Abstract
PURPOSE: To comparatively study the efficacy and maternal and fetal side-effects of two doses of bupivacaine associated with morphine and clonidine, administered by the subarachnoid route for cesarean section. METHODS: The study included 66 pregnant women at term, distributed into two groups. GI: bupivacaine 8.0 mg (1.6mL) + clonidine 75µg (0.5mL) + morphine 100µg (1.0mL) and GII: bupivacaine 10mg (2.0mL) + clonidine 75µg (0.5mL) + morphine 100µg (1.0mL). The following parameters were assessed: onset and maximum level of sensory block; quality of intraoperative and postoperative analgesia; degree and duration of motor block; maternal repercussions and Apgar score. RESULTS: The onset of sensory block, quality of intraoperative analgesia and total duration of analgesia were similar in both groups; maximum extent of sensory block predominated in T4; maximum degree of motor block (Bromage 3); time motor block regression was significantly longer in GII; Hemodynamic, respiratory repercussions, adverse maternal effects and Apgar scores were similar between groups. In both groups, there was a predominance of drowsy or sleeping patients. CONCLUSION: The addition of morphine and clonidine to low doses of hyperbaric bupivacaine produced adequate anesthesia for cesarean section and good postoperative analgesia, without any maternal and fetal repercussions.
Adrenergic alpha-2 Receptor Agonists; Clonidine; Analgesics, Opioid; Morphine; Cesarean Section
5 - ORIGINAL ARTICLE
ANESTHESIA
Spinal anesthesia for elective ceasarean section. Use of different doses of hyperbaric bupivacaine associated with morphine and clonidine1 1 Research performed at Department of Anesthesiology, Faculty of Medical Sciences, Campinas University (UNICAMP), Sao Paulo, Brazil.
Angélica de Fátima de Assunção BragaI; José Aristeu Fachini FriasII; Franklin Sarmento da Silva BragaIII; Rosa Inês Costa PereiraIII; Stella Marys Meirelles Campos TitottoIV
IAssociate Professor, Department of Anesthesiology, UNICAMP, Campinas-SP, Brazil. Intellectual and scientific content of the study, acquisition and interpretation of data, manuscript preparation and writing, critical revision, designed the protocol, involved whit technical procedures, supervised all phases of the study
IIMD, Department of Anesthesiology, UNICAMP, Campinas-SP, Brazil. Acquisition and interpretation of data, manuscript preparation and writing, critical revision
IIIPhD, Department of Anesthesiology, Faculty of Medical Sciences, UNICAMP, Campinas-SP, Brazil. Advisor and critical revision
IVMD, Anesthesiologist, Department of Anesthesiology, Faculty of Medical Sciences, UNICAMP, Campinas-SP, Brazil. Acquisition and interpretation of data, manuscript preparation and writing
Correspondence Correspondence: Angélica de Fátima de Assunção Braga Avenida Dr. José Bonifácio Coutinho Nogueira, 225/61 Torre D 13091-611 Campinas - SP Brasil Tel.: (55 19)3521-9560 franklinbraga@terra.com.br
ABSTRACT
PURPOSE: To comparatively study the efficacy and maternal and fetal side-effects of two doses of bupivacaine associated with morphine and clonidine, administered by the subarachnoid route for cesarean section.
METHODS: The study included 66 pregnant women at term, distributed into two groups. GI: bupivacaine 8.0 mg (1.6mL) + clonidine 75µg (0.5mL) + morphine 100µg (1.0mL) and GII: bupivacaine 10mg (2.0mL) + clonidine 75µg (0.5mL) + morphine 100µg (1.0mL). The following parameters were assessed: onset and maximum level of sensory block; quality of intraoperative and postoperative analgesia; degree and duration of motor block; maternal repercussions and Apgar score.
RESULTS: The onset of sensory block, quality of intraoperative analgesia and total duration of analgesia were similar in both groups; maximum extent of sensory block predominated in T4; maximum degree of motor block (Bromage 3); time motor block regression was significantly longer in GII; Hemodynamic, respiratory repercussions, adverse maternal effects and Apgar scores were similar between groups. In both groups, there was a predominance of drowsy or sleeping patients.
CONCLUSION: The addition of morphine and clonidine to low doses of hyperbaric bupivacaine produced adequate anesthesia for cesarean section and good postoperative analgesia, without any maternal and fetal repercussions.
