Rhomboid intercostal block versus serratus block for postoperative analgesia after thoracoscopic sympathectomy for primary palmar hyperhidrosis: a randomized controlled trial

Background

Although thoracoscopic sympathectomy is made via small incisions, it is associated with severe postoperative pain. Both Rhomboid intercostal block (RIB) and serratus anterior plane block (SABP) are recent techniques used for pain control after such procedures. Herein, we compared RIB and SAPB regarding pain control in patients undergoing thoracoscopic sympathectomy for palmar hyperhidrosis.

Patients and methods

Three groups were enrolled in this prospective randomized study (71 patients in each group); Group S received SAPB, Group R received RIB and Group C as controls. The block procedures were performed after general anesthesia and prior to the skin incision.

Results

The three groups showed comparable demographics and operative time (P ˃ 0.05). Pain scores showed a significant decline with the two block procedures compared to controls during the first day following surgery (both P ˂ 0.05), but Group R had better scores compared to Group S. Both block techniques were associated with a significant prolongation of the time to first rescue analgesic and less fentanyl consumption compared to controls (both P ˂ 0.05). However, both parameters were improved with RIB rather than SAPB (both P ˂ 0.05). Both blocks led to a significant improvement in patient satisfaction than in the control group (both P ˂ 0.05), but it was comparable between the two approaches (P ˃ 0.05).

Conclusion

Both RIB and SAPB are safe and effective in pain reduction after thoracoscopic sympathectomy procedures in patients with hyperhidrosis. Moreover, RIB is superior to SAPB as it is associated with better analgesic outcomes.

Trial registration

Pan African Trial Registry PACTR202203766891354. https://pactr.samrc.ac.za/Researcher/TrialRegister.aspx?TrialID=21522

Primary palmar hyperhidrosis is a disorder characterized by chronic excessive sweating despite the absence of sweating triggers. With the evolution of surgical approaches, upper thoracic dorsal sympathectomy performed via video-assisted thoracoscopic surgery (VATS) is the main management option for that clinical entity [1].

Although VATS is performed through small incisions, postoperative pain remains challenging, as some patients report sharp chest pain with deep inspiration, while others report constant pain in the dorsal region. This might necessitate prescribing opioid analgesia for proper pain relief [2].

Postoperative pain not only increases patients' anxiety but also decreases postoperative satisfaction and hinders early rehabilitation, so effectively preventive post-operative pain is important [3]. Different techniques have been described, including paravertebral block, thoracic epidural analgesia, intercostal nerve block, and local wound infiltration [4, 5].

Disadvantages of the previously mentioned techniques are infection, hematoma parasympathetic manifestations, paraspinal muscular pain, spinal anesthesia, and short duration of analgesia [6, 7].

Recently, rhomboid intercostal block (RIB) and serratus anterior plane block (SAPB) have been described to provide effective analgesia after thoracic procedures [8, 9]. RIB was described in 2016 as an alternative to thoracic epidural analgesia [10]. The local anesthetic agent is delivered into the plane between the rhomboid major and intercostal muscles. That provides good analgesia for the anterior and posterior hemithorax [11]. SAPB induces blocking of the lateral cutaneous intercostal nerves, and its efficacy has been proved after thoracotomy and mastectomy procedures. Local anesthesia is instilled, either superficial or deep, in relation to the serratus muscle [12, 13]. Therefore, we conducted this study to compare RIB and SAPB regarding pain control in patients undergoing thoracoscopic sympathectomy for palmar hyperhidrosis.

Patients and methods

This prospective randomized controlled parallel study was conducted over one year, starting from March 2022 to March 2023, at Mansoura university hospitals after the Institutional Research Board and ethical committee of our university (MFM-IRB) approval (R.21.09.1462) on 31/10/ 2021. The study was designed for 213 patients with severe palmar hyperhidrosis after explaining its benefits and potential risks. Patients were interviewed, and written informed consent was obtained. All methods were performed in accordance with the declaration of Helsinki. The study was registered in the Pan African Trial Registry (PACTR202203766891354) on 16/3/2022. The study was reported according to the Consolidated Standards for Reporting Trials (CONSORT) guidelines[14].

The sample size was calculated via the PASS software program (version 23.0.2.), considering the time to the first rescue analgesic as the main outcome. The null hypothesis was considered as the absence of difference between RIB and SAPB techniques regarding that parameter. No previous studies have compared these two specific block techniques before. A minimal patient sample of 64 patients was required in each group to achieve a power and significance level of 80% and 5%, respectively. With an expected seven patients to drop out, the included sample was increased to 71 in each group (a total number of 213 cases).

Patients aged between 15 to 40 years old, from either gender, scheduled for VATS, and classified as class I or II according to the American Society of Anesthesiologists (ASA) were included. Contrarily, we excluded patients whose ASA was more than II, patients with infection at the injection site, bleeding disorders, and psychiatric illnesses.

Randomization and blinding

A total of 213 patients were randomly assigned to three equal groups using a computer-generated table of random numbers: Group R included patients who received RIB, Group S included patients who received SAPB, and Group C included the remaining patients who received no block procedure. The group allocation was concealed in sequentially numbered, sealed, and opaque envelopes. This study was double-blinded, as patients, data collectors, and those assessing the outcomes (a trained nurse who was not involved in the study), were blinded to the allocation until the end of the trial.

