Preoperative Sedation, Hemodynamic Stability during General Anesthesia and Improving Postoperative Pain: Pregabalin Is the Answer ()
1. Introduction
Endotracheal intubation is one of the most invasive stimuli in anesthesia, particularly during induction and after tracheal intubation. Laryngoscopy and tracheal intubation are an essential part of general anesthesia but severely noxious stimuli that induce an intense sympathetic hemodynamic response [1] . Tachycardia and hypertension cause an imbalance in myocardial oxygen supply and demand, predisposing patients to ischemia, infarction and heart failure. While this sympathetic response can normally be tolerated by healthy adults, it can be quite hazardous in patients with compromised cardiovascular function. The search for an ideal drug to attenuate the pressor response to intubation has been ongoing for several decades [2] . Appropriate premedication, smooth induction and rapid intubation would prevent the associated risks and complications of the hemodynamic pressor responses, which may be attenuated pharmacologically. Various pharmacological techniques have been evaluated either as premedication or during induction to attenuate the adverse hemodynamic response to laryngoscopy and tracheal intubation, including deepening the anesthesia and, pretreatment with opioids, (beta) blockers, vasodilators and calcium channel blockers but with variable results [3] .
Recently, gamma-amino butyric acid (GABA) analogs pregabalin and gabapentin have gained prominence in various clinical studies, as they can not only alleviate perioperative pain but also effectively attenuate the pressor response to intubation and produce perioperative sedation and anxiolysis.
Gabapentin was introduced as an antiepileptic drug in 1993. The most recent studies aiming to attenuate the hemodynamic response to laryngoscopy and intubation have focused on the effect of gabapentin [4] . Pregabalin is a lipophilic gamma-amino-butyric acid (GABA) analog, that is, absorbed and tolerated well after oral administration, with limited side effects. It has no known clinically relevant drug interactions. Pregabalin undergoes negligible hepatic metabolism and is eliminated by renal excretion. It has been alleged to possess anxiolytic, analgesic, and anticonvulsant properties. Recent studies have found that premedication with oral pregabalin could produce dose-dependent reductions in acute (state) anxiety and increases in sedation (sleepiness) before the induction of general anesthesia; however few studies on the cardiovascular properties of pregabalin in patients undergoing surgery are present in the literature [5] [6] . Thus, this study compared the efficacy and safety of two different doses (150 mg and 300 mg respectively) of oral pregabalin premedication on attenuation of the hemodynamic pressor response to airway instrumentation and, perioperative hemodynamic stability, as well as secondary outcomes, i.e., preoperative sedation, acute postoperative pain and analgesics consumption, in patients undergoing laparoscopic cholecystectomy. The effect of pregabalin on the hemodynamic response to laryngoscopy and intubation may be explained by its inhibitory effects on membrane voltage-gated calcium channels. Pregabalin binds potently and selectively to the alpha 2 delta subunit of hyper excited voltage-gated calcium channels and inhibits the release of several neurotransmitters, such as glutamate, noradrenaline, and substance P [7] . It does not interact with GABA receptors. However, few data are available in the literature regarding the effect of pregabalin on the cardiovascular system. Pain after surgery has a neuropathic component as well as somatic and visceral characteristics, and agents that are effective in the treatment of neuropathic pain are effective in reducing central sensitization [8] . The efficacy of oral pregabalin in providing postoperative analgesia and reducing parenteral analgesic use has been demonstrated in several studies [9] .
2. Patients and Methods
Approval was obtained from the local ethics committee, and written informed consent was obtained from each patient in this prospective, observational study consisting of 60 adult patients scheduled for laparoscopic cholecystectomy in Aswan University Hospital from October 2015 to October 2016. Inclusion criteria: Age between 20 and 60, both genders, ASA physical status I and II, and airway: Mallampatti Grade I and II for orotracheal intubation only. Exclusion criteria: History of allergy to pregabalin, anticipated difficult intubation, laryngoscopy exceeding 20 s with normal airway, second attempt for intubation in normal airway, and patients on sedatives, hypnotics, and analgesics for chronic pain.
Patients were randomly allocated to one of three groups of 20 patients each by a computer-generated random table. Group allocations were performed by an anesthetist who was unaware of the study protocol.
• Group I received a placebo (P0).
• Group II received 150 mg pregabalin (P150).
• Group III received 300 mg pregabalin (P300). The placebo and pregabalin were administrated orally with sips of water approximately 1 h before the induction of general anesthesia.