Key words: Adrenergic alpha-2 Receptor Agonists. Clonidine. Analgesics, Opioid. Morphine. Cesarean Section.
Introduction
Hyperbaric bupivacaine in spinal anesthesia is commonly used for the performance of cesarean delivery. Its association with adjuvant drugs not only improves the quality of intraoperative analgesia and prolongs postoperative analgesia, but allows use of smaller doses, decreasing the risk of maternal hypotension and damage to the fetus1-5. Subarachnoid opioids have been used for acute and chronic pain control2,3. Clonidine, a partial agonist of α2-adrenergic receptors, interacts with local anesthetics in the neural axis. The analgesic effect of the drug is quite evident, due to its action on spinal and supraspinal α2-adrenergic receptors (CNS), including activation of α2 postsynaptic receptors from noradrenergic descending pathways of cholinergic neurons and the release of nitric oxide and substances such as encephalin5-7. In cesarean section, the morphine dose recommended to produce satisfactory intra- and postoperative analgesia is 100 to 200µg, while the recommended for clonidine doses range from 15 to 150µg2,6-8.
The aim of this study was to comparatively evaluate the effectiveness of different doses of hyperbaric bupivacaine associated with morphine and clonidine in the quality of block and maternal and neonatal repercussions, in pregnant women undergoing cesarean section under spinal anesthesia.
Methods
The study was performed after obtaining approval from the Medical Research Ethics Committee of the institution (CEP-number 325/2011) and informed consent signature. This was a double-blind, randomized clinical trial, which consecutively included pregnant women at term, physical status ASA 1 and 2, undergoing elective cesarean section and receiving spinal anesthesia. Exclusion criteria were: contraindications to spinal block, prematurity, multiple pregnancy, preeclampsia, history of hypersensitivity to drugs used, previous administration of opioids and/or other CNS depressants, Body Mass Index (BMI) > 40.
Based on the results of Braga et al.9, considering that the dependent variable time for motor block regression was 255.75 ± 71.47 minutes, when a combination of bupivacaine 10mg + clonidine 75µg + morphine 100µg was used in the subarachnoid space, and assuming that decreasing bupivacaine dose to 8mg associated with the same adjuvants in the same doses (clonidine 75µg + morphine 100µg), time for motor block regression would be reduced by 20%. Using type error (0.05) and type β error (0.2) - a power of test of 80%, the number of cases calculated per group was 33. Therefore, an "n"of 66 subjects distributed into 2 groups was required to assess the differences existing between groups for the variable studied.
Sixty-six (66) subjects were randomly allocated to 2 groups (GI and GII), using randomization software (SAS 9.1). Both the anesthesiologist performing the block and the anesthesiologist evaluating the parameters studied were blinded to the idenity of the spinal solution employed.
In both groups, the LA used was hyperbaric bupivacaine 0.5% associated with adjuvant morphine and clonidine. Two groups were formed, according to the dose of bupivacaine used: GI - bupivacaine 8.0mg (1.6mL) + clonidine 75µg (0.5mL) + morphine 100µg (1.0mL) + saline 0.9% (0.9mL); GII-bupivacaine 10mg (2.0mL) + clonidine 75µg (0.5mL) + morphine 100µg (1.0mL) + saline 0.9% (0.5mL). Saline 0.9% was added to the solution in both groups to obtain a total volume of 4mL. The drugs used were commercial products supplied by only one manufacturer, without determination of lot number. Solution densities were analyzed by the laboratory manufacturing the drugs, using digital density meter Anton Paar Model DMA 4500, previously calibrated with milli-Q water at 37ºC. The characteristics of the resulting solutions are found in Table 1.
