Introduction

Laparoscopic liver resection is increasingly used in patients with hepatocellular carcinoma (HCC).¹ Although laparoscopic surgery is minimally invasive, a significant number of patients continue to experience moderate to severe pain after laparoscopic surgery.² Postoperative pain after laparoscopic liver resection is complex and multifactorial, consisting of both somatic and visceral pain caused by gas distension of the abdominal wall, port placement, and dissection in the abdominal cavity.^3,4 Therefore, analgesic modalities should provide upper and lower abdominal analgesia, including epigastric area, umbilical area as well as the lower abdomen. Previous studies have evaluated analgesic strategies including intrathecal morphine administration and single-injection erector spinae plane (ESP) block in laparoscopic liver resection,^3,4 but there is limited evidence to draw relevant conclusions mandating effective analgesic management.

Numerous studies have reported that the erector spinae plane (ESP) block can be a potentially valuable regional anesthesia technique in various abdominal surgeries performed at a lower thoracic vertebral level (T7 or T8).^4–8 Furthermore, the relatively safe profile of ESP block, including the absence of major blood vessels and neural structures, can be advantageous to other invasive techniques such as thoracic epidural analgesia or paravertebral blocks, especially when postoperative coagulopathy is a major concern after liver surgery. However, the analgesic duration and efficacy remain inconsistent after single-injection ESP blocks in liver surgery.^3,4 In addition, the risk of local anesthetic systemic toxicity can pose even greater concern in these subset of patients after the removal of substantial volume of liver where extensive local anesthetic metabolism takes place. Therefore, we sought to identify alternative analgesic modalities with favorable analgesic efficacy and safety profiles.

The quadratus lumborum (QL) block is an abdominal trunk block. Out of the three possible approaches of QL blocks (lateral, posterior, or anterior), posterior or anterior QL block provides widespread (T4 to T12 or L1) and long-lasting (up to 48 h) upper and lower abdominal analgesia.^9,10 Recent studies have shown that anterior QL block can reduce opioid consumption and pain scores in patients undergoing liver resection.^11,12 Therefore, we expected that posterior or anterior QL block would be suitable analgesic option for liver surgery. However, the analgesic efficacy of posterior QL block in liver surgery has not been compared with that of ESP block. Therefore, we conducted a randomized trial to test the hypothesis that, bilateral posterior QL block would improve the quality of postoperative analgesia in the first 24 h after laparoscopic liver resection compared to that of ESP block. Furthermore, we measured the chronological changes in arterial ropivacaine concentrations in both block groups to determine the safety of the local anesthetic dose in patients.

Patients and Methods Study Participants

This study was conducted in accordance with the Declaration of Helsinki. After receiving approval from the Samsung Medical Center Research Ethics Board (SMC 2020-01-035-006), this trial was prospectively registered with the Clinical Research Information Service (CRiS) trial registry of South Korea (identifier: KCT0005077; date of registration: 02/06/2020; principal investigator's name: RyungA Kang). Written informed consent was obtained from all participants. We enrolled adult patients with American Society of Anesthesiologists physical status classifications I–III scheduled for elective laparoscopic liver resection, including segmentectomy, right anterior sectionectomy, left lateral sectionectomy, right or left hepatectomy, or right or left extended hemihepatectomy between December 2020 and July 2021 at Samsung Medical Center, Seoul, Korea. We excluded patients who refused to participate in the study, had contraindications to peripheral nerve block, had systemic infectious disease, or had an allergy to local anesthetics in the standardized postoperative analgesic regimen.

Randomization and Blinding

A hospital staff member who was not otherwise involved in the study performed computer-generated block randomization (www.randomizer.org) in a 1:1 ratio to allocate enrolled patients to an ESP group (n=44) or a QL group (n=44). The randomization number and allocation of each patient were concealed in a password-protected log file. All blocks were performed by a single investigator who was experienced in the technique (RyungA Kang).⁴ This investigator was not involved in the outcome assessment or further patient management. Study participants and the outcome assessor (Seungwon Lee) were blinded to group allocation. To maintain the blinding of the participants, all blocks were performed after induction of general anesthesia. All methods were carried out in accordance with relevant guidelines and regulations.

