Open-access Vasopressin in vasoplegic shock in surgical patients: systematic review and meta-analysis

ABSTRACT

Purpose:  Vasoplegia, or vasoplegic shock, is a syndrome whose main characteristic is reducing blood pressure in the presence of a standard or high cardiac output. For the treatment, vasopressors are recommended, and the most used is norepinephrine. However, new drugs have been evaluated, and conflicting results exist in the literature.

Methods:  This is a systematic review of the literature with meta-analysis, written according to the recommendations of the PRISMA report. The SCOPUS, PubMed, and ScienceDirect databases were used to select the scientific articles included in the study. Searches were conducted in December 2022 using the terms “vasopressin,” “norepinephrine,” “vasoplegic shock,” “postoperative,” and “surgery.” Meta-analysis was performed using Review Manager (RevMan) 5.4. The endpoint associated with the study was efficiency in treating vasoplegic shock and reduced risk of death.

Results:  In total, 2,090 articles were retrieved; after applying the inclusion and exclusion criteria, ten studies were selected to compose the present review. We found no significant difference when assessing the outcome mortality comparing vasopressin versus norepinephrine (odds ratio = 1.60; confidence interval 0.47–5.50), nor when comparing studies on vasopressin versus placebo. When we analyzed the length of hospital stay compared to the use of vasopressin and norepinephrine, we identified a shorter length of hospital stay in cases that used vasopressin; however, the meta-analysis did not demonstrate statistical significance.

Conclusions:  Considering the outcomes included in our study, it is worth noting that most studies showed that using vasopressin was safe and can be considered in managing postoperative vasoplegic shock.

Key words Atrial Fibrillation; Norepinephrine; Mortality; Hospitalization; Vasoplegia; Vasopressins

Introduction

Vasoplegic syndrome (VS) is characterized by systemic arterial hypotension associated with standard or increased cardiac output and reduced systemic vascular resistance. Increased need for fluids or vasopressors represents the more severe systemic inflammatory response syndrome spectrum. The occurrence rate ranges from 5 to 25% in postoperative patients without known risk factors. Still, in those with a known predisposition to the syndrome, the prevalence can range from 30 to 50% of cases1.

In this regard, vasoplegia is present in advanced shock states, including septic, cardiogenic, hemorrhagic, and anaphylactic shock2. It presents a complex pathophysiology that involves several mechanisms in vascular smooth muscle cells, such as desensitization of receptors coupled to the G protein (adrenoceptors, vasopressin receptor, type 1 angiotensin receptor), alteration of second messenger pathways, acute corticosteroid insufficiency and increased production of nitric oxide35.

The most common therapeutic approaches for vasoplegia predict the need for changes in treatment, with the application of personalized multimodal treatment with the indication of various vasopressors. Although norepinephrine is considered a first-line therapy for the treatment of vasoplegia, recent guidelines from the Surviving Sepsis Campaign think that the best therapeutic management of vascular hyporesponsiveness to vasopressors could be a combination of multiple vasopressors, including norepinephrine, and early prescription of vasopressin6. The inclusion of this new approach may be justified by limiting adrenoceptor desensitization and sympathetic hyperactivation due to their subsequent deleterious impacts on hemodynamics and inflammation7.

In postoperative cardiac surgery, the recent Vasopressin versus Norepinephrine in Patients with Vasoplegic Shock after Cardiac Surgery, a randomized, controlled, double-blind study, compared vasopressin to norepinephrine in vasoplegic shock after cardiac surgery8. This study used vasopressin as the first treatment option for shock, in direct comparison with norepinephrine. This study showed that the group randomized to use vasopressin showed reduction in a combined endpoint of mortality and severe complications, a decrease in the intensive care unit (ICU) length of stay, and a lower incidence of supraventricular arrhythmias1.