The pregnant women were fasted and had not been given any preanesthetic medication. In the operating room, all were continuously monitored with cardioscope in DII lead, noninvasive arterial blood pressure monitor and pulse oximeter. After venous access with an 18G cannula, 500 to 750 mL of lactated Ringer's solution was administered before the spinal block. Subarachnoid anesthesia was performed at the L3-L4 interspace with the patients in the sitting position. A Whitacre 27G or Quincke 25G needle was used, in case of a technically difficult spinal anesthesia. The anesthetic solution was injected at a rate of 1mL.15s-1, without barbotage. After performance of the spinal block, the pregnant women were placed in the supine position, and a Crawford wedge was used for left uterine displacement until birth. Supplemental oxygen was administered (2 to 3 L.min-1) with the aid of nasal prongs. Hydration was maintained with lactated Ringer solution (10mL.kg-1.hour-1). The following parameters were studied: 1) onset of sensory block - time elapsed from the end of intrathecal injection of the anesthetic (evaluated each minute) to loss of painful pinprick sensation in T10; 2) maximum level of sensory block-evaluated 20 minutes after the end of anesthetic injection; 3) maximum level of motor block - evaluated 20 minutes after the end of anesthetic injection, according to a modified Bromage scale: 0 = free movement of the lower limbs (nil); 1 = able to flex knees and move feet; 2 = just able to flex feet; 3 = completely unable to move lower limbs; 4) time for motor block regression- time interval between end of anesthetic injection in the subarachnoid space and free movement of the lower limbs (0 - nil); 5) discomfort in the intraoperative period - complaint of pain (VNS > 3) requiring the intravenous use of opioid (fentanyl 100µg) associated with midazolam (1 to 2 mg); 6) total duration of analgesia - time interval between the end of solution injection in the subarachnoid space and spontaneous complaint of pain (VNS> 3) reported by the patient during stay in the postanesthetic care unit (PACU). The use of tenoxicam (40mg) and dipyrone (30 mg.kg-1) was adopted, only after the first spontaneous complaint of pain (VNS > 3), while in the PACU; 7) maternal cardiovascular and respiratory parameters: mean arterial pressure (PAM - mmHg), heart rate (HR-beats per minute), respiratory rate (breaths per minute) and oxygen saturation (SpO2 - %), were assessed in the following time points: before the block (M0); immediately after the block (M1); every five minutes during surgery (M2); and at the end of surgery (M3); 8) level of consciousness in the intraoperative period, according to a scale proposed by Filos et al.10 and modified by Braz et al.11: 1= awake (anxious, agitated); 2= awake (calm); 3=drowsy; 4=asleep (awakes with verbal stimulation); 9) intraoperative maternal side-effects: nausea, vomiting, pruritus, respiratory depression (SpO2 < 90% and respiratory rate below 10 rpm); 10) neonatal repercussions: through the Apgar score at one and five minutes.
Arterial hypotension was defined as a mean arterial blood pressure less than 70 mmHg. If present, hypotension was treated with a rapid infusion of crystalloid solution. If persistent, it was treated with ephedrine (5mg - venous bolus); bradycardia was defined as a decrease in heart rate for values below 50 beats per minute and it was treated with atropine (10-20µg.kg-1). In anxious and agitated patients, use of venous midazolam (1.0 to 5.0 mg) was recommended.
Fetal extraction time was defined as the interval from skin incision to placental delivery. The duration of surgery (minutes) was defined as the interval from skin incision to the end of surgery.
Statistical analysis
For statistical analysis of patient characteristics, the ANOVA test was used. To study the onset of sensory block, duration of analgesia, and time for motor block regression, the Student's t test was used; for degree of motor block, level of sensory block, ephedrine requirement, maternal side-effects and level of consciousness; incidence of hypotension, the chi-square test was used; for intraoperative discomfort, Fisher's exact test was used. On statistical analysis of cardiovascular and respiratory parameters, M2 was the time point considered the average of the mean values obtained in 5-minute intervals during surgery and the MANOVA test was used. The level of significance was set at 5%.
Results
Anthropometric data analysis showed a significance difference between the groups, regarding height and body mass index (Table 2). The mean time and standard deviation for surgery duration (minutes) and fetal extraction (minutes) were: 75.48 ± 13.29 and 17.48 ± 5.50, in GI and 74.75 ± 14.69 and 16.15 ± 5.58 in GII, respectively. There was no significant difference between the groups (p=0.44).
The onset of sensory block was similar between groups (p=0.43). For maximum level of sensory block, there was a predominance of T4 level in more than 70% of cases, without any significant difference between groups. In both groups, the majority of patients had level 3 motor block and the time for motor block regression was significantly longer (p= 0.00073) in GII. In the intraoperative period, a mean time of 65.00 ± 10.00 minutes, the number of patients reporting pain (VNS> 3) was similar in both groups (p= 0.11). In GI, four patients required fentanyl (100µg) and midazolam (2.0mg) intravenously. Both groups showed similarities in the total duration of analgesia and number of patients reporting pain (VNS> 3) in the immediate postoperative period (PAC). Data relative to block characteristics are found in Table 3.