Erector Spinae Plane Block or Quadratus Lumborum Block

In the ESP group, the patients were placed in the right lateral position after induction of general anesthesia. Ultrasound-guided bilateral ESP blocks at the level of the T8 transverse process were performed as previously described.^4,8 Using a high-frequency (6 to 13 MHz) linear probe, T8 transverse process was identified and the left ESP block (upper side) was performed first. A 21-gauge, 100-mm echogenic needle (SonoPlex STIM, PAJUNK, Geisingen, Germany) was inserted in-plane in a cranial-to-caudal direction to contact the T8 transverse process. The correct needle tip position was confirmed by a linear pattern of injectate spread lifting the erector spinae muscle off the transverse process and 20 mL of 0.375% ropivacaine was injected through the needle. The right ESP block was performed in an identical manner without patient repositioning.

In the QL group, ultrasound-guided bilateral posterior QL block was performed with the patients in the supine position after the induction of general anesthesia. The reason for choosing the posterior QL block out of the three possible approaches (lateral, posterior, or anterior) was because it was indicated for any abdominal surgery above and below umbilicus with wide dermatomes coverage from T4 to T12 or L1.¹⁰ In addition, posterior QL block is associated with reduced pain scores after laparoscopic ovarian surgery⁹ and reduced opioid requirements after cesarean section when compared to placebo¹³ or transverse abdominis plane block.¹⁴ If necessary, a thin pillow was placed under the patient's hip, or an operating table was laterally tilted to obtain a better ultrasound image. Using a high-frequency linear probe or a convex probe (X-porte; SonoSite, Bothell, Washington, USA), the three muscle layers of the lateral abdomen; external oblique, internal oblique, and transversus abdominis muscles, and the quadratus lumborum muscle were visualized. The same echogenic needle that was used for the ESP block was inserted in-plane using an anterior-to-posterior trajectory. A local anesthetic (20 mL of 0.375% ropivacaine) was injected on the posterior surface of QL muscle (ie, posterior QL block).^10,15 A successful blockade was indicated by the spread of local anesthetics around the posterior surface of QL muscle under the ultrasound. Another injection was performed identically on the other side. A total of 40 mL 0.375% ropivacaine (150 mg) was administered bilaterally in both the ESP and QL blocks. Dosing guidelines (volume and type of local anesthesia) were based on a combination of existing evidence and institutional experience.^4,5,16

Intraoperative Management

General anesthesia was induced with intravenous (IV) thiopental (4–6 mg·kg⁻¹) and rocuronium (0.6–0.8 mg·kg⁻¹) followed by tracheal intubation. Anesthesia was maintained with sevoflurane in a 1:1 oxygen:air mixture and IV remifentanil (0.01–0.05 µg·kg⁻¹·min⁻¹) infusion. The mean arterial blood pressure was maintained above 65 mmHg.¹⁷ All patients received IV meperidine 0.5 mg·kg⁻¹ 30 min before the end of surgery in accordance with the institutional protocol.^3,4,8 The same surgical team performed all surgical procedures (Gyu-Seung Choi or Jong Man Kim).

Postoperative Post-Anesthesia Care Unit and Postoperative Pain Management

After surgery, patients were transferred to the post-anesthesia care unit (PACU). Resting pain severity was assessed by the PACU nurse using an 11-point numeric rating scale (NRS; 0 = no pain and 10 = worst pain). All patients received a standardized postoperative supplemental analgesic regimen.^3,4,8 IV patient-controlled analgesia (PCA) with fentanyl was initiated at the first complaint of surgical site pain (NRS≥1/10), which deliver a bolus dose of 15 µg (1 mL) of fentanyl and a lockout time of 15-min, without background infusion. If the NRS was more than 4/10, IV meperidine 25 mg was administered as first-line therapy in the PACU. IV hydromorphone 0.08–0.1 µg·kg⁻¹ was administered as second-line therapy. Postoperative nausea or vomiting was treated with IV metoclopramide 10 mg. A PACU nurse recorded all PACU data, including opioid consumption, nausea or vomiting, and pain scores on admission, at discharge, and the highest reported pain score during the PACU stay.

