Methods to decrease blood loss during liver resection: a network meta-analysis

Elisabetta Moggia, Benjamin Rouse, Constantinos Simillis, Tianjing Li, Jessica Vaughan, Brian R Davidson, Kurinchi Selvan Gurusamy, Elisabetta Moggia, Benjamin Rouse, Constantinos Simillis, Tianjing Li, Jessica Vaughan, Brian R Davidson, Kurinchi Selvan Gurusamy

Abstract

Background: Liver resection is a major surgery with significant mortality and morbidity. Specialists have tested various methods in attempts to limit blood loss, transfusion requirements, and morbidity during elective liver resection. These methods include different approaches (anterior versus conventional approach), use of autologous blood donation, cardiopulmonary interventions such as hypoventilation, low central venous pressure, different methods of parenchymal transection, different methods of management of the raw surface of the liver, different methods of vascular occlusion, and different pharmacological interventions. A surgeon typically uses only one of the methods from each of these seven categories. The optimal method to decrease blood loss and transfusion requirements in people undergoing liver resection is unknown.

Objectives: To assess the effects of different interventions for decreasing blood loss and blood transfusion requirements during elective liver resection.

Search methods: We searched the Cochrane Central Register of Controlled Trials (CENTRAL), MEDLINE, Embase, and Science Citation Index Expanded to September 2015 to identify randomised clinical trials. We also searched trial registers and handsearched the references lists of identified trials.

Selection criteria: We included only randomised clinical trials (irrespective of language, blinding, or publication status) comparing different methods of decreasing blood loss and blood transfusion requirements in people undergoing liver resection.

Data collection and analysis: Two review authors independently identified trials and collected data. We assessed the risk of bias using Cochrane domains. We conducted a Bayesian network meta-analysis using the Markov chain Monte Carlo method in WinBUGS 1.4, following the guidelines of the National Institute for Health and Care Excellence Decision Support Unit guidance documents. We calculated the odds ratios (OR) with 95% credible intervals (CrI) for the binary outcomes, mean differences (MD) with 95% CrI for continuous outcomes, and rate ratios with 95% CrI for count outcomes, using a fixed-effect model or random-effects model according to model-fit. We assessed the evidence with GRADE.

Main results: We identified 67 randomised clinical trials involving a total of 6197 participants. All the trials were at high risk of bias. A total of 5771 participants from 64 trials provided data for one or more outcomes included in this review. There was no evidence of differences in most of the comparisons, and where there was, these differences were in single trials, mostly of small sample size. We summarise only the evidence that was available in more than one trial below. Of the primary outcomes, the only one with evidence of a difference from more than one trial under the pair-wise comparison was in the number of adverse events (complications), which was higher with radiofrequency dissecting sealer than with the clamp-crush method (rate ratio 1.85, 95% CrI 1.07 to 3.26; 250 participants; 3 studies; very low-quality evidence). Among the secondary outcomes, the only differences we found from more than one trial under the pair-wise comparison were the following: blood transfusion (proportion) was higher in the low central venous pressure group than in the acute normovolemic haemodilution plus low central venous pressure group (OR 3.19, 95% CrI 1.56 to 6.95; 208 participants; 2 studies; low-quality evidence); blood transfusion quantity (red blood cells) was lower in the fibrin sealant group than in the control (MD -0.53 units, 95% CrI -1.00 to -0.07; 122 participants; 2; very low-quality evidence); blood transfusion quantity (fresh frozen plasma) was higher in the oxidised cellulose group than in the fibrin sealant group (MD 0.53 units, 95% CrI 0.36 to 0.71; 80 participants; 2 studies; very low-quality evidence); blood loss (MD -0.34 L, 95% CrI -0.46 to -0.22; 237 participants; 4 studies; very low-quality evidence), total hospital stay (MD -2.42 days, 95% CrI -3.91 to -0.94; 197 participants; 3 studies; very low-quality evidence), and operating time (MD -15.32 minutes, 95% CrI -29.03 to -1.69; 192 participants; 4 studies; very low-quality evidence) were lower with low central venous pressure than with control. For the other comparisons, the evidence for difference was either based on single small trials or there was no evidence of differences. None of the trials reported health-related quality of life or time needed to return to work.