Although some studies show benefits in using vasopressin, the Surviving Sepsis Campaign 2016 recommendations on catecholamine therapy clear norepinephrine as the vasopressor of first choice. Vasopressin, as an additionally administered drug, is classified as more tentative. Evidence for the benefit of vasopressin remains low, with reduced incidence of newly diagnosed atrial fibrillation and reduced mortality rate. Still, the administration remains safe9. Therefore, we performed a systematic review followed by metanalysis to evaluate the efficacy of using vasopressin in treating postoperatively vasoplegic syndrome, especially considering the mortality outcome.

Methods

The current meta-analysis was performed according to the recommendations of the PRISMA statement10. It was registered in PROSPERO under the number CRD 42020208622.

Search strategy

We searched for four databases for studies, i.e., PubMed, Embase, Web of Science, and Google Scholar. In addition, we also looked for any undergoing trials on clinicaltrials.gov. The keywords searched were “vasopressin,” “norepinephrine,” “Vasoplegic syndrome,” and “surgery.” There was no restriction on our search by language. The bibliographic details of all the included studies were searched manually for any additional citations. In case of duplication of publication, the analysis with the entire data set was included.

Eligibility criteria

Inclusion criteria were randomized controlled trials, and observational studies, published from 2012 to 2022, whose clinical outcome was using vasopressin compared to norepinephrine or placebo in treating vasoplegic shock. The main characteristics of the studies analyzed in the meta-analysis included patients aged 18 years old or older undergoing high-risk cardiac surgery and postoperative patients of non-cardiac surgeries. We considered as high-risk non-cardiac surgery all abdominal, thoracic, and orthopedic surgical procedures with an expected duration greater than 90 minutes and in which the patient presented at least one of the following high-risk criteria: age over 65 years old, coronary artery disease, severe left ventricular dysfunction (defined as ejection fraction less than 30% by echocardiography), moderate or severe heart valve disease, heart failure, chronic obstructive pulmonary disease, chest radiography showing chronic lung disease, chronic renal failure (creatinine ≥ 1.5 mg/dL), and diabetes mellitus.

We excluded publications that did not correspond to the research topic; publications that did not present a complete text; repeated publications; publications that addressed the issue tangentially to the objective of this study; publications that addressed case reports or case series; publications that were not finalized (“preprint”); literature reviews, and those that did not meet the previously mentioned inclusion criteria.

Assessment of bias risk

The quality of scientific evidence in the studies covered was classified as high, moderate, low, or very low according to the risk of bias in the body of evidence, clarity of comparisons, precision, and consistency in treatment effects. High-quality evidence was assigned to well-designed randomized controlled trials with consistent results. The quality of evidence was considered moderate if 1 of the four quality of evidence criteria was not met, and low if two or more were not met. A low rate of evidence was assigned to studies with inconclusive results. Cochrane Collaboration’s tool was used to check for the quality of studies included in the meta-analysis10.

Data synthesis and statistical analysis

For data analysis, a database was built in Microsoft Excel spreadsheet that was later exported to the statistical program Minitab 18 (version 18, Minitab, LLC, State College, Pennsylvania, United States of America) (Minitab) and also to OriginPro 9 (DPR Group, Inc., Northampton, Massachusetts, United States of America) (Moberly, Bernards, Waynant, 2018).

For the statistical analysis, we extracted the data from the selected original articles obtaining the values of total N, mean, standard deviation, 95% confidence interval (95%CI), and percentage (frequency) for all predictors. One-way analysis of variance (ANOVA) test was applied, adopting the α level less than 0.05 with a statistically significant difference for the 95%CI. The value of R-sq (I2) was analyzed to determine the analyses’ imprecision or heterogeneity. The codes of low association = < 25%, medium association 25% < X < 50%, and high association = > 50% were adopted. For dichotomous outcomes, the estimated effect of the intervention was expressed as risk ratio (RR) and odds ratio (OR), along with 95%CI. Relevant data were extracted from the studies, and the Mantel-Haenszel statistical method was used for data synthesis in the Rev Man 5.4 program.