In the general ward, all patients received multimodal analgesia consisting of (1) 400 mg of IV ibuprofen (Huons, Seoul, South Korea) every 6 h (maximum 6 doses); (2) one tablet of oral C·I·A capsule^® (codeine phosphate 10 mg/ibuprofen 200 mg/acetaminophen 250 mg; Myungmoon Pharmacy, Seoul, South Korea) every 8 h; (3) IV fentanyl PCA; and (4) 1 mg of IV hydromorphone every 4 h as needed as rescue analgesia.^3,4,8

Outcome and Outcome Measures

The primary outcome used to assess the quality of postoperative analgesia was cumulative opioid consumption at 24 h postoperatively. This was calculated as the sum of all rescue opioid doses plus total IV PCA usage and converted into IV morphine equivalents (IME).¹⁸ Secondary outcomes included (1) resting pain scores in the PACU (admission, highest, and discharge) and, at 24, 48, and 72 h postoperatively; (2) cumulative opioid consumption in the PACU and at 48 and 72 h postoperatively; (3) incidence of postoperative nausea or vomiting in the PACU and at 24, 48, and 72 h postoperatively; (4) quality of sleep on the first night using a Likert scale (1 = very dissatisfied, 2 = dissatisfied, 3 = neutral, 4 = satisfied, and 5 = very satisfied); (5) patient satisfaction with pain relief at 24 h postoperatively using a Likert scale; (6) Quality of Recovery (QoR)-15 questionnaire scores preoperatively and 24 h postoperatively (using the Korean version of the Quality of Recovery-15 scale¹⁹), which can be divided into two components: physical and mental well-being;²⁰ (7) the incidence of procedure-related complication (hematoma, infection, or needle trauma); (8) time to first flatus; (9) intraoperative remifentanil consumption; (10) block performance time defined as time from insertion of the needle to completion of the block; and (11) total arterial plasma ropivacaine concentrations at 30, 45, 60, and 240 min after local anesthetic injection. An independent outcome assessor visited each patient at predetermined time points (24, 48, and 72 h postoperatively) to collect all outcome data.

Total Arterial Plasma Ropivacaine Concentration Analysis

The right radial artery was accessed using a 20-gauge catheter after induction of general anesthesia. Arterial blood samples were collected from the indwelling arterial catheter at 30, 45, 60, and 240 min after the second dose of ropivacaine administration.⁹ According to the initial investigational plan, ropivacaine concentrations were measured at baseline (pre-block), and 30, 60, and 240 min, however, the sampling protocol was modified to include additional samples at 45 min instead of baseline to better define the peak concentration of ropivacaine. The modified protocol was approved by the Samsung Medical Center Research Ethics Board (SMC 2020-01-035-010) and reported to the CRiS trial registry of South Korea. The samples were stored at 4 °C and delivered to the clinical laboratory within 1 h of collection, where they were centrifuged at 2500 revolutions/min for 5 min at 4 °C and transferred to a −70 °C freezer for storage prior to transport to the SCL healthcare laboratory (Seoul, South Korea) for analysis. Total plasma ropivacaine concentration (measuring the sum of bound and unbound fractions) was analyzed using liquid chromatography-tandem mass spectrometry (API 4000 LC-MS/MS system, Applied Biosystems, USA) with a chromatography column. The detection limit was 5 ng/mL. The internal standard used was Ropivacaine-D7 (Santa Cruz Biotechnology, USA). A previous report presented an arterial threshold value of total ropivacaine of 4.3 ± 0.6 µg/mL for systemic toxicity.²¹