Authors' conclusions: Paucity of data meant that we could not assess transitivity assumptions and inconsistency for most analyses. When direct and indirect comparisons were available, network meta-analysis provided additional effect estimates for comparisons where there were no direct comparisons. However, the paucity of data decreases the confidence in the results of the network meta-analysis. Low-quality evidence suggests that liver resection using a radiofrequency dissecting sealer may be associated with more adverse events than with the clamp-crush method. Low-quality evidence also suggests that the proportion of people requiring a blood transfusion is higher with low central venous pressure than with acute normovolemic haemodilution plus low central venous pressure; very low-quality evidence suggests that blood transfusion quantity (red blood cells) was lower with fibrin sealant than control; blood transfusion quantity (fresh frozen plasma) was higher with oxidised cellulose than with fibrin sealant; and blood loss, total hospital stay, and operating time were lower with low central venous pressure than with control. There is no evidence to suggest that using special equipment for liver resection is of any benefit in decreasing the mortality, morbidity, or blood transfusion requirements (very low-quality evidence). Radiofrequency dissecting sealer should not be used outside the clinical trial setting since there is low-quality evidence for increased harm without any evidence of benefits. In addition, it should be noted that the sample size was small and the credible intervals were wide, and we cannot rule out considerable benefit or harm with a specific method of liver resection.

Conflict of interest statement

Review authors perform research related to decreasing blood loss in liver resection. This includes clinical studies. No other conflicts of interest.

