoglobin index (THI) were determined with near-infrared spectroscopy, and a vascular occlusion test was performed. The microcirculatory perfused boundary region was assessed in SDF images as an index of glycocalyx damage, and glycocalyx compounds (syndecan-1, hyaluronan, and heparan sulfate) were measured in the serum.

Results

No differences were observed in microvascular parameters at baseline and after transfusion between the groups, except for the proportion of perfused vessels (PPV) and blood flow velocity, which were higher after transfusion in the leukodepleted group. Microvascular flow index in small vessels (MFI) and blood flow velocity exhibited different responses to transfusion between the two groups (P = 0.03 and P = 0.04, respectively), with a positive effect of leukodepleted RBCs. When within-group changes were examined, microcirculatory improvement was observed only in patients who received leukodepleted RBC transfusion as suggested by the increase in De Backer score (P = 0.02), perfused vessel density (P = 0.04), PPV (P = 0.01), and MFI (P = 0.04). Blood flow velocity decreased in the non-leukodepleted group (P = 0.03). THI and StO₂ upslope increased in both groups. StO₂ and StO₂ downslope increased in patients who received non-leukodepleted RBC transfusions. Syndecan-1 increased after the transfusion of non-leukodepleted RBCs (P = 0.03).

Conclusions

This study does not show a clear superiority of leukodepleted over non-leukodepleted RBC transfusions on microvascular perfusion in patients with sepsis, although it suggests a more favorable effect of leukodepleted RBCs on microcirculatory convective flow. Further studies are needed to confirm these findings.

Trial registration

ClinicalTrials.gov, {"type":"clinical-trial","attrs":{"text":"NCT01584999","term_id":"NCT01584999"}}NCT01584999     

Blood transfusions recruit the microcirculation during cardiac surgery

BACKGROUND: Perioperative red blood cell transfusions are commonly used in patients undergoing cardiac surgery to correct anemia caused by blood loss and hemodilution associated with cardiopulmonary bypass circulation. The aim of this investigation was to test the hypothesis that blood transfusion has beneficial effects on sublingual microcirculatory density, perfusion, and oxygenation. To this end, sidestream dark field (SDF) imaging and spectrophotometry were applied sublingually before and after blood transfusion during cardiac surgery. STUDY DESIGN AND METHODS: Twenty‐four adult patients undergoing on‐pump cardiac surgery, including coronary artery bypass grafting, cardiac‐valve surgery, or a combination of these two procedures, were included consecutively in this prospective, observational study. Sublingual microcirculatory density and perfusion were assessed using SDF imaging in 12 patients (Group A). Sublingual reflectance spectrophotometry was applied in 12 patients (Group B) to monitor microcirculatory oxygenation and hemoglobin (Hb) concentration. RESULTS: Blood transfusion caused an increase in systemic Hb concentration (p < 0.01) and hematocrit (p < 0.01). At the microcirculatory level, blood transfusion resulted in increased microcirculatory density (from 10.5 ± 1.2 to 12.9 ± 1.2 mm capillary/mm² tissue, p < 0.01) as shown using SDF imaging. In concert with the SDF measurements, spectrophotometry showed that microcirculatory Hb content increased from 61.4 ± 5.9 to 70.0 ± 4.7 AU (p < 0.01) and that microcirculatory Hb oxygen saturation increased from 65.6 ± 8.3% to 68.6 ± 8.4% (p = 0.06). CONCLUSION: In this study we have shown that blood transfusion: 1) improves the systemic circulation and oxygen‐carrying capacity, 2) improves sublingual microcirculatory density but not perfusion velocity, and 3) improves microcirculatory oxygen saturation.     