Statistical Analysis

Sample Size Calculations This study was designed as a superiority trial. Based on a previous study³ and retrospective data from our experience, we calculated the mean ± standard deviation for cumulative opioid consumption at 24 h to be 45.5 ± 21.8 mg IME. A 30% reduction in the mean cumulative 24-h opioid consumption after bilateral QL blocks compared to that with the bilateral ESP blocks was considered clinically significant. Sample size calculation using G*Power (v. 3.1.9.4), with α = 0.05 and power of 80% showed that 42 patients were required in each group. We decided to enroll 44 patients per group to allow for dropouts (5%).

Data Analyses

After determining the normality of data distributions using the Shapiro–Wilk test, continuous variables were analyzed using the t-test or Mann–Whitney U-test as appropriate. Parametric and non-parametric data are reported as mean ± standard deviation and median [interquartile ranges], respectively. Categorical variables were analyzed using the chi-square test or Fisher's exact test. For all outcomes with repeated measures (cumulative opioid consumption, pain scores, incidence of postoperative nausea or vomiting, and ropivacaine concentrations), Bonferroni correction was applied for multiple comparisons. The peak plasma concentration of ropivacaine (C_max) and time to C_max (T_max) were obtained directly from the observed concentration-time data, which are summarized as mean ± standard deviation and median [interquartile ranges], respectively. Data analyses were performed using SPSS software (ver. 27.0; SPSS Inc., Chicago, IL). Two-sided tests were used for all analyses, and P<0.05 was taken to indicate significance. All analyses were conducted using an intention-to-treat approach.

Results Study Participants

Eighty-eight patients scheduled for laparoscopic liver resection between December 2020 and July 2021 were assessed for eligibility (Figure 1). All enrolled patients (n=88) were randomly assigned to one of two groups (n=44 each). One patient in the ESP group did not receive the allocated intervention due to equipment problems, and one patient in the ESP group received allocated intervention but underwent reoperation within 24 h after surgery due to postoperative bleeding. One patient in the QL group received the allocated intervention but underwent open laparotomy conversion during surgery. These three patients were excluded from further analyses. A total of 85 patients were analyzed (ESP group, n=42; QL group, n=43). Baseline patient and surgical characteristics of the two groups were comparable, except for the significantly higher score in the QoR-15 questionnaire in the ESP group than in the QL group because the ESP group had significantly higher physical well-being scores than the QL group (Table 1). This difference was because the ESP group had significantly higher physical well-being scores than those of the QL group.

Cumulative Opioid Consumption

The primary outcome of cumulative opioid consumption at 24 h postoperatively was not significantly different between the two groups (ESP vs QL group; 41.4 ± 22.6 mg vs 44.2 ± 20.0 mg IME, mean difference [QL-ESP), 2.8 mg, 95% CI, −6.4 to 12 mg IME, p>0.99) (Table 2). There was no significant difference in cumulative opioid consumption at 48 and 72 h postoperatively (p>0.99).

Pain Score and Other Secondary Outcomes

Intraoperative remifentanil consumption and the incidence of intraoperative hypotension were similar between the groups (Table 3). There was no significant difference in resting pain scores in the PACU (admission, highest, and discharge) and, at 24, 48, and 72 h postoperatively (Figure 2). There was no significant difference between groups in terms of quality of sleep on the first postoperative night, patient satisfaction with pain relief at 24 h postoperatively, QoR-15 scores at 24 h postoperatively, including physical and mental well-being, time to first flatus, or the incidence of postoperative nausea or vomiting (Table 3). No block-related complications were reported in either group.