Figures

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1
Study flow diagram.
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Risk of bias graph: review authors' judgements about each risk of bias item presented as percentages across all included studies.
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3
Risk of bias summary: review authors' judgements about each risk of bias item for each included study.
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The network plot showing the comparisons in the trials included in the comparison of cardiopulmonary interventions in which network meta‐analysis was performed. The size of the node (circle) provides a measure of the number of trials in which the particular treatment was included as one of the arms. The thickness of the line provides a measure of the number of direct comparisons between two nodes (treatments). ANH: acute normovolemic haemodilution; CVP: central venous pressure; RBC: red blood cells.
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Probability of best treatment: probability of being best, second best, third best, etc. for each treatment for blood transfusion (red blood cells) (cardiopulmonary interventions). A probability of more than 90% is a reliable indicator that a treatment is best with regards to the specific outcome. A probability of less than 90% is less reliable. None of the treatments have a 90% probability of being best treatment. ANH: acute normovolemic haemodilution; CVP: central venous pressure; RBC: red blood cells.
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Cumulative probability of being best treatment: cumulative probability of being best for each treatment for cardiopulmonary interventions. Rank 1 indicates the probability that a treatment is best, rank 2 indicates the probability that a treatment is in the two best treatments, rank 3 indicates the probability that a treatment is in the three best treatments, and so on. ANH: acute normovolemic haemodilution; CVP: central venous pressure; RBC: red blood cells.
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Cardiopulmonary intervention: blood transfusion (red blood cells) Forest plot of the comparisons in which direct and indirect estimates were available. The mean effect is in opposite directions in the indirect estimate and the direct estimates, thus suggesting that there may be discrepancies between direct and indirect estimates. Direct evidence appears to be preferable over indirect evidence and network meta‐analysis based on the quality of evidence. 1 Risk of bias was unclear or high in the trial(s) (downgraded by 1 point).
 2 Sample size was low (downgraded by 1 point).
 3Confidence intervals spanned no effect and clinically significant effect (downgraded by 1 point).
 4There was substantial or considerable heterogeneity (downgraded by 2 points).
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Probability of best treatment: probability of being best, second best, third best, etc. for each treatment for blood loss (cardiopulmonary interventions). A probability of more than 90% is a reliable indicator that a treatment is best with regards to the specific outcome. A probability of less than 90% is less reliable. None of the treatments have a 90% probability of being best treatment. ANH: acute normovolemic haemodilution; CVP: central venous pressure.
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Cardiopulmonary intervention: blood loss Forest plot of the comparisons in which direct and indirect estimates were available. There does not appear to be any discrepancy between the direct and indirect estimates, although the indirect estimates have wide credible intervals. Direct evidence appears to be preferable over indirect evidence and network meta‐analysis based on the quality of evidence. ANH: acute normovolemic haemodilution; CVP: central venous pressure. 1Risk of bias was unclear or high in the trial(s) (downgraded by 1 point).
 2Sample size was low (downgraded by 1 point).
 3Confidence intervals spanned no effect and clinically significant effect (downgraded by 1 point).
 4There was substantial or considerable heterogeneity (downgraded by 2 points).
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The network plot showing the comparisons in the trials included in the comparison of methods for parenchymal transection in which network meta‐analysis was performed. The size of the node (circle) provides a measure of the number of trials in which the particular treatment was included as one of the arms. The thickness of the line provides a measure of the number of direct comparisons between two nodes (treatments). CUSA: cavitron ultrsonic surgical aspirator; RFDS: radiofrequency dissecting sealer.
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Probability of best treatment: probability of being best, second best, third best, etc. for each treatment for adverse events (proportion) (parenchymal transection methods). A probability of more than 90% is a reliable indicator that a treatment is best with regards to the specific outcome. A probability of less than 90% is less reliable. None of the treatments have a 90% probability of being best treatment. CUSA: cavitron ultrsonic surgical aspirator; RFDS: radiofrequency dissecting sealer.
