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Yeungnam Univ J Med > Volume 35(1); 2018 > Article
Do, Cho, Kim, Kim, Kim, and Lee: Ultrasound-guided superficial cervical plexus block under dexmedetomidine sedation versus general anesthesia for carotid endarterectomy: a retrospective pilot study

Abstract

Background

Carotid endarterectomy (CEA) has been performed under regional and general anesthesia (GA). The general anesthesia versus local anesthesia for carotid surgery study compared the two techniques and concluded that there was no difference in perioperative outcomes. However, since this trial, new sedative agents have been introduced and devices that improve the delivery of regional anesthesia (RA) have been developed. The primary purpose of this pilot study was to compare intraoperative hemodynamic stability and postoperative outcomes between GA and ultrasound-guided superficial cervical plexus block (UGSCPB) under dexmedetomidine sedation for CEA.

Methods

Medical records from 43 adult patients who underwent CEA were retrospectively reviewed, including 16 in the GA group and 27 in the RA group. GA was induced with propofol and maintained with sevoflurane. The UGSCPB was performed with ropivacaine under dexmedetomidine sedation. We compared the intraoperative requirement for vasoactive drugs, postoperative complications, pain scores using the numerical rating scale, and the duration of hospital stay.

Results

There was no difference between groups in the use of intraoperative antihypertensive drugs. However, intraoperative inotropic and vasopressor agents were more frequently required in the GA group (p<0.0001). In the GA group, pain scores were significantly higher during the first 24 h after surgery (p<0.0001 between 0-6 h, p<0.004 between 6-12 h, and p<0.001 between 12-24 h). The duration of hospital stay was significantly more in the GA group (13.3±4.6 days in the GA group vs. 8.5±2.4 days in the RA group, p<0.001).

Conclusion

In this pilot study, intraoperative hemodynamic stability and postoperative outcomes were better in the RA compared to the GA group.

INTRODUCTION

Carotid endarterectomy (CEA) has been successfully performed under regional anesthesia (RA) and general anesthesia (GA). A large randomized multicenter study of general anesthesia versus local anesthesia for carotid surgery (GALA) was conducted to determine whether GA or RA resulted in the better outcomes, including the proportion of patients with stroke, myocardial infarction (MI), or death within 30 days after anesthesia; survival free of stroke, MI or death up to 1 year after anesthesia; length of stay in hospital and blood pressure manipulation [1]. The GALA study concluded that the anesthetic technique does not affect perioperative outcomes. However, the trial has been criticized due to the wide variability in methodology; general anesthetic techniques were compared with a variety of regional anesthetic techniques. In addition, clinical practice had changed over the 8-year trial period. Since this study, there have been improvements in regional anesthetic techniques, intraoperative sedation, and the use of ultrasound guidance for RA [2,3]. In the GALA trial, RA was performed using landmark-guided superficial or deep cervical plexus block, which has been replaced by ultrasound-guided block, a method that allows direct visualization of structures and injection of local anesthetic [3].
The α2-adrenoreceptor agonist sedative, dexmedetomidine, is widely used in anesthetic practice. The α2-adrenoreceptors mediate sedation, sympatholysis, inhibition of vasoconstriction, and antinociception. The advantage of dexmedetomidine is that it has minimal respiratory depression [4]. Moreover, compared to sedation with a combination of midazolam and propofol, dexmedetomidine is less likely to cause perioperative hypertension and tachycardia. It also decreases intraoperative and postoperative anxiety and the need for opioids for postoperative pain control [5]. However, perioperative hypotension and bradycardia can occur [6].
Although the GALA trial did suggest a tendency towards a better hemodynamic profile in the RA group, the trial did not focus on the use of sedatives or perioperative hemodynamic status. The purpose of this pilot study was to test the hypothesis that for CEA, intraoperative hemodynamic stability is improved using an ultrasound-guided superficial cervical plexus block (UGSCPB) with dexmedetomidine sedation compared to GA. The primary outcome of this study was the requirement for vasoactive drugs between the two groups. Postoperative hemodynamic stability, pain severity, and complications within 1 year were also compared.

MATERIALS AND METHODS

1. Study design

This study was approved by the Institutional Review Board and exempted from the need to obtain informed consent. We retrospectively reviewed the electronic medical records of adult patients (aged between 46 and 91 years) who underwent CEA from June 2012 to July 2015. We chose this period because a single surgeon performed all CEA procedures during this time. We excluded patients who underwent a combined surgical procedure with CEA or underwent emergency surgery. The anesthetic technique was routinely determined by the anesthesiologist and the surgeon depending on the clinical condition of the patient. Patients were divided into the GA and the RA groups.