Microvascular blood flow during cardiopulmonary resuscitation is predictive of outcome

There is growing evidence that microcirculatory blood flow is the ultimate determinant of the outcome in circulatory shock states. We therefore examined changes in the microcirculation accompanying the most severe form of circulatory failure, namely cardiac arrest and the effects of subsequent cardiopulmonary resuscitation. Ventricular fibrillation was electrically induced in nine pigs and untreated for 5min prior to beginning closed chest cardiac compression and attempting electrical defibrillation. Orthogonal polarization spectral imaging was utilized for visualization of the sublingual microcirculation at baseline, 0.5, 1, 3 and 5min after onset of ventricular fibrillation and at 1 and 5min after start of chest compression. Images were also obtained 1 and 5min after restoration of spontaneous circulation. Microvascular flow was graded from 0 (no flow) to 3 (normal flow). Aortic and right atrial pressures were measured and coronary perfusion pressure was computed continuously. Microcirculatory blood flow decreased to less than one-fourth within 0.5min after inducing ventricular fibrillation. Precordial compression partially restored microvascular flow in each animal. In animals that were successfully resuscitated, microvascular flow was significantly greater after 1 and 5min of chest compression than in animals with failed resuscitation attempts. Microvascular blood flow was highly correlated with coronary perfusion pressure (r=0.82, p<0.01). Microvascular blood flow in the sublingual mucosa is therefore closely related to coronary perfusion pressure during cardiopulmonary resuscitation and both are predictive of outcome.     

Efficacy of recombinant human erythropoietin in critically ill patients admitted to a long-term acute care facility: a randomized, double-blind, placebo-controlled trial

CONTEXT: Anemia is common in the critically ill and results in a large number of red blood cell transfusions. Recent data have shown that red blood cell transfusions in critically ill patients can be decreased with recombinant human erythropoietin (rHuEPO) therapy during their intensive care unit stay. OBJECTIVE: To assess the efficacy of rHuEPO therapy in decreasing the occurrence of red blood cell transfusions in patients admitted to a long-term acute care facility (LTAC). DESIGN: A prospective, randomized, double-blind, placebo-controlled, multiple-center trial. SETTING: Two long-term acute care facilities. PATIENTS: A total of 86 patients who met eligibility criteria were enrolled in the study with 42 randomized to rHuEPO and 44 to placebo. INTERVENTIONS: Study drug (rHuEPO 40,000 units) or a placebo was administered by subcutaneous injection before day 7 of long-term acute care facility admission and continued weekly for up to 12 doses. MAIN OUTCOME MEASURES: The primary efficacy end point was cumulative red blood cell units transfused. Secondary efficacy end points were the percent of patients receiving any red blood cell transfusion; the percent of patients alive and transfusion independent; cumulative mortality; and change in hematologic variables from baseline. Logistic regression was used to adjust the odds ratio for red blood cell transfusion. All end points were assessed at both study day 42 and study day 84. RESULTS: The baseline hemoglobin level was higher in the rHuEPO group (9.9 +/- 1.15 g/dL vs. 9.3 +/- 1.41 g/dL, p = .02) as was the pretransfusion hemoglobin level (8.0 +/- 0.5 g/dL vs. 7.5 +/- 0.8 g/dL, p = .04). At day 84, patients receiving rHuEPO received fewer red blood cell transfusions (median units per patient 0 vs. 2, p = .05), and the ratio of red blood cell transfusion rates per day alive was 0.61 with 95% confidence interval of 0.2, 1.01, indicating a 39% relative reduction in transfusion burden for the rHuEPO group compared with placebo. There was also a trend at day 84 toward a reduction in the total units of red blood cells transfused in the rHuEPO group (113 units of placebo vs. 73 units of rHuEPO). Patients receiving rHuEPO were also less likely to be transfused (64% placebo vs. 41% rHuEPO, p = .05; adjusted odds ratio 0.47, 95% confidence interval 0.19, 1.16). Most of the transfusion benefit of rHuEPO occurred by study day 42. Increase in hemoglobin from baseline to final was greater in the rHuEPO group (1.0 +/- 2 g/dL vs. 0.4 +/- 1.7 g/dL, p < .001). Mortality rate (19% rHuEPO, 29.5% placebo, p = .17; relative risk, 0.55, 95% confidence interval 0.21-1.43) and serious adverse clinical events (38 % rHuEPO, 32% placebo, p = .65) were not significantly different between the two groups. CONCLUSIONS: In patients admitted to a long-term acute care facility, administration of weekly rHuEPO results in a significant reduction in exposure to allogeneic red blood cell transfusion during the initial 42 days of rHuEPO therapy, with little additional benefit achieved with therapy to 84 days. Despite receiving fewer red blood cell transfusions, patients treated with rHuEPO achieve a higher hemoglobin level.     