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Cumulative probability of being best treatment: cumulative probability of being best for each treatment for parenchymal transection methods. Rank 1 indicates the probability that a treatment is best, rank 2 indicates the probability that a treatment is in the two best treatments, rank 3 indicates the probability that a treatment is in the three best treatments, and so on. CUSA: cavitron ultrsonic surgical aspirator; RFDS: radiofrequency dissecting sealer.
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Parenchymal transection: adverse events (proportion) Forest plot of the comparisons in which direct and indirect estimates were available. There does not appear to be any discrepancy between the direct and indirect estimates, although the indirect estimates have wide credible intervals. Direct evidence appears to be preferable over indirect evidence and network meta‐analysis based on the quality of evidence. CUSA: cavitron ultrsonic surgical aspirator; RFDS: radiofrequency dissecting sealer. 1Risk of bias was unclear or high in the trial(s) (downgraded by 1 point).
 2Sample size was low (downgraded by 1 point).
 3Confidence intervals spanned no effect and clinically significant effect (downgraded by 1 point).
 4There was substantial or considerable heterogeneity (downgraded by 2 points).
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Probability of best treatment: probability of being best, second best, third best, etc. for each treatment for adverse events (number) (parenchymal transection methods). A probability of more than 90% is a reliable indicator that a treatment is best with regards to the specific outcome. A probability of less than 90% is less reliable. None of the treatments have a 90% probability of being best treatment. CUSA: cavitron ultrsonic surgical aspirator; RFDS: radiofrequency dissecting sealer.
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Parenchymal transection: adverse events (number) Forest plot of the comparisons in which direct and indirect estimates were available. There does not appear to be any discrepancy between the direct and indirect estimates. Direct evidence appears to be preferable over indirect evidence and network meta‐analysis based on the quality of evidence. CUSA: cavitron ultrsonic surgical aspirator; RFDS: radiofrequency dissecting sealer. 1Risk of bias was unclear or high in the trial(s) (downgraded by 1 point).
 2Sample size was low (downgraded by 1 point).
 3Confidence intervals spanned no effect and clinically significant effect (downgraded by 1 point).
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Probability of best treatment: probability of being best, second best, third best, etc. for each treatment for blood transfusion (proportion) (parenchymal transection methods). A probability of more than 90% is a reliable indicator that a treatment is best with regards to the specific outcome. A probability of less than 90% is less reliable. None of the treatments have a 90% probability of being best treatment. CUSA: cavitron ultrsonic surgical aspirator; RFDS: radiofrequency dissecting sealer.
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Parenchymal transection:blood transfusion (proportion) Forest plot of the comparisons in which direct and indirect estimates were available. There does not appear to be any discrepancy between the direct and indirect estimates, although the indirect estimates have wide credible intervals for some comparisons. There was little apparent difference in the quality of evidence between direct, indirect estimates, and network meta‐analysis; so, we could not choose one estimate over the others based on the quality of evidence. CUSA: cavitron ultrsonic surgical aspirator; RFDS: radiofrequency dissecting sealer. 1Risk of bias was unclear or high in the trial(s) (downgraded by 1 point).
 2Sample size was low (downgraded by 1 point).
 3Confidence intervals spanned no effect and clinically significant effect (downgraded by 1 point).
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The network plot showing the comparisons in the trials included in the comparison of methods for vascular occlusion in which network meta‐analysis was performed. The size of the node (circle) provides a measure of the number of trials in which the particular treatment was included as one of the arms. The thickness of the line provides a measure of the number of direct comparisons between two nodes (treatments). Con: continuous; Int: intermittent; HVE: hepatic vascular exclusion; PTC: portal triad clamping; RBC: red blood cells.
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Probability of best treatment: probability of being best, second best, third best, etc. for each treatment for serious adverse events (proportion) (vascular occlusion methods). A probability of more than 90% is a reliable indicator that a treatment is best with regards to the specific outcome. A probability of less than 90% is less reliable. None of the treatments have a 90% probability of being best treatment. Con: continuous; Int: intermittent; HVE: hepatic vascular exclusion; PTC: portal triad clamping.
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Cumulative probability of being best treatment: cumulative probability of being best for each treatment for vascular occlusion methods. Rank 1 indicates the probability that a treatment is best, rank 2 indicates the probability that a treatment is in the two best treatments, rank 3 indicates the probability that a treatment is in the three best treatments, and so on. Con: continuous; Int: intermittent; HVE:hepatic vascular exclusion; PTC: portal triad clamping.
