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Lim, Choi, Jeong, Lim, Kim, Park, Lee, and Lee: The relationship between perioperative nausea and vomiting and serum serotonin concentrations in patients undergoing cesarean section under epidural anesthesia

Abstract

Background

Serotonin-also known as 5-hydroxytryptamine or 5-HT-can induce nausea and vomiting (NV) by peripheral mechanisms via the activation of 5-HT3 receptors. In this study, we observed perioperative NV, including intraoperative NV, and changes in serum 5-HT concentrations. We evaluated the relationship between perioperative NV and serum 5-HT levels in patients undergoing cesarean section under epidural anesthesia, and carried out a pilot study to determine if further studies on a larger scale were justified.

Methods

Twenty-eight patients who were scheduled for cesarean section under epidural anesthesia were included in the study. Patients were assigned to 2 groups according to the occurrence of NV after induction, i.e., an NV-positive or an NV-negative group. Serum 5-HT concentrations were measured before induction, at the time that NV occurred (in the case of the NV-positive group) or 5 min after the umbilical cord clamping (in the case of the NV-negative group) during surgery, and at 2 h postoperatively.

Results

NV occurred in 10 of the 28 patients. No significant differences in serum 5-HT concentrations were found within or between the two groups.

Conclusions

This study suggests that there is no correlation between serum 5-HT concentration and the occurrence of perioperative NV in patients undergoing cesarean section under epidural anesthesia, and the findings do not seem to support further investigations regarding a possible relationship between serum 5-HT concentration and perioperative NV.

Introduction

Regional anesthesia is a highly effective, reliable, and safe anesthetic technique, and is currently the standard for elective and emergency cesarean section. However, despite its many advantages, a major drawback [1] is that perioperative nausea and vomiting (NV), a common and distressing side effect, develops in up to 80% of patients receiving regional anesthesia. It is well known that serotonin-also known as 5-hydroxytryptamine or 5-HT-plays a key role in the development of NV in many situations. Serotonin, which is markedly released from enterochromaffin (EC) cells in the gastrointestinal (GI) mucosa as a result of chemotherapy, may pass into the systemic circulation and act directly on central serotonin receptors in the vomiting center of the brain, causing chemotherapy-induced emesis (CIE) [2,3]. Serotonin receptor antagonists are very effective at preventing NV during regional anesthesia for cesarean section in parturients [4,5,6]. They act centrally by competitively and selectively binding to 5-HT receptors in the chemoreceptor trigger zone of the central nervous system, as well as peripherally by blocking the receptors in the GI tract, thus preventing the action of 5-HT and inhibiting emesis [7]. Conversely, 5-HT can also act systemically and locally. If direct mechanical compression of the GI mucosa by a large gravid uterus and peripheral venous pooling induced by regional anesthesia cause substantial ischemia of GI mucosa, then a large amount of 5-HT may be released. The 5-HT that is released would pass into the systemic circulation, act directly on the central nervous system, and thereby cause NV by a mechanism similar to that of CIE. However, there are no reports that confirm a relationship between an increase in peripheral 5-HT and perioperative NV in patients undergoing cesarean section under regional anesthesia. In this study, we observed perioperative NV, including intraoperative NV, and changes in serum 5-HT concentrations. We evaluated the relationship between perioperative NV and the serum 5-HT level in patients undergoing cesarean section under epidural anesthesia.