Total Arterial Plasma Ropivacaine Concentrations

Blood tests of the first (30 min) and third (60 min) panels of the ropivacaine assay were completed according to the designated timing in the study protocol. The second (45 min) panel of ropivacaine assays was obtained in 26 patients in the ESP group and 26 patients in the QL group due to changes in the blood sampling protocol during the study. The last panel (240 min) of ropivacaine assays was not obtained in one patient in the QL group because the timing of the tests was not in accordance with the study protocol. Total ropivacaine concentration at 30 min was significantly higher in the ESP group than in the QL group (ESP vs QL block; 1.4 ± 0.3 vs 1.1 ± 0.6 µg/mL, p=0.008) (Figure 3). The C_max was significantly higher in the ESP group (1.5 ± 0.3 µg/mL) than in the QL group (1.3 ± 0.5 µg/mL, p=0.035), but both were lower than the arterial threshold value of systemic toxicity (4.3 µg/mL). The T_max was comparable between the two groups (ESP vs QL group: 45 [30–48.8] vs 45 [30–60] min, p=0.295). All the test results were below the documented toxic concentration of 4.3 µg/mL. No adverse events or clinical symptoms indicating systemic toxicity were observed.

Discussion

In this randomized controlled trial comparing bilateral single-injection ESP blocks with bilateral single-injection posterior QL blocks, we were unable to demonstrate a difference between groups in the primary outcome of cumulative opioid consumption during the first 24 h after laparoscopic liver resection. There were no significant differences in pain scores or opioid consumption between the two blocks at 48 and 72 h postoperatively. Recovery outcomes, including postoperative nausea or vomiting, QoR-15 scores, sleep quality on the first night, and patient satisfaction, were also similar between the two groups. Plasma ropivacaine concentration at 30 min after 150 mg of ropivacaine injection was significantly lower in the QL group than in the ESP group, however, all measurements were below the cut-off value (<4.3 µg/mL) for the risk of systemic toxicity of arterial total ropivacaine concentrations.

The ESP block has emerged as a potentially useful regional anesthesia technique in abdominal surgery.^5,6 Our previous study also demonstrated the adequate analgesic efficacy of bilateral single-injection ESP blocks in donors who underwent laparoscopic donor hepatectomy.⁴ However, a recent study conducted at our institution in patients with HCC demonstrated that ESP block decreased rescue opioid dose in PACU but did not reduce opioid consumption in the first 24 h after laparoscopic liver resection compared to that with the systemic control.³ The analgesic effect of the ESP block differed between the two studies, despite being conducted in the same center and the same surgical team, might be ascribed to the differences in the detailed perioperative analgesic methodology (ESP block injection point [T8 vs T9] and IV PCA regimen) and patient characteristics (young healthy donors vs middle-aged HCC patients). The severity of postoperative pain and opioid requirements in patients with chronic liver disease was different from that in other patients.^22,23 In the current study, the pain scores and cumulative opioid consumption in the ESP group were similar to those in a previous study.³ Therefore, it can be deduced that both ESP and QL blocks may provide mainly intraoperative and immediate postoperative analgesia, as evidenced by an opioid-sparing effect in the PACU.

The QL block has been increasingly used for postoperative analgesia in various types of surgery including cesarean section,¹³ laparoscopic ovarian surgery,⁹ hip arthroplasty,²⁴ and laparoscopic hepatectomy.¹² Its analgesic effect is ascribed to the spread of local anesthetic injected between the transversalis fascia and the quadratus lumborum muscle to the thoracic paravertebral space, thus, anesthetizing the thoracolumbar nerves.¹⁰ Previous studies demonstrated that the effect of a single-injection of posterior QL block with 20 mL of 0.375% ropivacaine could spread from T4 to T12 or L1^9,10 and could last up to 48 h postoperatively,^9,14 which is relatively longer than that with single-injection ESP block (5–12 h).^7,25 Based on this, we hypothesized that the posterior QL block would provide a prolonged analgesic effect, and thus, reduce the cumulative opioid consumption within 24 h compared to the ESP block. However, the results of our study did not demonstrate the superiority of the analgesic effect of the QL block over that of the ESP block, which is consistent with a recent procedure specific postoperative pain management (PROSPECT) review that found no evidence to support QL block after open liver resection.²⁶