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Methods of vascular occlusion: serious adverse events (proportion) Forest plot of the comparisons in which direct and indirect estimates were available. Although there is overlap of confidence intervals, the mean indirect estimate seems to be quite different from the direct estimate (sometimes, suggesting an opposite effect), thus suggesting that there may be discrepancies between direct and indirect estimates. There was little apparent difference in the quality of evidence between direct, indirect estimates, and network meta‐analysis; so, we could not choose one estimate over the others based on the quality of evidence. 1Risk of bias was unclear or high in the trial(s) (downgraded by 1 point).
 2Sample size was low (downgraded by 1 point).
 3Confidence intervals spanned no effect and clinically significant effect (downgraded by 1 point).
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Probability of best treatment: probability of being best, second best, third best, etc. for each treatment for adverse events (proportion) (vascular occlusion methods). A probability of more than 90% is a reliable indicator that a treatment is best with regards to the specific outcome. A probability of less than 90% is less reliable. None of the treatments have a 90% probability of being best treatment. Con: continuous; Int: intermittent; HVE: hepatic vascular exclusion; PTC: portal triad clamping.
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Methods of vascular occlusion: adverse events (proportion) Forest plot of the comparisons in which direct and indirect estimates were available. There does not appear to be any discrepancies between direct and indirect estimates. Direct evidence appears to be preferable over indirect evidence and network meta‐analysis based on the quality of evidence. 1Risk of bias was unclear or high in the trial(s) (downgraded by 1 point).
 2Sample size was low (downgraded by 1 point).
 3Confidence intervals spanned no effect and clinically significant effect (downgraded by 1 point).
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Probability of best treatment: probability of being best, second best, third best, etc. for each treatment for blood transfusion (proportion) (vascular occlusion methods). A probability of more than 90% is a reliable indicator that a treatment is best with regards to the specific outcome. A probability of less than 90% is less reliable. None of the treatments have a 90% probability of being best treatment. Con: continuous; Int: intermittent; HVE: hepatic vascular exclusion; PTC: portal triad clamping.
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Methods of vascular occlusion: blood transfusion (proportion) Forest plot of the comparisons in which direct and indirect estimates were available. Although the confidence intervals overlap, there appear to be some discrepancies between direct and indirect estimates for continuous portal triad clamping versus control, intermittent portal triad clamping versus control, and intermittent portal triad clamping versus continuous portal triad clamping. Direct evidence appears to be preferable over indirect evidence and network meta‐analysis based on the quality of evidence. 1Risk of bias was unclear or high in the trial(s) (downgraded by 1 point).
 2Sample size was low (downgraded by 1 point).
 3Confidence intervals spanned no effect and clinically significant effect (downgraded by 1 point).
 4There was substantial or considerable heterogeneity (downgraded by 2 points).
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Probability of best treatment: probability of being best, second best, third best, etc. for each treatment for blood transfusion (red blood cells) (vascular occlusion methods). A probability of more than 90% is a reliable indicator that a treatment is best with regards to the specific outcome. A probability of less than 90% is less reliable. Intermittent selective portal triad clamping has about 90% probability of being best treatment. However, other random and systematic errors make this finding unreliable. Con: continuous; Int: intermittent; HVE: hepatic vascular exclusion; PTC: portal triad clamping.
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Methods of vascular occlusion:blood transfusion (red blood cells) Forest plot of the comparisons in which direct and indirect estimates were available. There do not appear to be any discrepancies between direct and indirect estimates, although the credible intervals are different (the direct evidence had narrower credible intervals in four of the five comparisons above) resulting in the differences in the comparisons in which there was evidence for difference. Direct evidence appears to be preferable over indirect evidence and network meta‐analysis based on the quality of evidence for the comparison 'continuous selective portal triad clamping versus continuous portal triad clamping'. Indirect evidence and network meta‐analysis appear to be preferable over direct evidence for the comparison 'continuous portal triad clamping versus control'. Direct evidence and network meta‐analysis appear to be preferable over indirect evidence for the comparison 'intermittent portal triad clamping versus control'. There was little apparent difference in the quality of evidence between direct, indirect estimates, and network meta‐analysis; so, we could not choose one estimate over the others based on the quality of evidence. 1Risk of bias was unclear or high in the trial(s) (downgraded by 1 point).