Materials and Methods

After obtaining the approval of our hospital's Institutional Review Board and written informed consent from the patients, 34 parturients, aged 22-37 years and of the American Society of Anesthesiologists (ASA) physical status II, who were undergoing elective cesarean section were enrolled in this study. They underwent epidural anesthesia without premedication for cesarean section. The patients who experienced NV during the intraoperative and immediate 2 h postoperative periods were categorized as the NV-positive group, whereas those who did not experience NV were categorized as the NV-negative group. The latter group consisted of patients who did not experience either nausea or vomiting since the first trimester of pregnancy, did not take any drugs known to interfere with the serotoninergic system within 48 h prior to the operation, and had avoided foods such as bananas and nuts, which are known to increase serotonin levels, from the day before the study. Patients were excluded if they had experienced severe gravid emesis, pre-eclampsia, or eclampsia. Patients with a psychological disorder or a cardiovascular, pulmonary, or endocrine disease were also excluded.
Standard electrocardiography and pulse oximetry monitoring were started once the patients arrived at the operating room. The radial artery was cannulated for blood samplings and blood pressure measurements under local anesthesia. The heart rate and blood pressure were recorded at 3 min intervals. All patients received a rapid infusion of 1,000-1,500 ml (20 ml/kg) of lactated Ringer's solution before an epidural injection of the local anesthetic. With the patient in the left lateral decubitus position, an 18 G Tuohy needle was inserted into the L3-L4 interspace using a midline approach method. The epidural space was identified using the loss of resistance to air technique, and an epidural catheter was inserted 3 cm into the epidural space through a needle oriented in the cephalad direction. Since neither blood nor cerebrospinal fluid was obtained on aspiration, a 3 ml test dose of 0.75% ropivacaine was injected. After 5 min without any signs of subarachnoid or intravenous injection, 17 ml of 0.75% ropivacaine was injected. Aortocaval compression was avoided by maintaining patients in the supine position with a left lateral tilt. Oxygen was administered through a nasal cannula at a flow rate of 3 L/min.
Assessment for a sensory block and NV was performed by a study-blinded anesthesiologist. The completion of the epidural injection was taken as time 0 for all assessments. The sensory block level was checked by a pin-prick test every 5 min for up to 90 min after epidural injection. In all patients, the operation was started when a complete bilateral sensory block from T6 to S3 was achieved within 20 min of the epidural injection. If the sensory block from T6 to S3 was not achieved 20 min after the injection, 1.5 ml increments of 0.75% ropivacaine per missing segment were injected epidurally, and the patient was excluded from the study.
Hypotension was defined as a systolic blood pressure below 100 mmHg or as a systolic pressure reduction of more than 30% from the baseline. Hypotension was treated immediately with intravenous lactated Ringer's solution and ephedrine in 5 mg increments. After delivery and clamping of the umbilical cord, 20 IU of oxytocin was added to 1,000 ml of lactated Ringer's solution and allowed to infuse over a 45-60 min period.
The presence of NV was checked every 5 min during the operation. Nausea was defined as a subjective desire to vomit but without expulsive muscular movements. Vomiting was defined as an expulsive movement of the stomach muscles with or without expulsion of stomach contents. All episodes of postoperative NV experienced by the patients were also recorded until 2 h postoperatively in the postanesthesia care unit (PACU). Metoclopramide 10 mg was injected intravenously as a rescue antiemetic. In order to prevent excessive sympathetic block, the epidural infusion pumps-with an infusion rate of 2 ml/h and a total volume of 100 ml of 0.2% ropivacaine-were connected to the patients only when the sensory block decreased to the T8 level. Patients were not allowed to have clear liquids within the first 6 h or solid food within 24 h after surgery.
Blood samples were obtained before induction, at the time that NV occurred (in the case of the NV-positive group) or 5 min after the umbilical cord clamping (in the case of the NV-negative group) during the surgery, and at 2 h postoperatively. The arterial catheter was removed before the patient left the PACU, and the puncture site was compressed for 5 min. Quantitative enzyme immunoassays for serum 5-HT concentrations were performed, according to the manufacturer's instructions, using Serotonin ELISA kits made by Immuno-Biological Laboratories in Hamburg, Germany.
Sample size calculation was based on the results of a pilot study performed with a total of 9 cases, 3 in the NV-positive group and 6 in the NV-negative group. One of the primary outcomes was that the serum 5-HT concentration of the second blood sample was 151.9 ± 11.0 ng/ml in the NV-positive group and 140.8 ± 3.9 ng/ml in the NV-negative group, and also that the effect size of the 2 groups was 1.17. On the assumption that the allocation ratio of NV-negative group/NV-positive group was 2, the total sample size was 28 (9 in the NV-positive group and 19 in the NV-negative group), the level of significance was 0.05 with a power of 0.8 as calculated by a two-sided Student's t-test, and the potential patient dropout rate was 20%, the final sample size was increased to 34.
Statistical analysis was performed using the Statistical Package for the Social Sciences (SPSS) data analysis software, version 15.0 for Windows (SPSS Inc., Chicago, IL, USA). The results are expressed as mean ± standard deviation (SD) or median (range). Demographic data and anesthetic variables were analyzed using the Student's t-test or the Mann-Whitney U-test. Categorical variables were analyzed by using a chi-square test. To compare the serum 5-HT level within the NV-positive and negative groups, a one-way repeated measures analysis of variance was used, and post-hoc analyses were carried out using Scheffé's method. To compare the serum 5-HT levels between the 2 groups at each sampling time and the rate of increment from the baseline, the Student's t-test or Mann-Whitney U-test was used to compare serum 5-HT concentrations to values obtained during the surgery between the groups. P < 0.05 was considered statistically significant.