Results

Literature search

A total of 2,090 articles were obtained in the initial search, 87 studies involving vasopressin and VS. Twenty-six duplicate articles were removed, leaving 61 for screening. After screening titles and abstracts, ten full-text articles remained for review (Fig. 1 and Table 1).

Figure 1
PRISMA diagram with the results found in the research.
Table 1
Characteristics of the studies selected for the metanalysis.

Qualitative synthesis

Seven clinical trials and three observational studies were included. In a double-blind, randomized clinical trial published by Okamoto et al.12, the aim was to investigate the relationship between intraoperative vasopressin and the presence of postoperative cardiac enzymes. One hundred patients who underwent cardiac surgery were included. These patients were randomized into two groups. In the first group, patients used vasopressin (1.8 U/h), and in the second group, they used a placebo (saline 1.8 mL/h). The primary endpoint was an assessment of CK-MB and troponin T levels at the end of surgery, and 6 and 12 hours afterward. The authors found no significant differences in the levels of the markers evaluated at any time during the study.

Hajjar et al.3 conducted a double-blind, randomized clinical trial in which patients with vasoplegic shock after cardiac surgery were included. These patients were randomized into two groups. Group 1 (n = 149) was infused with vasopressin, and group 2 (n = 151) with norepinephrine. The primary endpoint was mortality or severe complications, and 32% of patients in the vasopressin group died, while in the norepinephrine group the rate was 49% (hazard ratio–HR = 0.55; 95%CI 0.38–0.80; p = 0.0014).

Jahangirifard et al.13 also conducted a double-blind, randomized clinical trial to evaluate the prophylactic effect of low-dose vasopressin in patients undergoing cardiac revascularization. They included 80 patients randomly divided into two groups. In the first group (n = 40), patients received 0.03 IU/min 30 minutes before the end of cardiac revascularization. In the second group (n = 40), patients received saline solution. The authors found that vasopressin administration decreased the required dopamine dose (p = 0.031) after cardiac surgery.

Dargah et al.14 conducted a randomized clinical trial to compare the incidence of renal failure in patients undergoing coronary artery revascularization who used vasopressin or norepinephrine. One hundred and twenty randomized patients were included in the two groups. The authors demonstrated a statistically significant difference only considering creatinine clearance, which was higher in the group that received norepinephrine compared to the group that received vasopressin (p < 0.05).

Verma et al.15 performed a double-blind, randomized clinical trial to evaluate the prophylactic effect of vasopressin administration in patients undergoing coronary artery bypass. In this study, 60 patients were randomly divided into two groups, one group received vasopressin (0.03 IU/min via infusion pump), and the other group received a saline infusion pump. Heart rate and cardiac output were lower in the group receiving vasopressin, and mean arterial pressure and systemic vascular resistance were higher in this group. Central venous pressure was stable with no significant difference. The authors concluded that low-dose vasopressin infusion is safe for postoperative vasodilatory shock.

Elgebaly and Sabry16, was a double-blind, randomized study to assess whether low doses of vasopressin administered in patients undergoing coronary graft revascularization with mild to moderate systolic dysfunction can produce improvement in cardiac function. Twenty patients were randomly divided into two groups; the patients received 0.03 IU/min of vasopressin in the second saline solution in equal volume for 60 minutes. The authors demonstrated that infusion of low doses of vasopressin for patients with systolic dysfunction benefits the postoperative hemodynamic profile, reduces the doses of catecholamines required, and improves left ventricular systolic function.

The final one, performed by Eissa17, included clinical trial, in a randomized double-blind study, in patients undergoing elective cardiac revascularization with cardiopulmonary bypass (CPB), who used lisinopril, an angiotensin-converting enzyme inhibitor, pre-operatively. Sixty patients were included, divided into three groups: 20 patients did not receive any medication, 20 patients received norepinephrine 0.03–0.05 mcg/kg/min, and 20 patients received vasopressin 0.03 IU/min. The intervention began 20 minutes before the start of prophylactic CPB. The primary outcome was hemodynamic monitoring. The result showed that low-dose vasopressin is beneficial with an improvement in the hemodynamic profile and less blood loss.