 2Sample size was low (downgraded by 1 point).
 3Confidence intervals spanned no effect and clinically significant effect (downgraded by 1 point).
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Probability of best treatment: probability of being best, second best, third best, etc. for each treatment for blood loss (vascular occlusion methods). A probability of more than 90% is a reliable indicator that a treatment is best with regards to the specific outcome. A probability of less than 90% is less reliable. None of the treatments have a 90% probability of being best treatment. Con: continuous; Int: intermittent; HVE: hepatic vascular exclusion; PTC: portal triad clamping.
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Methods of vascular occlusion:blood loss Forest plot of the comparisons in which direct and indirect estimates were available. There does not appear to be any discrepancies between direct and indirect estimates, although the credible intervals are different (the direct evidence had narrower credible intervals in three of the five comparisons above). Direct evidence appears to be preferable over indirect evidence and network meta‐analysis based on the quality of evidence. 1Risk of bias was unclear or high in the trial(s) (downgraded by 1 point).
 2 Sample size was low (downgraded by 1 point).
 3Confidence intervals spanned no effect and clinically significant effect (downgraded by 1 point).Ç
 4There was substantial or considerable heterogeneity (downgraded by 2 points).
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Funnel plot of blood transfusion (proportion): The funnel plot shows funnel plot asymmetry (i.e. some trials with large variance with large effects favouring one treatment were not matched by other trials with similarly large variance with large effects favouring the other treatment). This may be evidence of reporting bias or could be because of heterogeneity between the studies.
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Funnel plot of blood transfusion (red blood cells): The funnel plot shows funnel plot asymmetry (i.e. some trials with large variance with large effects favouring one treatment were not matched by other trials with similarly large variance with large effects favouring the other treatment). This may be evidence of reporting bias or could be because of heterogeneity between the studies.
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Funnel plot of blood loss: The funnel plot shows funnel plot asymmetry (i.e. some trials with large variance with large effects favouring one treatment were not matched by other trials with similarly large variance with large effects favouring the other treatment). This may be evidence of reporting bias or could be because of heterogeneity between the studies.
1.1. Analysis
1.1. Analysis
Comparison 1 Anterior approach vs conventional approach, Outcome 1 Mortality (perioperative).
1.2. Analysis
1.2. Analysis
Comparison 1 Anterior approach vs conventional approach, Outcome 2 Serious adverse events (proportion).
1.3. Analysis
1.3. Analysis
Comparison 1 Anterior approach vs conventional approach, Outcome 3 Adverse events (proportion).
1.4. Analysis
1.4. Analysis
Comparison 1 Anterior approach vs conventional approach, Outcome 4 Adverse events (number).
1.5. Analysis
1.5. Analysis
Comparison 1 Anterior approach vs conventional approach, Outcome 5 Blood transfusion (proportion).
1.6. Analysis
1.6. Analysis
Comparison 1 Anterior approach vs conventional approach, Outcome 6 Major blood loss (proportion).
2.1. Analysis
2.1. Analysis
Comparison 2 Autologous blood donation vs control, Outcome 1 Adverse events (proportion).
2.2. Analysis
2.2. Analysis
Comparison 2 Autologous blood donation vs control, Outcome 2 Blood transfusion (proportion).
2.3. Analysis
2.3. Analysis
Comparison 2 Autologous blood donation vs control, Outcome 3 Blood transfusion (red blood cell).
2.4. Analysis
2.4. Analysis
Comparison 2 Autologous blood donation vs control, Outcome 4 Blood loss.
2.5. Analysis
2.5. Analysis
Comparison 2 Autologous blood donation vs control, Outcome 5 Major blood loss (proportion).
2.6. Analysis
2.6. Analysis
Comparison 2 Autologous blood donation vs control, Outcome 6 Total hospital stay.
2.7. Analysis
2.7. Analysis
Comparison 2 Autologous blood donation vs control, Outcome 7 Operating time.
3.1. Analysis
3.1. Analysis
Comparison 3 Cardiopulmonary interventions, Outcome 1 Mortality (perioperative).
3.2. Analysis
3.2. Analysis
Comparison 3 Cardiopulmonary interventions, Outcome 2 Serious adverse events (proportion).
3.3. Analysis
3.3. Analysis
Comparison 3 Cardiopulmonary interventions, Outcome 3 Serious adverse events (number).
3.4. Analysis
3.4. Analysis
Comparison 3 Cardiopulmonary interventions, Outcome 4 Adverse events (proportion).
3.5. Analysis
3.5. Analysis
Comparison 3 Cardiopulmonary interventions, Outcome 5 Adverse events (number).
3.6. Analysis
3.6. Analysis
Comparison 3 Cardiopulmonary interventions, Outcome 6 Blood transfusion (proportion).
3.7. Analysis
3.7. Analysis
Comparison 3 Cardiopulmonary interventions, Outcome 7 Blood transfusion (red blood cell).
3.8. Analysis
3.8. Analysis
Comparison 3 Cardiopulmonary interventions, Outcome 8 Blood transfusion (fresh frozen plasma).
3.9. Analysis
3.9. Analysis