2. Anesthetic technique

Anesthesia was performed according to hospital protocols. In both groups, intraoperative monitoring included electrocardiography, invasive blood pressure (BP) measured from the radial artery, pulse oximetry, bispectral index monitoring (BIS; Bispectral IndexTM, Aspect Medical System Inc., Norwood, MA, USA), and near-infrared spectroscopy (NIRS; INVOS 5100; Somanetics Corp., Troy, MI, USA). GA was induced with intravenous propofol (1-2mg/kg), remifentanil (0.1 μg/kg/min), and rocuronium(1.0 mg/kg) and maintained with sevoflurane and remifentanil. Sevoflurane was titrated to a BIS score of 40-60. Remifentanil was titrated to maintain the mean arterial pressure at 80% of the baseline. Mechanical ventilation was carried out with an oxygen/air mixture (fraction of inspired oxygen, 0.5) to maintain the end-tidal carbon dioxide at 30-40mmHg. RA was performed by UGSCPB. After negative aspiration, 8-12mL of 0.375-0.5% ropivacaine was injected beneath the sternocleidomastoid muscle. The sternocleidomastoid muscle was directly visualized sonographically (Vivid i, GE Healthcare, Wauwatosa, WI, USA) using a 12L-RS, 5-13MHz linear probe. Prior to incision, a loading dose of dexmedetomidine (1.0 μg/kg) was administrated over 10 minutes, followed by a maintenance infusion at 0.5 μg/kg/h, and adjusted to maintain a BIS score of 60-80 (infusion rate: 0.1-1.0 μg/kg/h). Adequacy of the RA was not documented; however, lidocaine (0.5%) administered by the surgeon to treat intraoperative pain is common practice in our institution. Hypertension and tachycardia were managed with diltiazem (5-10mg), esmolol (10-20mg), labetalol (10mg), or nicardipine (1-2mg). To treat hypotension and bradycardia, intravenous ephedrine (10mg bolus) or atropine (0.5mg bolus) was administered. Persisting hypotension and bradycardia were treated with a continuous infusion of dopamine, dobutamine, norepinephrine, or phenylephrine. Postoperative pain was managed by the surgeon; morphine, 3mg, and ketorolac, 30 mg were administered according to the numerical rating scale (NRS) until the pain was controlled.

3. Outcome variables

Demographic data, including the American Society of Anesthesiologists physical status, age, sex, weight, height, and coexisting diseases were obtained from the electronic medical records. Details on surgery-related outcomes, including the side of surgery, duration of surgery, type of anesthesia, carotid artery cross-clamping, and the use of a shunt were also obtained. Hemodynamic instability was categorized into three groups: none, no intervention; mild, 1 or 2 doses of vasoactive medication; severe, ≥3 doses or a continuous infusion of vasoactive medication. We identified the frequency and timing of vasoactive drugs administered during surgery: T1, during the administration of dexmedetomidine or after intubation; T2, at skin incision; T3, before carotid artery crossclamping; T4, after carotid artery cross-clamping; T5, at the completion of surgery. Hemodynamic profiles during the 24 h postoperative period and the duration of hospital stay were recorded. Postoperative pain was rated using the NRS and recorded at 0-6 h, 6-12 h, and 12-24 h after surgery. Major complications including cardiovascular, respiratory, and neurological complications within 1 year were also compared.

4. Statistical analysis

Data are presented as number (%), mean±standard deviation, or median (interquartile range). All continuous variables were checked for normal distribution with a Q-Q plot and the Kolmogorov-Smirnov test. Continuous variables that were normally distributed were compared with the Student’s t-test. The frequency of interventions for hemodynamic instability and complications were compared with the chi-square or the Fisher’s exact test. Postoperative NRS was compared using two-way repeated measures ANOVA with Bonferroni correction. For Bonferroni correction, a p-value of less than 0.0083 (0.05/6) was considered significant. For other statistical tests, a p-value of less than 0.05 was considered significant. All analyses were performed using SPSS version 18.0 (SPSS Inc., Chicago, IL, USA).