Considering observational studies, Porhomayon et al.18 evaluated the effect of vasopressin on postoperative acute renal failure. A retrospective cohort study was conducted, in which 483 patients undergoing coronary revascularization were included. Patients were grouped according to preoperative vasopressin use, and the development of acute renal failure was the primary outcome. According to the results, the authors showed that the incidence of renal failure in the total sample was 14.5%. Vasopressin was administered in 280 patients, and the prevalence of renal failure was 20% in this group and 6.1% in the patients who did not receive it (p < 0.0001). Moreover, the use of vasopressin was an independent factor in predicting the occurrence of renal failure (OR = 3.6; 95%CI 1.22–10.62; p = 0.02). However, this association needed to be recovered in propensity score matching analysis (p = 0.073).

Bomberg et al.19 also conducted an observational cohort study in which 78 patients undergoing cardiac revascularization who had non-occlusive mesenteric ischemia as a complication were included. Among these patients, in 11 the blood pressure was not maintained with the use of norepinephrine alone. Therefore, vasopressin was administered. Two days after treatment, the patients who used vasopressin improved bowel perfusion compared to those who did not (p = 0.002). In addition, all patients in the vasopressin group survived, and 17 patients in the group that did not use vasopressin died in the hospital.

Cheng et al.20 conducted a retrospective observational cohort study in which 1,156 patients who had vasoplegic shock after cardiac surgery and who used vasopressin or norepinephrine were included. The primary endpoint was mortality rate, mechanical ventilation for more than 48 hours, stroke, acute renal failure, and extracorporeal membrane oxygenation. Propensity matching analysis was performed, and, after it, 338 patients were selected (169 used vasopressin and 169 used norepinephrine). No significant differences were found in any of the primary outcomes assessed. However, when evaluating atrial fibrillation and ventricular arrhythmias, the rates were statistically significantly higher in the patients who used vasopressin (p = 0.038 and p = 0.014, respectively).

Quantitative synthesis

The bias risk analysis of all studies included in the metanalyses is shown in Fig. 2. We used the Cochrane RoB 2.0 tool to perform the risk analysis of the studies, and the results are shown in Fig. 3. Regarding selection bias, we noticed 20% of high risk for randomization and 40% for allocation. For performance bias, there was 40% high risk and for attrition bias 40% high risk. The quality of the evidence was assessed using GRADE, and this result is demonstrated in Tables 2 and 3.

Figure 2
Risk of bias analysis of all studies included in the meta-analyses.
Figure 3
Risk of bias item presented as percentages across all included studies.
Table 2
Quality of the evidence was assessed using GRADE for mortality.
Table 3
Quality of the evidence was assessed using GRADE for length of stay.

Mortality

In our analysis, we included studies that evaluated the mortality rate as an outcome comparing patients who received vasopressin and norepinephrine. As we can see in the forest plot (Fig. 4), two studies were included in this analysis, and the mortality rate was higher in the vasopressin group, although without statistical significance in the meta-analysis (OR = 1.60; 95%CI 0.47–5.50, I2 = 67%; z = 0.75; p = 0.45). As we can see, the heterogeneity rate of the analysis was significant, so we chose the random analysis model.

Figure 4
Mortality rate as endpoint comparing patients receiving vasopressin and norepinephrine.

Considering the mortality outcome, we analyzed vasopressin versus placebo and found three studies, included in our analysis. As shown in the forest plot (Fig. 5), no statistically significant difference was found for the intervention (vasopressin use). However, this analysis requires attention because the event (death) did not occur in two studies, making the examination impossible.

Figure 5
Mortality analysis comparing vasopressin versus placebo.