Transfusion-related leukocytosis in critically ill patients

OBJECTIVE: We observed that many critically ill patients developed leukocytosis following blood transfusions. To validate this observation and to explore a possible mechanism, a prospective study was designed. DESIGN: Prospective, non-interventional study. SETTING: Surgical/medical intensive care unit in a university-affiliated community hospital. PATIENTS: Consecutive patients who required packed red blood cells transfusion. INTERVENTIONS: White blood cell count (mean +/- SD) x 10(9)/L before and 2, 4, 6, 12, and 24 hrs following transfusion of non-filtered packed red cells was measured in 96 patients. MEASUREMENTS AND MAIN RESULTS: Twenty patients were septic at the time of transfusion, whereas 76 were not. The incidence of post-transfusion leukocytosis in septic vs. nonseptic patients was 15% vs. 76%, respectively (p <.001). The white blood cell count in nonseptic patients increased from 14.3 +/- 4.8 before transfusion to 19.5 +/- 7.0 2 hrs following transfusion (p <.001) and returned to baseline in 24 hrs. In the septic group, no significant post-transfusion leukocytosis occurred. In 11 nonseptic patients requiring more than one unit of packed red cells, a significant increase in mean white blood cell count occurred 2 hrs after transfusion with non-filtered packed red cells, whereas transfusion with pre-storage-filtered packed red cells did not result in such an increase. Interleukin-8 concentrations (pg/mL) in stored non-filtered packed red cells were significantly higher after 4 wks of storage (745.5 +/- 710, p =.02) than at weeks 1 (61.2 +/- 21.6) and 2 (59.3 +/- 29). In the last 16 nonseptic patients, the units of non-filtered packed red cells were assayed for interleukin-8 immediately before transfusion. Interleukin-8 concentrations were higher in units that caused leukocytosis in the recipients compared with those that did not (408.4 +/- 202 vs. 65.1 +/- 49, p =.02). CONCLUSIONS: Transfusion of non-filtered packed red cells, but not of pre-storage-filtered packed red cells, may frequently cause an acute and transient leukocytosis in critically ill nonseptic patients. Interleukin-8 accumulating in stored non-filtered packed red cells may play a role in this phenomenon. Recognition of post packed red cell transfusion leukocytosis may avoid unnecessary investigations and therapies in false suspicion of sepsis.     

Bench-to-bedside review: microvascular dysfunction in sepsis--hemodynamics,oxygen transport,and nitric oxide

The microcirculation is a complex and integrated system that supplies and distributes oxygen throughout the tissues. The red blood cell (RBC) facilitates convective oxygen transport via co-operative binding with hemoglobin. In the microcirculation oxygen diffuses from the RBC into neighboring tissues, where it is consumed by mitochondria. Evidence suggests that the RBC acts as deliverer of oxygen and 'sensor' of local oxygen gradients. Within vascular beds RBCs are distributed actively by arteriolar tone and passively by rheologic factors, including vessel geometry and RBC deformability. Microvascular oxygen transport is determined by microvascular geometry, hemodynamics, and RBC hemoglobin oxygen saturation. Sepsis causes abnormal microvascular oxygen transport as significant numbers of capillaries stop flowing and the microcirculation fails to compensate for decreased functional capillary density. The resulting maldistribution of RBC flow results in a mismatch of oxygen delivery with oxygen demand that affects both critical oxygen delivery and oxygen extraction ratio. Nitric oxide (NO) maintains microvascular homeostasis by regulating arteriolar tone, RBC deformability, leukocyte and platelet adhesion to endothelial cells, and blood volume. NO also regulates mitochondrial respiration. During sepsis, NO over-production mediates systemic hypotension and microvascular reactivity, and is seemingly protective of microvascular blood flow.     