RESULTS

Forty-eight patients underwent CEA during the study period. Five patients were excluded as they had combined or emergency surgery. Of the remaining 43 patients, 16 received GA and 27 received RA (Fig. 1).
Demographic data were not different between the two groups (Table 1). In the RA group, no patient required conversion to GA and no local anesthetic-related adverse effects were noted. Duration of surgery, anesthesia, and carotid artery cross-clamping were longer, and a shunt was used more frequently in GA group (Table 1). The frequency of intervention for hypertension and tachycardia was similar between groups; however, inotropic and vasopressor agents were more frequently used in the GA group (p<0.0001, Table 2). In the RA group, an antihypertensive drug was required in 51.9% of patients at the time of administration of the loading dose of dexmedetomidine. In the GA group, 50% of patients required an antihypertensive drug after intubation and at the time of the skin incision. An infusion of inotropic or vasopressor agents was required in 75% of patients in the GA group. In contrast, 18.5% of patients in the RA group required inotropic or vasopressor agents (Fig. 2). Intervention for hypertension was more frequently required in the GA group at the time of skin incision (50% in the GA group vs. 3.7% in the RA group, p=0.001) and at the completion of surgery (31.3% in the GA group vs. 3.7% in the RA group, p=0.039). Use of inotropic and vasopressor agents was significantly more frequent in the GA group throughout the surgery (All p<0.01, Fig. 2).
Postoperative hemodynamic stability was not different between groups. Only 6.2% of patients in the GA group and 18.5% of patients in the RA group required intervention for hypotension, while 56.2% of patients in the GA group and 44.4% in the RA group received antihypertensive agents. NRS during the first 24 hours postoperatively was significantly higher (p<0.0001 between 0-6 h, p<0.004 between 6-12 h, and p<0.001 between 12-24 h), and the duration of hospital stay was significantly longer (13.3±4.6 vs. 8.5±2.4 days, p<0.001) in the GA group. The incidence of major complications was similar in both the groups (Table 3).