The level of sedation was assessed using the Ramsay sedation scale (RSS) done premedication, at 1 h after medication, during postoperative recovery, and 2 h, 4 h, 6 h and 24 h thereafter.
1) Anxious, agitated or restless.
2) Co-operative, oriented and tranquil.
3) Responds to command.
4) Asleep with brisk response to stimulus.
5) Asleep with sluggish response to stimulus.
6) Asleep with no response.
On arrival to the operating room, monitors were attached. Baseline heart rate (HR), systolic blood pressures (SBP), diastolic blood pressures (DBP) and mean arterial blood pressures (MBP) were recorded. After pre-oxygenation for 3 min with 100% oxygen, anesthesia was induced with Propofol at (2 mg/kg) or dose sufficient for the loss of verbal commands. The direct laryngoscopy and intubation was facilitated with atracurium at 0.5 mg/kg. Anesthesia was maintained with isoflurane in 40% air and 60% oxygen. The patients were mechanically ventilated to maintain normocapnia (CO2 between 35 and 40 mmHg). The supplemental neuromuscular blockade was achieved with atracurium at 0.1 mg/kg. After completion of the surgery, residual neuromuscular block was antagonized with appropriate doses of neostigmine (0.05 mg/kg) and atropine (0.01 mg/kg), and extubation was performed when respiration was adequate.
Intraoperative HR, SBP, DBP, MAP, electrocardiography, and pulse oximeter (SpO2) and EtCO2 levels were continuously monitored until the end of the surgery using a VESTA 2000 system. Hemodynamic changes [after premedication], [after induction], [during laryngoscopy] and at (1) (3) (5) (10) (30) and (60) min. after intubation were recorded.
If the HR increased to 100 beats/min or SBP increased to more than 160 mmHg, the patient was treated with an increased concentration of inhaled isoflurane and supplemental bolus doses of fentanyl (0.5 μg/kg).
The patients were transferred to the post-anesthesia care unit (PACU) and monitored for vital signs, postoperative pain intensity using the Verbal Numerical Rating Scale (VNRS) and any side effects such as nausea, vomiting or any respiratory inadequacy [at recovery time], (2 h), (4 h), (6 h) and (24 h) postoperatively. If any side-effects were noted, they were treated accordingly. All patients received 1 gm of Paracetamol by infusion at the PACU. Then, patients received analgesia as follows according to the VNRS score when VNRS ≥ 4 postoperative (whether achieved during rest or movement):
1) Ketorolac 30 mg, I.V.: 4 ≤ VNRS ≤ 6 (moderate pain score)
2) Morphine 0.1 mg/kg, I.V.: 7 ≤ VNRS ≤ 10 (severe pain score)
Statistical analysis:
Date entry and data analysis were done using SPSS version 23 (Statistical Package for Social Science). Data were presented as number, percentage, mean, standard deviation. Chi-square test and Fisher Exact test were used to compare between qualitative variables. Mann Whitney was used to compare quantitative variables between groups. As regard using paired T-test to comparison between baseline and each time in the same group. P-value considered statistically significant when P < 0.05.
3. Results
Sixty patients were scheduled for laparoscopic cholecystectomy at Aswan University Hospital. Patients were randomly allocated to one of three groups of 20 patients each. Table 1 shows the demographic data of the study groups, with non-significance differences (P > 0.05) in age, sex and weight between the groups.
HR. There was a significant decrease in HR in group III (P300) (P < 0.001) during laryngoscopy compared with the placebo group (P0). At 10 min, 30 min and 1 hour after intubation, HR remained significantly attenuated in the premedicated groups, compared with the placebo group (P0).
At recovery and 2, 4 and 6 h postoperatively, HR remained significantly attenuated in the premedictated groups compared with the placebo group (P0), while after 24 h HR remained significantly attenuated (P < 0.04) in group III (P300) only compared with the placebo group (P0) (Figure 1).
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Table 1. Demographic data of the study groups.
SBP. SBP, was significantly lower in group II compared with group I during laryngoscopy and after intubation from 1 min to 1 hr. SBP was significantly lower in group III compared with group II after medication, and at 1 min, 5 min and 10 min after intubation (Figure 2).
DBP. DBP, was significantly lower in group II compared with group I during laryngoscopy and after intubation from 1 to 5 min. DBP was significantly reduced in group III compared with group II after general anesthesia induction and during laryngoscopy (Figure 3).
MAP. The MAP in the study groups, was significantly attenuated in the premedicated groups compared with the baseline values, in a dose-dependent manner (Figure 3).