The ease of performance and risk of local anesthetic systemic toxicity are important in daily practice. In our clinical experience with ESP block, changing the patient's position from supine to lateral for the block procedure requires multiple personnel and increases the risk of falls, especially in anesthetized patients. In contrast, the QL block can be performed with the patient in a supine position. However, in obese patients, it is difficult to obtain high-quality ultrasound images and placing a thin pillow under the patient's hip or lateral tilt improves the images in these cases. In our study, the patient was supine, but depending on the physician's preference and patient mobility, the patient can lie lateral, sitting or prone.¹⁰ Therefore, QL block can be a favorable option in terms of ease of performance and practicality over ESP block. The major risk associated with the fascial plane block is local anesthetic systemic toxicity due to systemic absorption.²⁷ The instances of local anesthetic systemic toxicity following the ESP block have been minor to date.^28,29 In addition, no systemic toxicity was observed after the QL block with 150 mg of ropivacaine.⁹ Notably, ropivacaine is mainly eliminated by hepatic metabolism, with reduced clearance in patients with chronic liver disease.³⁰ However, in our study, the peak ropivacaine concentrations after the ESP or QL blocks were below the arterial threshold of systemic toxicity (4.3 µg/mL).²¹ Moreover, ropivacaine concentrations at 240 min after injection were also below the systemic toxicity threshold in both groups, and thus, it can be deduced that the metabolism of 150 mg of ropivacaine is not hindered even after removal of a significant portion of liver mass. Although free plasma ropivacaine concentrations were not measured in this study, our results suggest that both ESP and QL blocks with 150 mg of ropivacaine might be performed safely in patients undergoing liver surgery. This is also supported by the fact that there were no patients with any clinical signs or symptoms of local systemic anesthetic toxicity. The peak ropivacaine concentration was significantly lower in the QL group than in the ESP group, and the difference in peak ropivacaine concentration between the two blocks could be explained by the fact that the rate of local anesthetic absorption into the blood depends on the local tissue perfusion.³¹ Epinephrine added to ropivacaine decreased peak plasma concentrations and delayed the time of peak concentration in thoracic paravertebral block³² or posterior QL block.³³ Although epinephrine was not added to ropivacaine in this study, the risk of systemic toxicity would likely be lower if epinephrine was added, and further study is needed to confirm this. Since the local anesthetic was injected within recommended doses (0.2–0.4 mL/kg of 0.2–0.5% ropivacaine),¹⁰ our results for ropivacaine concentration can be generalized to a variety of clinical settings.

Several study limitations should be considered when interpreting our results. First, we did not have a control group that received systemic analgesia alone or placebo, which would have further defined the benefit afforded by ESP or QL blocks. However, the institutional ethics board prevented us from using placebo or sham blocks. Second, we only assessed resting pain scores. An assessment of pain during movement might have uncovered further functional differences in analgesic quality between the groups. Third, we did not assess block success by evaluation of dermatomal sensory loss using pinprick test or cold alcohol swab, which may have contributed to the observed results. Fourth, we only measured total plasma ropivacaine concentrations. The toxicity of ropivacaine arises from the unbound fraction of ropivacaine.²¹ Therefore, we cannot rule out the possibility that our data underestimated or overestimated the plasma concentration for toxicity. Finally, it is conceivable that the use of different types of QL block (eg, lateral or anterior), different volumes and doses of local anesthesia, or other combinations of multimodal analgesics will produce different outcomes, as the optimal regimen for ESP block or QL block in laparoscopic liver resection has yet to be determined.

Conclusion

In conclusion, bilateral single-injection QL block did not reduce cumulative opioid consumption over 24 h compared to the bilateral single-injection ESP block in patients undergoing laparoscopic liver resection. Further studies are needed to define the benefits afforded by ESP or QL blocks in patients undergoing liver surgery.

Disclosure

Prof. Dr. RyungA Kang report grants from Samsung Medical Center Grant # SMO1210471. The authors report no other conflicts of interest in this work.