Length of hospital stay

We performed a meta-analysis using a length of stay as the endpoint. We included four studies that compared vasopressin versus norepinephrine. In this analysis, we also performed the random effect due to heterogeneity. As shown in Fig. 6, three studies had a lower mean length of stay in the vasopressin group. One study had a lower mean for the norepinephrine group, but the result of our meta-analysis showed no statistically significant difference (OR = 0.08; 95%CI 0.40–0.56, I2 = 87%; z = 0.33; p = 0.74).

Figure 6
Comparison of length of stay about the use of noradrenaline and vasopressin.

When analyzing vasopressin versus placebo, regarding the outcome of the length of hospital stay, five studies comprised our analysis, as shown in the forest plot (Fig. 7); there was also no statistical significance regarding the use of placebo and vasopressin (OR = -0.10; 95%CI -0.37–-0.18, I2 = 0%; z = 0.67; p = 0.50).

Figure 7
Vasopressin versus placebo concerning length of stay.

Discussion

In our systematic review, we evaluated the effect of vasopressin in patients with vasoplegic shock after significant surgery. We included studies that compared vasopressin with norepinephrine and placebo and evaluated some outcomes reported in the articles as mortality and length of stay. After quantitative and qualitative synthesis of the studies, we observed that, although some studies indicate that vasopressin decreased some of the outcomes significantly, the same was not observed in others. The results are extremely heterogeneous, which can be seen in the meta-analysis performed; in none of them we observed significant differences. However, although we did not find benefits associated with the use of vasopressin, we did not find that its use brought a higher frequency of comorbidities for patients either, showing some safety for its use.

Vasopressin is a nonapeptide hormone formed by sequences of nine amino acids. This hormone is produced by magnocellular neurons located in the paraventricular and supraoptic nuclei of the hypothalamus, in which it is stored until its use21. This synthesis and storage cycle lasts approximately two hours. When in the bloodstream, vasopressin has a half-life of between 10 and 35 minutes and is degraded in the kidneys and liver through the action of peptidases. Compared to other vasoconstrictor agents such as noradrenaline and phenylephrine, vasopressin is considered more potent because, besides the contraction mechanism, this hormone also uses other contractile cascades to function in vascular smooth muscle. These mechanisms may contribute to the justification of its use in the clinic during vasoplegic shock. However, whether this contribution is beneficial, it is still unclear since its vasoconstrictor potential is very pronounced.

The use of vasopressin in this context has been recent yet. Argenziano et al.22 in 1997 aimed to evaluate through a randomized clinical trial the effect of vasopressin in the VS after implantation of a ventricular assist device in patients with advanced heart failure Ten patients were included in this clinical trial; five were randomized to vasopressin and five to saline solution. In the intervention group (vasopressin), a statistically significant improvement in mean arterial pressure and systemic vascular resistance was observed.

Forty-eight patients who developed vasodilatory shock after cardiovascular surgery were included in another previously published study. These patients were randomized into two groups; one received vasopressin, and the other group received vasopressin and noradrenaline. Hemodynamic parameters were evaluated for 48 hours, and the authors demonstrated that the group of patients treated with vasopressin had a statistically significant decrease in heart rate. In addition, no significant adverse effects were observed with vasopressin23.

In our systematic review, we included a single Brazilian study, a randomized clinical trial in which 82 patients were included and randomized into two groups, one group received vasopressin, and the other one norepinephrine. The outcome was assessed as the length of stay, mortality, presence of organ dysfunctions, and adverse effects. In this study, as already mentioned, a significant difference was observed in the length of stay in the ICU favorable to the intervention (vasopressin), which was approximately four days compared to seven days for noradrenaline. Also, in this study, the authors showed no significant difference considering mortality, and the group treated with vasopressin showed a lower incidence of renal failure when compared to noradrenaline3.