DISCUSSION

In this study, we found that intraoperative hemodynamic stability was better in the RA group compared to the GA group. The NRS during the first 24 h postoperatively and the duration of hospital stay were higher in the GA group. However, major postoperative complications within 1 year were not significantly different between groups.
RA has the advantage of ease of assessment of neurological status during carotid cross-clamping. RA has been in use for CEA for over 15 years. The GALA [1] and the other studies [7,8] have not identified a statistically significant difference in the incidence of major perioperative outcomes, such as stroke, MI, or death between RA and GA. However, if major perioperative outcomes were similar between GA and RA, hemodynamic stability, postoperative pain, minor complications, and duration of hospital stay may be appropriate outcomes to determine the better anesthetic technique for CEA. Thus, well-standardized RA with advanced techniques needs to be compared with GA to evaluate perioperative outcomes.
Despite the ease of perioperative neurological assessment with RA, this technique has several risks. Systemic toxicity from local anesthetics can be a life-threatening complication resulting from intravascular injection or overdose [9]. Puncture-related complications include vertebral artery injection, subarachnoid or epidural injection, Horner’s syndrome, phrenic nerve block, and local hematomas [10]. Advantages of ultrasound-guided block over the landmark-based technique include the ability to control the depth of needle insertion and avoid inadvertent puncture of neighboring structures [11]. Ultrasonography is now commonly used for the visualization of real-time images when performing nerve blocks. The advantages of the ultrasound-guided technique over the landmark technique are the direct visualization of nerves and adjacent anatomical structures, observation of the needle and local anesthetic spread during injection, detection of anatomical abnormalities, and reduced volume of local anesthetic [12], leading to a lower incidence of RA-related complications and increased safety. In our study, superficial cervical plexus block was performed with 8-10mL of ropivacaine (0.375-0.5%), which is less than the 20-30mL volume recommended with the landmark technique [13-15]. In the GALA study, 4.4% of patients in the RA group had complications that led to the cancellation of surgery or conversion to GA[1]. The reasons for cancellation of surgery or conversion to GA were patient preference, problems with positioning the patient, deterioration of clinical condition after local-anesthetic block, pain at the operative site, general anxiety, physiological instability, difficult surgery, and neurological deterioration on cross-clamping [1]. In our study, however, no patient required conversion to GA. Precise identification of the superficial cervical plexus by ultrasonography results in the use of a smaller volume of local anesthetic compared to the landmark technique to provide an adequate nerve block for CEA.
Hemodynamic instability is very common during CEA due to impaired autoregulation of arterial pressure after a stroke and reduced baroreceptor sensitivity because of carotid atherosclerosis; besides, the effects of carotid surgery, anesthesia, age, diabetes, and antihypertensive medications may also lead to hemodynamic instability [16]. With the use of GA, patients are more likely to be hypotensive and generally require vasopressor support [17-19]. In the postoperative period, patients who undergo GA are likely to be hypertensive, due to emergence from anesthesia and possibly, pain. The perioperative course was similar in patients who underwent GA in our study.
On the other hand, patients receiving RA are often hypertensive during surgery, particularly during the cross-clamp period; however, they become hypotensive after surgery [20]. These observations may be explained by preserved cerebral autoregulation when the patient is awake [21]. Local anesthesia inhibits carotid sinus nerve fibers beneath the carotid bifurcation and decreases baroreceptor sensitivity, leading to increased intraoperative sympathetic activity [22]. Additionally, the stressful, awake state and absence of GA-related cardiovascular depression might increase the incidence of hypertension and tachycardia [23]. However, except at T1, only 25.9% of patients who underwent RA required intervention for hypertension and tachycardia in our study. This is likely due to dexmedetomidine infusion, which is associated with fewer interventions for the treatment for hypertension and tachycardia, and less postoperative pain compared with other sedatives [5,6]. In a previous study, 40% patients who received dexmedetomidine required treatment for hypertension and tachycardia, compared with 72% of patients who received fentanyl and midazolam sedation [6]. A concern in the RA group of our study was the hypertension observed during administration of the loading dose of dexmedetomidine, with 50% of patients requiring a vasodilator. Dexmedetomidine produces vasoconstriction by acting on peripheral α2b-adrenoreceptors while simultaneously exerting sympatholytic effects by binding to central α2a-adrenoreceptors [24]. In anesthetized subjects or subjects with reduced sympathetic nervous system tone, increasing doses of dexmedetomidine have a more prominent vasoconstrictor effect [25]. However, this can be easily managed with low doses of vasodilators, such as diltiazem(10 mg) or nicardipine (1mg).
The greatest advantage of RA during CEA is the continuous and direct feedback of brain function that it provides to the surgeon. During carotid clamping, assessment of brain function in the awake patient reliably alerts the surgeon to the need for a shunt. Since assessment of brain function could not be done in patients under GA, a shunt was placed more frequently, and intraoperative monitoring of brain function was done more often in patients in the GA group. The GALA trial demonstrated a 29% reduction in the use of a shunt with RA compared to GA [1]. In our study, shunts were used in 93.8% patients receiving GA and 18.5% in patients with RA. Although the use of a shunt is common practice and should protect the brain from stroke [26,27], intraoperative shunt placement is a strong predictor of perioperative strokes [28].
Postoperative pain was significantly lower in the RA group in our study. The difference within the first 6 hours could be the combined effect of RA and dexmedetomidine. Additionally, patients in the GA group received a remifentanil infusion, which causes postoperative hyperalgesia [29]. Overall, postoperative complications occurred more frequently in patients who underwent GA, and major complications, including MI and acute asthma, occurred in the GA group. The duration of hospital stay was significantly longer in the GA (13.3±4.6 days) than in the RA group (8.5±2.4 days). Our results are similar to those of a recently published study [30], in which patients who underwent GA had a significantly higher odds ratio for postoperative MI, acute congestive heart failure, and hemodynamic instability compared to RA. Additionally, the GA group showed extended duration of hospital stay for more than one day in their study.
There are several limitations in this study. First, we included only 43 patients according to the post hoc power analysis with comparison of the occurrence of intraoperative hypotension between the GA and the RA groups as one of the primary outcomes [31]. However, our results should be interpreted cautiously. In particular, considering the low incidence of major complications after CEA, no definitive conclusions can be drawn. Second, the reason for the choice of anesthetic technique was not specified in the medical records, which might be a potential source of bias. The anesthetic technique was chosen according to the physical status and patient characteristics, preference of the surgeon and the anesthesiologist, which may have influenced the results of our study.
This retrospective pilot study suggests that for CEA, UGSCPB with dexmedetomidine sedation provides better intraoperative hemodynamic stability and more favorable postoperative outcomes compared to GA. Large prospective studies are needed in the future before conclusions can be drawn about the validity of our findings. In addition, a prospective randomized controlled trial should compare outcomes between well-standardized RA and GA.

Conflicts of interest

No potential conflict of interest relevant to this article was reported.