Results

A total of 46 patients were originally eligible to participate in this study. Twelve patients were excluded for violations of the study protocol or for their refusal to participate. Thirty-four patients were subsequently enrolled in this study, but an additional 6 patients were further excluded for violations of the study protocol. Ultimately, 28 patients completed this study. The demographic and anesthetic data of the two groups were comparable in terms of age, body weight, height, body mass index, a history of perioperative NV or smoking, hypotensive events, ephedrine injection, and sensory block level (Table 1). There were no significant differences in the demographic and anesthetic variables between the groups. All patients were equally given 20 IU of oxytocin as a uterotonic agent after delivery and clamping of the umbilical cord. No patient complained of significant visceral pain during the surgery. Ten out of the total of 28 patients (35.7%) who experienced NV during the intraoperative and 2 h immediate postoperative periods were categorized as the NV-positive group, while the remaining 18 patients without NV comprised the NV-negative group. Among the 10 patients who experienced nausea during the study period, 6 experienced nausea during the intraoperative period, and 5 experienced nausea during the postoperative period. One patient experienced nausea during both intraoperative and immediate postoperative period. Four patients experienced vomiting: 2 during the intraoperative period and 2 during the postoperative period.
No significant changes could be seen in the serum 5-HT concentrations within each group during the study period. In addition, there were no differences in the serial serum 5-HT levels between the 2 groups (Fig. 1). The mean serum 5-HT concentrations before induction, at the time of the occurrence of NV (in the case of the NV-positive group) or 5 minutes after the umbilical cord clamping (in the case of the NV-negative group) during the surgery, and at 2 h postoperatively were 146.3 ± 9.8 ng/ml, 148.5 ± 9.9 ng/ml, and 147.8 ± 11.6 ng/ml respectively in the NV-positive group and 144.8 ± 10.8 ng/ml, 146.1 ± 11.2 ng/ml, and 145.6 ± 9.3 ng/ml in the NV-negative group. The rate of increment between the first and second samples was also not different between the two groups: 1.7 ± 5.2% in the NV-positive group and 1.1 ± 6.6% in the NV-negative group.