Bench-to-bedside review: Microvascular dysfunction in sepsis –hemodynamics, oxygen transport, and nitric oxide

The microcirculation is a complex and integrated system that supplies and distributes oxygen throughout the tissues. The red blood cell (RBC) facilitates convective oxygen transport via co-operative binding with hemoglobin. In the microcirculation oxygen diffuses from the RBC into neighboring tissues, where it is consumed by mitochondria. Evidence suggests that the RBC acts as deliverer of oxygen and 'sensor' of local oxygen gradients. Within vascular beds RBCs are distributed actively by arteriolar tone and passively by rheologic factors, including vessel geometry and RBC deformability. Microvascular oxygen transport is determined by microvascular geometry, hemodynamics, and RBC hemoglobin oxygen saturation. Sepsis causes abnormal microvascular oxygen transport as significant numbers of capillaries stop flowing and the microcirculation fails to compensate for decreased functional capillary density. The resulting maldistribution of RBC flow results in a mismatch of oxygen delivery with oxygen demand that affects both critical oxygen delivery and oxygen extraction ratio. Nitric oxide (NO) maintains microvascular homeostasis by regulating arteriolar tone, RBC deformability, leukocyte and platelet adhesion to endothelial cells, and blood volume. NO also regulates mitochondrial respiration. During sepsis, NO over-production mediates systemic hypotension and microvascular reactivity, and is seemingly protective of microvascular blood flow.     

Relationship between sublingual and intestinal microcirculatory perfusion in patients with abdominal sepsis

OBJECTIVE: To evaluate the relation between sublingual and intestinal microcirculatory alterations in patients with abdominal sepsis. DESIGN: Prospective observational study. SETTING: A 23-bed mixed intensive care unit of a tertiary teaching hospital. PATIENTS: Twenty-three patients with abdominal sepsis and a newly constructed intestinal stoma were included in the study group. Nineteen outpatient healthy individuals with an intestinal stoma and ten nonsepsis patients with a <24-hr-old intestinal stoma were included as controls. INTERVENTIONS: None. MEASUREMENTS AND MAIN RESULTS: Orthogonal polarization spectral imaging of the sublingual and intestinal microcirculation was performed on days 1 and 3. In addition, variables of systemic hemodynamics, such as cardiac index, heart rate, blood pressure, central venous pressure, and dosages of vasopressor and inotropic agents, were obtained. On day 1 there was no correlation of the microvascular flow index between the sublingual and intestinal microcirculatory beds (Spearman's rho [rs] = .12; 95% confidence interval, -.51 to .31; p = .59). Furthermore, there was no significant correlation between microcirculatory alterations and variables of systemic circulation (rs 相似文献   

Is a low transfusion threshold safe in critically ill patients with cardiovascular diseases?