The MAP values were attenuated during laryngoscopy and after intubation, in the premedicated groups compared with the placebo group.
Even in the PACU, cardiovascular parameters remained at a lower level in the pregabalin groups in a dose-dependent manner than in the placebo group (Figure 4).
RSS sedation level. There were non-significant differences (P > 0.05) in the premedication RSS level of sedation between the study groups but highly significant differences (P < 0.001) at 1 h. postmedication were observed between the study groups. Clear increases in RSS score were observed in groups II (P150) and
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Figure 2. Systolic blood pressure in study groups.
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Figure 3. Diastolic blood pressure in study groups.
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Figure 4. Mean arterial pressure in study groups.
III (P300) compared with the baseline values (P = 0.002). The degree of sedation was significantly higher in group III (P300) than in group II (P150) compared with group I (P0).
Analysis of the postoperative sedation scores, showed that the degree of sedation was significantly higher in group III (P300) than in group II (P150) compared with group I (P0) at all postoperative time points (P < 0.001) (Figure 5).
Postoperative pain. Comparison of static (Figure 6) and dynamic (Figure 7) postoperative pain showed significantly reduction in the pregabalin groups (P < 0.001) compared with the placebo group from recovery to 24 h.
Analgesic consumption. A significant increase (P < 0.05) in intraoperative fentanyl consumption was observed in the placebo group (Figure 8). There was a significant increase in postoperative ketorolac consumption in group I compared with group II and group III. Additionally, there was a highly significant increase in postoperative morphine consumption in group I compared with groups II and III (Figure 8).
Side effects. A highly significant incidence (P < 0.008) of nausea and vomiting were observed in the placebo group (Figure 9) while a significant incidence of dizziness (P < 0.000) was observed in group III (P 300) (Figure 10). A comparison of the postoperative side effects observed in the study groups is showing in (Figure 10).
4. Discussion
Pregabalin possesses several properties render it a valuable premedicant for attenuating the hemodynamic response to laryngoscopy and intubation and it is alleged to modulate the release of excitatory neurotransmitters, leading to reduced levels of anxiety and pain [10] .
The haemodynamic pressor response to laryngoscopy and intubation, in the form of tachycardia and hypertension, occurs frequently [11] . Shribman et al. reported that induction by laryngoscopye alone or tracheal intubation increases the arterial blood pressure and catecholamine levels, but intubation considerably increases the HR [12] . Reid et al. and Hassan et al. reported high incidences of myocardial ischemia, cardiac arrhythmias, acute left ventricular failure and cerebrovascular accidents after intubation in hypertensive patients [12] [13] [14] .
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Figure 5. The level of sedation “Ramsay sedation scale” in study groups.
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Figure 6. The level of (VNRS R) at rest in study groups.
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Figure 7. The level of (VNRS M) at movement in study groups.
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Figure 8. Comparison between analgesic consumption in study groups.
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Figure 9. Comparison between nausea, vomiting in study groups.
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Figure 10. Comparison between side effect postoperative in study groups.
In this study, during laryngoscopy there was a significant increase in HR in group I compared with groups II and III. Then, after intubation it was significantly increased in all the three groups, with a maximum increase at 1 min after intubation. This significant increase lasted for a longer duration in group I, up to 30 min after intubation, than in group II and III up to 5 min after intubation, meanings that the response to laryngoscopy and intubation was very much exaggerated in group I, with non-significant increases in HR in group II compared with group III.
Although the HR increase was not completely attenuated by pregabalin, the drug obviously mitigated the HR after laryngoscopy and intubation, which is in agreement with findings reported by Meena et al. showing no significant difference in the HR before and after premedication [15] . Immediately after laryngoscopy and intubation, the HR increased significantly in all groups, but the increase was smallest in group III (PG300); as such, the heart HR was not completely attenuated by pregabalin but was definitely mitigated after laryngoscopy. Similarly, Rastogi et al. studied the effect of different doses of pregabalin premedication for attenuating the hemodynamic pressor response to airway instrumentation during general anesthesia [16] . They reported that the HR increased significantly immediately after laryngoscopy and intubation in all groups. However, the increase was the smallest with 150 mg of pregabalin. In contrast, Gupta et al. found no significant difference in HR between the placebo group and the group administrated 150 mg of pregabalin; in addition, they found no statistically significant HR attenuation in the pregabalin premedicated groups, with a maximal increase in HR at 1 min after intubation and the smallest increase in pregabalin group, but this relation to group I was statistically insignificant [3] .