Discussion

It is well known that the incidence of NV is high during both a cesarean section and a gynecological laparoscopic surgery [1,8]. However, the mechanisms are still unclear and are believed to be multifactorial [9,10]. In this study, there were no differences in the effects of the main causes (hypotension, uterotonic agent, surgical stimulation, and visceral pain) and the risk factors (age, sex, smoking, and a previous history of PONV) of PONV between the 2 groups. Therefore, in this study, it is highly possible that the action of 5-HT was associated with the occurrence of NV. Although many studies have shown that cytotoxic drugs evoke 5-HT release from the EC cells in the intestinal mucosa, and that the released 5-HT stimulates the 5-HT receptors on the adjacent vagal afferent nerves [11,12], other studies have proposed that a large peripheral increase of 5-HT levels in CIE [2,3] directly activates the area postrema of the brain. Such studies have demonstrated the beneficial effects of 5-HT antagonists in postoperative NV [13,14]; however, the relationship between perioperative NV and changes in serum 5-HT concentrations has not been elucidated.
Serotonin is a key modulator of gut function and when in excess, it can induce NV. The most important reservoirs of body serotonin are EC cells of the GI mucosa [15], which store more than 90% of the body's serotonin. Many physiological and pathological factors such as chemotherapeutic agents and luminal toxins such as cyclophosphamide, mechlorethamine, cisplatin, acids, alkalis, irritants, and bacterial toxins can induce NV because they result in the release of serotonin [12,13]. Mechanical GI mucosa stimulation, including distension, contraction, and surgical manipulation can also produce the same effect.
The increased serotonin release in CIE was demonstrated well by Cubeddu et al. [11,16] using urine concentrations of 5-hydroxyindoleacetic acid (5-HIAA) and serum chromogranin A (CgA), metabolites of serotonin, as indices of serotonin release. Serotonin, which is released from EC cells in the GI mucosa by cytotoxic anticancer drugs, sends emetic signals to the vomiting center through the vagal afferent nerves in the GI mucosa. Serotonin may also pass into the systemic circulation and directly activate the area postrema, causing CIE [2,3]. Moreover, several established anti-emetic agents, such as ondansetron, granisetron, tropisetron, dolasetron, and palonosetron, are selective serotonin receptor antagonists [2,12,17], which many studies have shown to be effective in the prevention of postoperative NV [13,14]. However, the relationship between 5-HT and perioperative NV remains to be confirmed.
Several studies conducted by Borgeat et al. [18], Nicole et al. [19], and Rusch et al. [20] have evaluated the relationship between 5-HT and postoperative NV. These authors showed that the distension of intestinal loops created by a pneumoperitoneum during laparoscopic surgery did not cause increased production of 5-HT by EC cells in GI mucosa. In those studies, they measured and compared excretions of the serotonin metabolite, 5-HIAA. Although the studies produced consistent results, they had several limitations. Firstly, the changes in the concentration of 5-HIAA in a 24-h urine sample could not reflect serotonin changes at the time of NV development or during ischemic conditions during the operation. Secondly, the authors could not detect intraoperative NV under general anesthesia despite an expected release of large amounts of serotonin. Thirdly, the pneumoperitoneum induced during laparoscopic surgery may have been insufficient to cause compression and thus resulted in ischemic changes in the GI mucosa.
This study was designed to overcome the limitations mentioned above. Our investigation postulated that patients who undergo cesarean section under regional anesthesia would be more susceptible to perioperative NV because of the effects of a large uterus and regional anesthesia. We thought that direct mechanical compression of the GI mucosa by a large gravid uterus and peripheral venous pooling induced by regional anesthesia could cause substantial ischemia of the GI mucosa, thereby increasing peripheral serotonin secretion and NV. We thought that we could minimize the effects of many other causes of NV by using the standardized epidural technique, selecting non-obese patients with an ASA physical status of I or II, and arranging for the same surgeon to perform the cesarean section. Moreover, we supposed that we could observe intraoperative NV and confirm the correlation between NV and serum 5-HT changes at the time of NV, by directly measuring serum 5-HT concentrations through an arterial line. However, our expectations were unmet, as no correlation between serum 5-HT changes and perioperative NV was found.