OBJECTIVE: To compare a restrictive red blood cell transfusion strategy with a more liberal strategy in volume-resuscitated critically ill patients with cardiovascular disease. SETTING: Twenty-two academic and three community critical care units across Canada. STUDY DESIGN: Randomized controlled clinical trial. STUDY POPULATION: Three hundred fifty-seven critically ill patients with cardiovascular diseases from the Transfusion Requirements in Critical Care trial who had a hemoglobin concentration of <90 g/L within 72 hrs of admission to the intensive care unit. INTERVENTIONS: Patients were randomized to a restrictive strategy to receive allogeneic red blood cell transfusions at a hemoglobin concentration of 70 g/L (and maintained between 70 and 90 g/L) or a liberal strategy to receive red blood cells at 100 g/L (and maintained between 100 and 120 g/L). RESULTS: Baseline characteristics in the restrictive (n = 160) and the liberal group (n = 197) were comparable, except for the use of cardiac and anesthetic drugs (p <.02). Average hemoglobin concentrations (85 +/- 6.2 vs. 103 +/- 6.7 g/L; p <.01) and red blood cell units transfused (2.4 +/- 4.1 vs. 5.2 +/- 5.0 red blood cell units; p <.01) were significantly lower in the restrictive compared with the liberal group. Overall, all mortality rates were similar in both study groups, including 30-day (23% vs. 23%; p = 1.00), 60-day, hospital, and intensive care unit rates. Changes in multiple organ dysfunction from baseline scores were significantly less in the restrictive transfusion group overall (0.2 +/- 4.2 vs. 1.3 +/- 4.4; p =.02). In the 257 patients with severe ischemic heart disease, there were no statistically significant differences in all survival measures, but this is the only subgroup where the restrictive group had lower but nonsignificant absolute survival rates compared with the patients in the liberal group. CONCLUSION: A restrictive red blood cell transfusion strategy generally appears to be safe in most critically ill patients with cardiovascular disease, with the possible exception of patients with acute myocardial infarcts and unstable angina.     

Microvascular and systemic effects following top load administration of saturated carbon monoxide-saline solution

OBJECTIVE: To determine how top loads with different doses of carbon monoxide (CO)-saturated saline solutions (CO-saline) affect microvascular and systemic hemodynamics and to delineate the corresponding biochemical mechanisms. DESIGN: Prospective study. SETTING: University research laboratory. SUBJECTS: Male Golden Syrian hamsters. INTERVENTIONS: Hamsters implemented with a dorsal window chamber were given different volumes (characterized as percent of blood volume, BV) by intravenous injection of CO-saturated saline. MEASUREMENTS AND MAIN RESULTS: Hamsters were observed until 90 mins after infusion of CO-saline solution. In the 20% BV CO-saline infusion group, observation was extended until 180 mins. Systemic variables measured included mean arterial pressure, heart rate, systemic arterial blood gases, and cardiac output and index. Microvascular hemodynamic measurements included vessel diameter, red blood cell velocity, and functional capillary density. Cyclic guanosine monophosphate (cGMP) content in the chamber tissue was measured by enzyme immunoassay. 10% BV of CO-saline increased flow maximally in the microcirculation at 30 mins after infusion (207% in arterioles and 238% in venules, p < .05 vs. baseline). Functional capillary density was significantly increased in both 10% and 15% groups (p < .05 vs. baseline), and cardiac index increased 130% (p < .05 vs. baseline) at 10 mins after 10% CO-saline infusion. There were no changes of microhemodynamic variables and functional capillary density with 2.5%, 5%, and 20% CO-saline infusion during the observation period. Microvascular hemodynamic changes by 10% CO-saline infusion were inhibited completely by L-NAME pretreatment and partially by 1H-[1,2,4]oxadiazole[4,3-a]quinoxqalin-1-one pretreatment. cGMP content in skin fold tissues was related to changes of vessel diameter. CONCLUSIONS: Intravenous injection of CO-saturated saline caused vasodilation and improved microvascular hemodynamics in the hamster window chamber model in a dose-dependent manner. These changes were related to increased cardiac output and local cGMP content. These results support the possible use of CO-saturated solutions as a vasodilator in critical conditions.     