There are many studies published in the literature that had as an outcome the use of vasopressin in the clinical management of vasoplegic shock, especially after cardiac surgeries. The results of the works are controversial, which makes it crucial to perform systematic reviews especially with meta-analysis. Here, in our systematic review, we included clinical trials and also observational studies that were available and that met the previously established criteria, i.e., that included patients with VS or high risk for such a condition to define the efficacy of vasopressin in this clinical setting.

The VS in the immediate postoperative period of cardiac surgery has an incidence of 26%, and its severity is proportional to the response to vasoactive amines24. The main drug for treating mild to moderate syndrome is noradrenaline. Still, some evidence shows that noradrenaline alone is ineffective for a significant fraction of patients. In this sense, it is necessary to search for therapeutic alternatives, and among the drugs that are used in studies we have methylene blue and vasopressin, the drugs considered most promising24.

Our systematic review tried to evaluate vasopressin’s efficacy and safety in managing vasoplegic shock. We found an extremely heterogeneous scenario of clinical studies, which included six randomized clinical trials. Among these trials, three evaluated the prophylactic use of vasopressin versus placebo. The outcomes assessed in these studies were different, which makes comparison difficult. Still, in all of them, benefits were demonstrated in the use of vasopressin.

Most importantly, it was shown that its use in low doses prophylactically is safe for patients13,15,16. Only one clinical trial evaluated mortality as the primary endpoint. The results demonstrated that the use of vasopressin compared to norepinephrine was superior and decreased the death rate of patients3. One clinical trial evaluated the development of acute renal failure. It demonstrated no significant differences in the incidence of this condition comparing vasopressin versus noradrenaline15. We included four observational studies; two evaluated mortality as an endpoint comparing the use of vasopressin with noradrenaline and found no statistically significant differences19,20. A cohort study demonstrated that vasopressin administered in patients with mesenteric ischemia as a complication was superior to noradrenaline considering the improvement of intestinal perfusion18. We included a cohort study that demonstrated that using vasopressin increased the chance of developing acute renal failure by more than three times compared to matched patients who did not use the drug17.

We found no significant differences in any of the comparisons performed in our meta-analysis. In the literature for comparison, we found a single previously published systematic review on the subject. In this review, the authors included three studies, two randomized clinical trials and one retrospective cohort study. No differences were observed in mortality rates, ventricular arrhythmias, and duration of mechanical ventilation, however, conflicting results were observed for acute kidney injury, atrial arrhythmias, duration of vasopressors and length of ICU stay, as in our review the authors concluded that vasopressin was not a drug considered superior for any of the outcomes analyzed26.

Finally, it is worth noting that, although our systematic review and meta-analysis does not allow any favorable conclusion for the use of vasopressin, we could observe that only one observational study indicated that the use of vasopressin increases the risk of developing renal failure. However, this finding was not corroborated in a clinical trial conducted with the same objective.

Considering the limitations of our study, we emphasize that our results should be observed with caution, since due to the limited number of studies we included articles with different methodologies, small sample size, and in different populations. Furthermore, no subgroup analysis or adjustments were performed in the meta-analysis.

Conclusion

We concluded that more studies, especially clinical trials, should be conducted in a methodological setting of excellence so that more robust and safer conclusions can be inferred about using vasopressin in managing vasoplegic shock.

Acknowledgements

Not applicable.

  • Research performed at Postgraduate Program in Anesthesiology, Surgical Sciences and Perioperative Medicine, Faculty of Medicine at the Universidade de São Paulo, São Paulo (SP), Brazil. Part of PhD degree thesis, Postgraduate Program in Anesthesiology, Surgical Sciences and Perioperative Medicine. Tutor: Prof. Dr. Everson Luiz Almeida Artifon.
  • Funding
    Not applicable.

Data availability statement

The datasets used and/or analyzed during the current study available from the corresponding author on reasonable request.

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Publication Dates

  • Publication in this collection
    01 Dec 2023
  • Date of issue
    2023

History

  • Received
    19 Aug 2023
  • Accepted
    23 Sept 2023
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