Our study had two critical limitations. Because the half-life of 5-HT within the plasma is 2.5 min [21], the urinary excretion of 5-HIAA and the plasma levels of 5-HIAA and CgA have been used as markers for 5-HT release from the EC cells. They are regarded as valuable tools in the study of CIE [12,22]; however, there is controversy surrounding whether the circulating levels of plasma 5-HT increase after treatment with cytotoxic drugs [23,24,25]. Part of the discrepancies may be related to the methodology used for the collection and preparation of the platelet-free plasma [26]. That is, because 5-HT is avidly and effectively taken up by platelets, its rapid uptake into platelets may account for the failure to observe increases in serum levels. In fact, in our study, there is a possibility of 5-HT uptake into platelets during sample processing before centrifugation. Castejon et al. [27] reported that cisplatin-induced increases in blood 5-HIAA were not associated with increases in 5-HT blood dialysates through the application of intravenous microdialysis techniques, which allowed the continuous monitoring of plasma 5-HT and 5-HIAA and circumvented the problems related to sample handling. They insisted that the majority of the 5-HT released from the EC cells would be metabolized to 5-HIAA within the intestinal wall and/or during its passage through the liver or lung, leading to large increases in plasma and urinary 5-HIAA, which are not associated with increases in plasma 5-HT. These results support the view that circulating 5-HT does not play a role in the emetic response associated with cisplatin treatment; therefore, it was likely that plasma 5-HT would not be associated with perioperative NV in our study. However, we noticed that an increased 5-HT metabolism and excretion resulted in a decreased serum 5-HT concentration and an increased urine 5-HIAA excretion, despite increased 5-HT production during pregnancy [28]. We suppose that the increase in the basal plasma and urine 5-HIAA levels masked their increase during the surgery. Besides, Houghton et al. [29] reported an increased platelet-depleted plasma 5-HT concentration following meal ingestion in symptomatic patients with diarrhea-predominant irritable bowel syndrome (IBS). Dunlop et al. [21] also reported that platelet-poor plasma samples were obtained in patients with postinfectious IBS and healthy volunteers, immediately and from 30 to 240 min after the test meal was applied to the patients, resulting in significant increments in plasma 5-HT levels in both groups until 180 min after the test meal. Bearcroft et al. [30] indicated that although only about 1% of the 5-HT released can be measured as free 5-HT within the plasma, this measure is increased in patients with diarrhea-predominant IBS. Cubeddu et al. [24] reported that the content and concentration of 5-HT in platelets did not increase after treatment with cisplatin, despite large increases in the excretion of urine 5-HIAA. Taken together, we judged that we could confirm the correlation between NV and serum 5-HT changes if we shortened sample processing until centrifugation, after directly and promptly measuring serum 5-HT concentrations through an arterial line at the time of NV. However, our expectations were not realized, as there was no significant increase of serum 5-HT concentration at the time of perioperative NV. Therefore, further studies using plasma or urine 5-HIAA and serum CgA measurements will be needed to clarify the relationship between perioperative NV and serum 5-HT concentrations in patients undergoing cesarean section under epidural anesthesia.
Another limitation was that as a result of power analysis using the serum 5-HT concentration values of the second blood samples, one of the primary outcomes in this study-the power value-was very low. Therefore, our findings should be validated in an even greater number of patients. Nevertheless, the negative results of the present study may be useful in presenting the limitation of our method for serum 5-HT measurement and in recommending other methods such as plasma 5-HIAA or CgA measurement in such patients, given the high cost and time necessary for further studies and the difficulty in recruiting patients undergoing cesarean section under epidural anesthesia.
In conclusion, the present study suggests that no correlation exists between serum 5-HT concentration and the occurrence of perioperative NV in patients undergoing cesarean section under epidural anesthesia. In addition, it does not support further investigation into a potential relationship between serum 5-HT concentration and perioperative NV.

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Fig. 1
The changes in serum 5-HT concentrations in the NV-positive and NV-negative groups. Values are presented as mean ± standard deviation (SD). There were no significant differences between and within the two groups. NV-positive: patients with nausea or vomiting. NV-negative: patients without nausea or vomiting. 5-HT: 5-hydroxytryptamine (serotonin). 1st: before induction. 2nd: at the time of the occurrence of NV during the surgery (NV-positive group) or 5 min after the umbilical cord clamping (NV-negative group). 3rd: at 2 h postoperatively.
kjae-67-384-g001.jpg
Table 1
Demographic and Anesthetic Data of Patients
kjae-67-384-i001.jpg

Values are presented as mean ± standard deviation (SD), median (range), or number of patients. NV-positive: patients with nausea or vomiting. NV-negative: patients without nausea or vomiting. NV: nausea or vomiting. T: thoracic level.



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