Red blood cell transfusions and nosocomial infections in critically ill patients

OBJECTIVE: A previous retrospective evaluation of Project Impact data demonstrated an association between red blood cell transfusions, nosocomial infections, and poorer outcomes in critically ill patients, independent of survival probability or patient age. The objective of this study was to determine whether transfused patients, independent of survival probability based on Mortality Prediction Model scores, have higher nosocomial infection rates, longer intensive care unit and hospital lengths of stay, and higher mortality rates than nontransfused patients. DESIGN: Prospective, observational, cohort study. SETTING: A single-center, mixed medical/surgical, closed intensive care unit. PATIENTS:: Adults admitted to St. John's Mercy Medical Center between August 2001 and June 2003 (n = 2,085) were enrolled using Project Impact software. Both nonoperative and postoperative populations were represented, and transfusion decisions were made independently of patient study inclusion. Patients whose nosocomial infection was diagnosed before transfusion were counted as nontransfused. INTERVENTIONS:: None. MEASUREMENTS AND MAIN RESULTS: Nosocomial infections, mortality rates, and intensive care unit and hospital length of stay were the main outcome measures. Of the 2,085 patients enrolled, 21.5% received red blood cell transfusions. The posttransfusion nosocomial infection rate was 14.3% in 428 evaluable patients, significantly higher than that observed in nontransfused patients (5.8%; p < .0001, chi-square). In a multivariate analysis controlling for patient age, maximum storage age of red blood cells, and number of red blood cell transfusions, only the number of transfusions was independently associated with nosocomial infection (odds ratio 1.097; 95% confidence interval 1.028-1.171; p = .005). When corrected for survival probability, the risk of nosocomial infection associated with red blood cell transfusions remained statistically significant (p < .0001). Leukoreduction tended to reduce the nosocomial infection rate but not significantly. Mortality and length of stay (intensive care unit and hospital) were significantly higher in transfused patients, even when corrected for illness severity. CONCLUSIONS: Red blood cell transfusions should be used sparingly, bearing in mind the potential risks of infection and poor outcomes in critically ill patients.     

Red blood cell transfusion compared with gelatin solution and no infusion after cardiac surgery: effect on microvascular perfusion,vascular density,hemoglobin, and oxygen saturation

BACKGROUND: After cardiac surgery, red blood cell (RBC) transfusion may improve systemic hemodynamics and thereby microvascular blood flow and O₂ delivery (DO₂). STUDY DESIGN AND METHODS: In a nonrandomized prospective observational study on post–cardiac surgery patients, systemic hemodynamics and microvascular blood flow, vascular density (sidestream dark‐field imaging), hemoglobin (Hb) content, and saturation (reflectance spectrophotometry) were measured before and 1 hour after start of transfusion of 1 to 2 units of leukoreduced RBCs (270 ± 203 mL), 500 mL of gelatin solution, or control (no infusion), when patients were considered clinically hypovolemic with (RBC group, n = 12) or without (gelatin group, n = 14) anemia (Hb < 10 g/dL) or not (n = 13), respectively. RESULTS: Systemic Hb was lower and increased in the RBC transfusion but not in gelatin and control groups. There were no differences in changes in systemic DO₂, O₂ uptake, and extraction between groups. RBC transfusion, compared with gelatin or control, increased medium‐sized vascular density, Hb content, and saturation in the microcirculation, while blood flow remained unchanged. Changes of microvascular Hb and saturation paralleled changes in systemic Hb. CONCLUSION: The data argue in favor of efficacy of RBC transfusion after cardiac surgery. RBC transfusion increases systemic Hb and this in turn increases medium‐sized vascular density and DO₂ in the sublingual microcirculation, independently of systemic hemodynamics and volume status.     

Microhemodynamic and cellular mechanisms of activated protein C action during endotoxemia