Comparison 3 Cardiopulmonary interventions, Outcome 9 Blood transfusion (cryoprecipitate).
3.10. Analysis
3.10. Analysis
Comparison 3 Cardiopulmonary interventions, Outcome 10 Blood loss.
3.11. Analysis
3.11. Analysis
Comparison 3 Cardiopulmonary interventions, Outcome 11 Major blood loss (proportion).
3.12. Analysis
3.12. Analysis
Comparison 3 Cardiopulmonary interventions, Outcome 12 Hospital stay.
3.13. Analysis
3.13. Analysis
Comparison 3 Cardiopulmonary interventions, Outcome 13 Operating time.
4.1. Analysis
4.1. Analysis
Comparison 4 Methods of parenchymal transection, Outcome 1 Mortality (perioperative).
4.2. Analysis
4.2. Analysis
Comparison 4 Methods of parenchymal transection, Outcome 2 Serious adverse events (proportion).
4.3. Analysis
4.3. Analysis
Comparison 4 Methods of parenchymal transection, Outcome 3 Serious adverse events (number).
4.4. Analysis
4.4. Analysis
Comparison 4 Methods of parenchymal transection, Outcome 4 Adverse events (proportion).
4.5. Analysis
4.5. Analysis
Comparison 4 Methods of parenchymal transection, Outcome 5 Adverse events (number).
4.6. Analysis
4.6. Analysis
Comparison 4 Methods of parenchymal transection, Outcome 6 Blood transfusion (proportion).
4.7. Analysis
4.7. Analysis
Comparison 4 Methods of parenchymal transection, Outcome 7 Blood transfusion (red blood cell).
4.8. Analysis
4.8. Analysis
Comparison 4 Methods of parenchymal transection, Outcome 8 Blood transfusion (fresh frozen plasma).
4.9. Analysis
4.9. Analysis
Comparison 4 Methods of parenchymal transection, Outcome 9 Blood loss.
4.10. Analysis
4.10. Analysis
Comparison 4 Methods of parenchymal transection, Outcome 10 Operating time.
5.1. Analysis
5.1. Analysis
Comparison 5 Methods of dealing with cut surface, Outcome 1 Mortality (perioperative).
5.2. Analysis
5.2. Analysis
Comparison 5 Methods of dealing with cut surface, Outcome 2 Serious adverse events (proportion).
5.3. Analysis
5.3. Analysis
Comparison 5 Methods of dealing with cut surface, Outcome 3 Serious adverse events (number).
5.4. Analysis
5.4. Analysis
Comparison 5 Methods of dealing with cut surface, Outcome 4 Adverse events (proportion).
5.5. Analysis
5.5. Analysis
Comparison 5 Methods of dealing with cut surface, Outcome 5 Adverse events (number).
5.6. Analysis
5.6. Analysis
Comparison 5 Methods of dealing with cut surface, Outcome 6 Blood transfusion (proportion).
5.7. Analysis
5.7. Analysis
Comparison 5 Methods of dealing with cut surface, Outcome 7 Blood transfusion (red blood cell).
5.8. Analysis
5.8. Analysis
Comparison 5 Methods of dealing with cut surface, Outcome 8 Blood transfusion (fresh frozen plasma).
5.9. Analysis
5.9. Analysis
Comparison 5 Methods of dealing with cut surface, Outcome 9 Blood loss.
5.10. Analysis
5.10. Analysis
Comparison 5 Methods of dealing with cut surface, Outcome 10 Total hospital stay.
5.11. Analysis
5.11. Analysis
Comparison 5 Methods of dealing with cut surface, Outcome 11 ITU stay.
5.12. Analysis
5.12. Analysis
Comparison 5 Methods of dealing with cut surface, Outcome 12 Operating time.
6.1. Analysis
6.1. Analysis
Comparison 6 Methods of vascular occlusion, Outcome 1 Mortality (perioperative).
6.2. Analysis
6.2. Analysis
Comparison 6 Methods of vascular occlusion, Outcome 2 Serious adverse events (proportion).
6.3. Analysis
6.3. Analysis
Comparison 6 Methods of vascular occlusion, Outcome 3 Serious adverse events (number).
6.4. Analysis
6.4. Analysis
Comparison 6 Methods of vascular occlusion, Outcome 4 Adverse events (proportion).
6.5. Analysis
6.5. Analysis
Comparison 6 Methods of vascular occlusion, Outcome 5 Adverse events (number).
6.6. Analysis
6.6. Analysis
Comparison 6 Methods of vascular occlusion, Outcome 6 Blood transfusion (proportion).
6.7. Analysis
6.7. Analysis
Comparison 6 Methods of vascular occlusion, Outcome 7 Blood transfusion (red blood cell).
6.8. Analysis
6.8. Analysis
Comparison 6 Methods of vascular occlusion, Outcome 8 Blood loss.
6.9. Analysis
6.9. Analysis
Comparison 6 Methods of vascular occlusion, Outcome 9 Major blood loss (proportion).
6.10. Analysis
6.10. Analysis
Comparison 6 Methods of vascular occlusion, Outcome 10 Total hospital stay.
6.11. Analysis
6.11. Analysis
Comparison 6 Methods of vascular occlusion, Outcome 11 ITU stay.
6.12. Analysis
6.12. Analysis
Comparison 6 Methods of vascular occlusion, Outcome 12 Operating time.
7.1. Analysis
7.1. Analysis
Comparison 7 Pharmacological interventions, Outcome 1 Mortality (perioperative).
7.2. Analysis
7.2. Analysis
Comparison 7 Pharmacological interventions, Outcome 2 Serious adverse events (proportion).
7.3. Analysis
7.3. Analysis
Comparison 7 Pharmacological interventions, Outcome 3 Serious adverse events (number).
7.4. Analysis
7.4. Analysis
Comparison 7 Pharmacological interventions, Outcome 4 Adverse events (proportion).
7.5. Analysis
7.5. Analysis
Comparison 7 Pharmacological interventions, Outcome 5 Adverse events (number).
7.6. Analysis
7.6. Analysis
Comparison 7 Pharmacological interventions, Outcome 6 Blood transfusion (proportion).
7.7. Analysis
7.7. Analysis
Comparison 7 Pharmacological interventions, Outcome 7 Blood transfusion (fresh frozen plasma).
7.8. Analysis
7.8. Analysis
Comparison 7 Pharmacological interventions, Outcome 8 Blood loss.
7.9. Analysis
7.9. Analysis
Comparison 7 Pharmacological interventions, Outcome 9 Hospital stay.
7.10. Analysis
7.10. Analysis
Comparison 7 Pharmacological interventions, Outcome 10 Operating time.

Source: PubMed

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