Fig. 1.
Flow diagram of the patients.
yujm-2018-35-1-45f1.jpg
Fig. 2.
Frequency and timing of antihypertensive drugs (A) and inotropic or vasopressors (B) administrating during surgery. T1, during administration of dexmedetomidine or after intubation; T2, at skin incision; T3, before carotid artery cross-clamping; T4, after carotid artery cross-clamping; T5, at the end of the operation. a) p<0.005 compared with regional anesthesia group.
yujm-2018-35-1-45f2.jpg
Table 1.
Demographic data and intraoperative outcomes
Variable GA (n=16) RA (n=27) p-value
ASA physical status (II/III) 12 (75)/4 (25) 21 (77.8)/6 (22.2) 1.000
Sex (male) 14 (87.5) 23 (85.2) 1.000
Age (year) 72.7±8.2 68.1±9.8 0.124
Weight (kg) 62.9±9.0 65.7±8.6 0.318
Height (cm) 164.9±8.0 164.7±5.4 0.919
Coexisting diseases
 Diabetes 7 (43.8) 8 (29.6) 0.348
 Hypertension 11 (68.8) 21 (77.8) 0.768
 Ischemic heart disease 4 (25.0) 12 (44.4) 0.202
 Hyperlipidemia 3 (18.8) 4 (14.8) 0.929
 TIA/stroke 3 (18.8) 6 (22.2) 0.906
 COPD 3 (18.8) 1 (3.7) 0.291
 Renal failure 1 (6.3) 2 (7.4) 0.635
Indication for surgery 0.878
 Asymptomatic carotid stenosis 1 (6.3) 4 (14.8)
 TIA 9 (56.3) 16 (59.3)
 Stoke 6 (37.5) 7 (25.9)
Location of surgery (rt) 8 (50.0) 17 (63.0) 0.303
Duration of surgery (min) 147.8±29.6 125.6±32.0 0.029
Duration of anesthesia (min) 191.6±30.0 164.1±29.4 0.005
Duration of clamping (min) 49.1±10.4 31.5±9.8 <0.0001
Shunt 15 (93.8) 5 (18.5) <0.0001

Data are presented as mean±SD or number (%).

ASA, American Society of Anesthesiologists; GA, general anesthesia; RA, regional anesthesia; TIA, transient ischemic attack; COPD, chronic obstructive pulmonary disease; Rt, right; SD, standard deviation.

Table 2.
Hemodynamic stability during surgery
Variable GA (n=16) RA (n=27) p-value
Intervention for hypertension and tachycardia (n) 0.828
 None 7 (43.8) 14 (51.9)
 Mild 6 (37.5) 11 (40.7)
 Severe 3 (18.8) 2 (7.4)
Intervention for hypotension and bradycardia (n) <0.0001
 None 1 (6.2) 22 (81.5)
 Mild 3 (18.8) 4 (14.8)
 Severe 12 (75.0) 1 (3.7)
Drugs to treat hypertension and tachycardia
 Diltiazem 5 (31.3) 16 (59.3)
 Esmolol 5 (31.3) 1 (3.7)
 Nicardipine 1 (6.3) 5 (18.5)
 Labetalol 0 (0) 3 (11.1)
Drugs to treat hypotension and bradycardia
 Ephedrine 9 (56.3) 2(7.4)
 Atropine 0 (0) 2 (7.4)
 Dopamine 9 (56.3) 1 (3.7)
 Dobutamine 1 (6.3) 0 (0)
 Norepinephrine 1 (6.3) 0 (0)
 Phenylephrine 3 (18.8) 0 (0)

Data are presented as number (%).

GA, general anesthesia; RA, regional anesthesia; n, number; None, no intervention; Mild, 1 or 2 injections of drugs; Severe, 3 injections of drugs or infusion.

Table 3.
Postoperative outcomes
Variable GA (n=16) RA (n=27) p-value
Hemodynamic profiles
 Intervention for hypertension and tachycardia (n) 0.697
  None 7 (43.8) 15 (55.6)
  Mild 4 (25.0) 8 (29.6)
  Severe 5 (31.2) 4 (14.8)
 Intervention for hypotension and bradycardia (n) 0.539
  None 15 (93.8) 22 (81,5)
  Mild 0 (0) 4 (14.8)
  Severe 1 (6.2) 1 (3.7)
NRS 0.007
 0-6 hr 6 (5-8) 4 (2-5) <0.0001a)
 6-12 hr 5 (3-5) 2 (0.5-3.5) 0.004a)
 12-24 hr 3 (2-3) 2 (0.5-2) 0.001a)
Complications
 Neurologic 6 (37.5) 7 (25.9) 0.649
 Cardiac 1 (6.2) 2 (7.4) 0.635
 Respiratory 1 (6.2) 0 (0) 0.788
Hospital stay (day) 13.3±4.6 8.5±2.4 0.001

Data are presented as mean±SD, median (interquartile range) or number (%).

GA, general anesthesia; RA, regional anesthesia; NRS, n, number; numeric rating scale; SD, standard deviation; None, no intervention; Mild, 1 or 2 injections of drugs; Severe, 3 injections of drugs or infusion.

a) The significance level after Bonferroni correction is 0.0083.

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