Hemodynamic repercussions were similar between the groups. A comparison of mean MAP and HR values, in the different time periods studied, did not show any significant difference between groups (p > 0.05). Individual analysis of cardiovascular parameters indicated arterial hypotension (MAP < 70 mmHg) in M2 (intraoperative period- 15 minutes), in nine and 16 patients from groups I and II, respectively, without any significant difference (p= 0.055) and in 22 patients from GI and in 20 from GII, in M2 - 60 min, without any significant difference (p = 0.07). The number of patients requiring ephedrine totaled 14 and 18 in groups I and II, respectively, without any significant difference (p= 0.97). The mean dose of ephedrine used in both groups I and II was 13.9 mg and 9.5 mg, respectively, without any significant difference (p= 0.06).
In both groups, individual analysis showed a decrease in HR (< 50 bpm) in seven patients, with four in Group I and three in Group II. This event occurred in the PACU, and the use of intravenous atropine was necessary (0.5 mg).
All patients maintained respiratory rate above 10 breaths per minute and peripheral O2 saturation between 95 and 100%. In both groups, the Apgar score ranged from 8 to 10 and 9 to 10 at one and five minutes, respectively.
Concerning the level of consciousness (Table 4), a predominance of drowsy or sleeping patients was observed in both groups. In group I, two patients were anxious (score 1).
The incidence of maternal side-effects is shown in Table 5 and occurred in a similar manner between groups. Nausea and vomiting were observed especially in the presence of arterial hypotension and at the time of the revision of the abdominal cavity. Pruritus was reported in the intraoperative and postoperative periods (PARU).
Discussion
Most cesarean sections are performed under spinal anesthesia, involving the association between local anesthetics and subarachnoid adjuvants such as opioids and alpha2-agonists. The reason to combine drugs is because the use of low doses (7.5 to 10mg) of spinal hyperbaric bupivacaine alone has been shown to be insufficient to produce adequate perioperative analgesia. The incidence of pain is reported to be around 71%1. A higher incidence of arterial hypotension (50 a 85%) has been described with the use of higher doses (12 to 15mg)2,12-14 of hyperbaric bupivacaine. In addition to high doses of local anesthetics, other factors may contribute to a higher incidence of arterial hypotension15-18, such as oxytocin infusion and factors involved in the cephalic spread of local anesthetics in the cerebrospinal fluid.
The slow onset of action of morphine can explain the low efficacy in the quality of surgical analgesia and also contributes to the delayed appearance of adverse effects, such as respiratory depression, pruritus, urinary retention, postoperative nausea and vomiting. The incidence of these effects is minimized by the use of low spinal doses of morphine (100mg), as recommended for cesarean section and used in this study, without compromising the quality of postoperative analgesia2,19-25.
Another class of drugs highlighted as adjuvants in spinal anesthesia includes the α2-adrenergic agonists. Its main representative is clonidine which interacts with local anesthetics, increasing potassium conductance in isolated neurons. This action intensifies and prolongs the conduction block of local anesthetics. It indirectly reduces the absorption of local anesthetics by a vasoconstrictor effect, mediated by α2 postsynaptic receptors, improving the quality and increasing the duration of the anesthetic block. Its mechanism of antinociception is due to action on α2-adrenoceptors in the dorsal horn of the spinal cord. This effect seems to be more intense during pregnancy4,5,7,8,22,26-28.
Although the literature reports clonidine doses ranging from 15 to 150µg, in conjunction with local anesthetics and opioids for subarachnoid use in cesarean section, there is still no consensus on the best dose to use in this type of procedure. Recently, a dose of 1.0µg/kg of clonidine combined with bupivacaine has been recommended. However, good results have been obtained with doses of 150µg. Higher doses should be avoided because of greater hemodynamic repercussions4,8,16,26,27,29.
Owing to its sympatholytic action in the CNS and peripheral nerve endings, clonidine can produce hypotension and bradycardia, mainly manifested more than 30 minutes after intrathecal injection22,30. In this study, hemodynamic alterations occurred mainly in the intraoperative period in both groups. However, these changes were not significant and occurred after birth. The number of patients presenting with arterial hypotension and requiring ephedrine in the intraoperative period was higher in group II, a fact attributed to the higher dose of bupivacaine used, since the doses of the adjuvant agents were the same and the maximum level of sensory block was similar in both groups.