In our study, The MAP in the study groups, was significantly attenuated in the premedicated groups compared with the baseline values, in a dose-dependent manner. The MAP values were attenuated during laryngoscopy and after intubation, in the premedicated groups compared with the placebo group.
The results of the current study are in agreement with those of studies performed by Singh and Arora [17] , Montazeri et al. [18] and Rastogi et al. [16] , who demonstrated that the hemodynamic pressor response to airway instrumentation was attenuated by the use of oral pregabalin as a premedication. Similar results have also been reported by Salman et al. [7] and Eren et al. [19] who observed the a significant increase in HR and BP in the control group and attenuated BP the group premedicated with 150 mg of pregabalin after laryngoscopy and intubation.
Preoperative anxiety remains a problem for many patients during the perioperative period. A high degree of anxiety increases the difficulty of controlling postoperative pain. At most centers, patients normally receive sedatives to decrease anxiety before surgery. One study concluded that benzodiazepine premedication had low beneficial effects on the postoperative clinical course of women undergoing abdominal hysterectomy [12] .
The focus on perioperative sedation in our study includes the whole spectrum of anxiety, amnesia and hypnosis. Sedation was assessed with RSS and highly significance difference were observed between the study groups at 1hr. postmedication and postoperatively at all-time points.
Comparing group I with groups II & III, there was a more significant increase in the incidence of sedation between group I and III than between group I and II, meanings that the risk of perioperative sedation is dependent on the dose of preoperative pregabalin administrated. This finding is in agreement with those of White et al. [9] , who in their dose-ranging study on pregabalin addressed sedation itself as the primary end-point and found that preoperative pregabalin administration (75 - 100 - 150 - 300 mg) increased perioperative sedation in a dose-dependent manner. In contrast, Agraweel et al., used preoperative pregabalin at dose of 150 mg and reported no significant difference in RSS score [20] . The same applies to data reported by Peng et al., who assessed such side effects with the use of lower pregabalin doses (50 and 75 mg) [21] .
In this study, tachycardia was defined as HR greater than 100 beats/min and hypertension was defined as a SBP greater than 160 mmHg; these conditions were treated by supplemental bolus doses of fentanyl (0.5 μg/kg). There was a non-significant difference between groups II and III in intraoperative fentanyl consumption but, there was a moderately significant reduction in groups II and III compared with group I. These results are in agreement with those of Bahgat et al., whose study showed that the preoperative administration of 300 mg of oral pregabalin significantly reduces the intraoperative fentanyl requirements and end-tidal isoflurane concentrations required to maintain adequate anesthesia [22] .
The results of this study showed that single preoperative oral dose of pregabalin (150 mg or 300 mg) effectively reduced the postoperative pain in dose-dependent manner. Another study conducted by Pang et al., to test low dose pregabalin (75, 150 mg) showed a significant reduction in postoperative pain intensity, as assessed by verbal rating score (VRS) [21] . Peach et al., found that a single preoperative dose of 100 mg of pregabalin does not reduce acute pain or improve recovery after minor gynecological surgeries, such as dilatation and curettage [23] . Siddiqui et al., examined the effect of a single preoperative oral dose of pregabalin (150 mg) in patients with irritable bowel disease undergoing major bowel surgery, and the results suggested that there was no reduction in the postoperative pain scores, or opioid consumption [24] .
In our study ketorolac and morphine consumption was significantly reduced in groups II and III compared with group I but there were no significant difference between groups II and III, indicating that preoperative pregabalin reduces postoperative analgesic consumption and that the dose of 150 mg is effective for this purpose. This finding agrees with those of Park et al., who found that fewer ketorolac injections were required in the pregabalin group than in the control group, but that the difference between the groups was not significant [25] .
In this study, the incidence of postoperative vomiting was significantly lower with the use of pregabalin, which might be related to the decreased use of opioids after surgery and the consequent decrease in adverse opioid-related effects [26] . Other side effects analyzed in our study were dizziness, blurred vision and dyspnea occurring during the first 24 h after surgery. There was a highly significant increase in the incidence of dizziness among the three study groups. There was significant increase in the incidence of dizziness in groups II and III compared with group I and in group III compared with group II. Therefore, the incidence of dizziness increases with pregabalin administration in a dose- dependent manner.
5. Conclusion
The haemodynamic pressor response was significantly attenuated by oral pregabalin premedication in a dose-dependent manner, with a minimum effect on HR.