OBJECTIVE: To characterize microcirculatory actions of activated protein C in an endotoxemia rodent model that allows in vivo studies of microvascular inflammation and perfusion dysfunction. DESIGN: Animal study using intravital microscopy. SETTING: Animal research facility. SUBJECTS: Male Syrian golden hamsters, 6-8 wks old with a body weight of 60-80 g. INTERVENTIONS: In skinfold preparations, endotoxemia was induced by intravenous administration of 2 mg/kg endotoxin (lipopolysaccharide, Escherichia coli). Intravital microscopy allowed quantitative analysis of arteriolar and venular leukocyte adhesion and functional capillary density (cm) that served as a measure of microvascular perfusion failure. Activated protein C (APC group, n = 8, 24 microg/kg intravenously) was substituted continuously during 8 hrs after lipopolysaccharide, whereas endotoxemic buffer-treated animals (control, n = 7) served as controls. MEASUREMENTS AND MAIN RESULTS: Lipopolysaccharide increased leukocyte adhesion and decreased functional capillary density to 50% of baseline values (p <.01 vs. baseline). Activated protein C treatment inhibited (p <.05) lipopolysaccharide-mediated leukocytic response and attenuated (p <.05) endotoxic perfusion failure in nutritive capillaries. CONCLUSIONS: Activated protein C-induced protection from lipopolysaccharide-mediated microcirculatory dysfunction was characterized in vivo for the first time. The impressive modification of leukocyte cross-talk indicates systemic anti-inflammatory activated protein C effects on leukocytes and the endothelium, subsequently improving capillary perfusion. These actions could represent the in vivo mechanism of activated protein C interactions observed in patients with severe sepsis.     

Influence of cell-free Hb on local tissue perfusion and oxygenation in acute anemia after isovolemic hemodilution

BACKGROUND: Oxygen-carrying solutions are intended to eliminate the blood transfusion trigger. Their ability to maintain microvascular perfusion and to deliver oxygen to tissue when they replace the RBCs as oxygen carriers has not been directly measured. STUDY DESIGN AND METHODS: Microvascular response to exchange transfusion with a polymerized bovine cell-free Hb (PBH) solution after acute isovolemic hemodilution with a plasma expander was investigated by using the hamster window model. In vivo functional capillary density (FCD), blood flow, and high-resolution oxygen distribution in microvascular networks were measured by noninvasive methods. RESULTS: Exchange transfusion of PBH solution after a 60-percent isovolemic hemodilution with dextran 70 (MW, 70 kDa) resulted in a Hct of 11 percent and a Hb content of 6.7 g per dL. FCD was 0.37 of baseline. Interstitial pO2 was reduced from 21.0 mm Hg to 0.3 mmHg. Arteriolar and venular blood flows were ratios of 0.75 and 0.76 relative to baseline. In a previous study, tissue pO2 after hemodilution to 5.6 g of Hb per dL with dextran 70 was 23.0 mmHg. Hypervolemic injection of PBH solution increased blood pressure and caused vasoconstriction. CONCLUSION: Using PBH solution to replace RBC oxygen-carrying capacity during low Hb content conditions (<50%) causes abnormally low tissue oxygenation and FCD, while the same level of hemodilution with dextran maintains normal microvascular conditions.     

Microvascular resuscitation as a therapeutic goal in severe sepsis

Sepsis causes microvascular dysfunction. Increased heterogeneity of capillary blood flow results in local tissue hypoxia, which can cause local tissue inflammation, impaired oxygen extraction, and, ultimately, organ dysfunction. Microvascular dysfunction is clinically relevant because it is a marker for mortality: it improves rapidly in survivors of sepsis but fails to improve in nonsurvivors. This, along with the fact that resuscitation of mean arterial pressure and cardiac output alone fails to improve microvascular function, means that microvascular resuscitation is therefore a therapeutic goal. In animal studies of sepsis, volume resuscitation improves microvascular permeability and tissue oxygenation, and leads to improved organ function, including a reduction in myocardial dysfunction. Microvascular resuscitation strategies include hemodynamic resuscitation using the linked combination of volume resuscitation, judicious vasopressor use, and inotropes and vasodilators. Alternative vasoactive agents, such as vasopressin, may improve microcirculatory function to a greater degree than conventional vasopressors. Successful modulation of inflammation has a positive impact on endothelial function. Finally, targeted treatment of the endothelium, using activated protein C, also improves microvascular function and ultimately increases survival. Thus, attention must be paid to the microcirculation in patients with sepsis, and therapeutic strategies should be employed to resuscitate the microcirculation in order to avoid organ dysfunction and to reduce mortality.