Similar to our results, Lavand'homme et al.8 using different doses of bupivacaine (9 to 11mg) associated with two doses of clonidine (75 and 150 µg), also did not observe significant alterations in arterial blood pressure in the first 30 minutes. However, with a dose of 150 µg, those authors reported significant alterations in arterial blood pressure, 30 minutes after administration. In another study26, using bupivacaine doses equivalent to those employed in this study (8.0 and 10mg) associated with 50µg of clonidine, arterial hypotension was observed at 25 minutes after the performance of the block in 35% and 57% dos patients, respectively, and the authors concluded that this was a dose-dependent effect of bupivacaine.
Regarding heart rate, the mean heart rate values decreased 30 minutes after the block, without bradycardia (HR < 50 bpm). However, individual analysis showed that 45 minutes after the block the use of atropine was required in 12% and 9% of patients in groups I and II, respectively. These findings are similar to those found by Lavand'homme et al.8, who observed bradycardia in 7% and 13% of the patients 30 minutes after the use of two different doses of clonidine, 75µg and 150µg, respectively, justifying the dose-dependent bradycardic effect of clonidine.
The adverse effects on the product of conception, due to hemodynamic repercussions, were controlled by left uterine displacement, volume expansion and ephedrine. Therefore, newborns did not show any signs of fetal distress, with results similar to those described in the literature confirming the safety of drug combination used2,22,28.
The total duration of analgesia was similar in both groups, observing that 36% and 33% of patients in groups I and II reported pain after the block in the postanesthesia care unit at 163 and 191 minutes, respectively. Dipyrone and tenoxicam were used for pain control. Other authors7 evaluating the analgesic efficacy of the combined use of hyperbaric bupivacaine (12.5 mg) and morphine 100µg and two doses of clonidine (15 and 30 µg) in cesarean section, reported the absence of intraoperative pain and a mean time period of analgesia of 712 and 902 minutes, respectively, with the two different doses of clonidine.
Other studies have shown that the analgesic effect of intrathecal clonidine (50 to 150µg) associated with 0.5% hyperbaric bupivacaine (8.0 to 11mg), without morphine, and with or without a lipid soluble opioid, usually does not last longer than 246 minutes8,26,27.
In our study, pain in the intraoperative period was reported by four patients in the group receiving the lower dose of bupivacaine and occurred in a mean time period of 65 minutes. These findings are in agreement with those reported by Kothari et al.26 who used the same doses of bupivacaine employed in this study, associated with only 50µg of clonidine, and also observed discomfort in 4.28% of patients from the group receiving 8mg of bupivacaine in the intraoperative period.
Concerning time for motor block regression, it was significantly longer in the group using 10 mg of bupivacaine. Although data in the literature4,27,28 confirm that clonidine potentiates the motor block produced by local anesthetics, the difference found between both groups may be attributed to a higher dose of bupivacaine used in group II, since the dose of clonidine was the same in all patients studied.
Due to the activation of α2-adrenergic receptors in the Central Nervous System (CNS), clonidine causes a reduction in the release of norepinephrine from the Locus Coeruleus and an increase in the activity of inhibitory interneurons (GABA), with consequent sedation, anxiolytic action and hypnosis. This dose-dependent effect occurs 20 to 30 minutes after administration5,7. Systemic administration of high doses of morphine can also alter the level of consciousness, an effect attributed to its action on K (kappa) receptors in the CNS.2 Similarly to other studies8,22,26,28 that have described an important sedative effect of clonidine, we observed that more than 75% of patients in both groups, were drowsy and asleep, 30 minutes after performance of the block.
Pruritus, attributed to morphine, was the most common side effect found in this research study. It occurred in 72% and 84% in groups I and II, respectively, results similar to those described in the literature where 85% of pruritus is reported 45 minutes after the use of 100µg subarachnoid morphine for cesarean section7,19.
Conclusion
Morphine and clonidine to low doses of hyperbaric bupivacaine produced adequate anesthesia for cesarean section and good postoperative analgesia, without any maternal and fetal repercussions.
Received: September 3, 2012
Review: October 10, 2012
Accepted: November 28, 2012
Conflict of interest: none
Financial source: none
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Publication Dates
-
Publication in this collection
18 Jan 2013 -
Date of issue
Jan 2013
History
-
Received
03 Sept 2012 -
Accepted
28 Nov 2012 -
Reviewed
10 Oct 2012