Before the procedure, proper history-taking, clinical examination, and laboratory investigations were performed. All patients were also taught how to express their pain via the Visual analog scale (VAS), which ranges from 0 to 10, with the former for no pain and the latter for the worst pain ever[15].

Patient's data

At the operative theater, all patients were sedated by IV midazolam 2 mg, and standard monitoring was applied. General anesthesia was induced by IV propofol, atracurium, and fentanyl with doses of 2.5 mg/kg, 0.5 mg/kg, and 1 μg/kg, respectively. A single-lumen endotracheal tube was used. All patients were kept on pressure-controlled volume mode, with a 1:2 I/E ratio and 4 ml/kg tidal volume. The respiratory rate was adjusted to keep ETCO2 around 35 mmHg. Maintenance of anesthesia was done via a mixture of isoflurane and 50% air in oxygen, and atracurium (0.1 mg/kg) increments were administered when needed. The block procedures were performed before skin incision under aseptic conditions under ultrasound guidance. We used Philips Clear Vue 350, WA, USA) with a high-frequency linear transducer (6 – 12 MHz).

In Group R, RIB was done in the lateral position, with the operating side directed superiorly with the abduction of the ipsilateral arm. The linear ultrasound probe was positioned in the oblique sagittal plane medial to the medial scapular border, and the following structures were identified; rhomboid muscle, trapezius muscle, intercostal muscles, pleura, and lungs. Then, a 21-gauge sono-visible needle was inserted at the level of T 5–6 till reaching the plane between the rhomboid and intercostal muscles, where 20 ml of bupivacaine 0.25% was injected. The spread of the local anesthetic was noted by ultrasound, and the procedure was repeated for the opposite side after adjusting the patient's position (Fig. 1).

The rhomboid block technique: (A) Sonographic anatomy of the layers encountered during rhomboid block. (B) Directing the needle to the plane between intercostal and rhomboid muscles. (C) Spread of the local anesthetic injectate in the proper plane

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In Group S, SABP was performed in the lateral position. The probe was positioned in the sagittal plane over the thoracic region in the midaxillary line, where the seventh rib was identified along with the following muscles; serratus anterior, latissimus dorsi, and teres major. The sonovisible 18-gauge needle was advanced till reaching the plane superficial to the serratus muscle, where 20 ml of bupivacaine 0.25% was injected. The procedure was repeated for the opposite side (Fig. 2).

The serratus anterior block technique: (A) Sonographic anatomy of the layers encountered during serratus block. (B) Directing the needle to the plane between serratus and latissimus dorsi muscles. (C) Spread of the local anesthetic injectate in the proper plane

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No block procedure was done in Group C, as patients in this group received conventional IV analgesia. Heart rate (HR) and mean arterial pressure (MAP) were recorded basally, with skin incision, and then every 15 min till the procedure ended. At the end of the procedure all patients received acetaminophen with doses of 1 mg/kg.

Patients were transferred to the recovery room where VAS score was recorded immediately, 1, 3, 6, 12, and 24 h after the operation. Postoperative analgesia was achieved by IV ketorolac (30 mg/12 h) and IV acetaminophen (1 gm/8 h). IV fentanyl (1 μg/kg) was also commenced for breakthrough pain, and it was repeated after 4 h till the patient had a VAS of 3 or less. Time to the first rescue analgesia and total postoperative opioid consumption was also recorded. Patient satisfaction was graded by the same person(trained nurse) according to a five-point Likert scale; weak, medium, good, very good, and excellent [16].

Collected data

The primary outcome was the time to the first rescue analgesic, whereas secondary ones included intraoperative hemodynamic changes, pain scores, postoperative opioid consumption, the incidence of complications, and patient satisfaction.

Statistical analysis

Statistical analysis was performed by the SPSS (version 21.0; SPSS Inc, Chicago, Ill, United States) software program. Numerical data were expressed as mean and standard deviation and compared between the three groups using the one-way ANOVA test. The categorical ones were expressed as numbers and percentages and compared between the three groups using the Chi-square test or Fisher's exact test. Post-hoc analysis (Tukey pairwise comparison) was also performed to compare each individual two groups. P-values less than 0.05 were considered significant. P was used to express the comparison between the three groups. P1, P2, and P3 were used to compare Groups R and S, Groups R and C, and Groups S and C, respectively, as shown in the following tables in the results section.

The current study assessed 230 patients for eligibility; 17 patients were excluded. Subsequently, 213 patients assigned for thoracoscopic sympathectomy were randomized to receive RIB (Group R), SAPB (Group S), and Group C included the remaining patients who received no block procedure. No cases were lost to follow up. Thus, the data of 213 patients were analyzed (Fig. 3).

CONSORT Flow Chart

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The age of the included patients had mean values of 23.17, 24.38, and 23.69 years, whereas their weight had mean values of 79.37, 80.66, and 78.34 kg in Groups R, S, and C, respectively. Most cases in the three groups were ASA I classification with percentages of 66%, 63%, and 65% of cases, respectively, whereas the remaining cases had class II. The duration of the procedure had an average of 47.68, 50.14, and 48.89 min in the same three groups, respectively. There was no significant difference regarding age, body weight, physical status, and duration of the surgery among the three studied groups (Table 1).

Both HR and MAP showed no significant difference between the three study groups at the baseline and with the skin incision. Nonetheless, the two block groups expressed significantly lower readings after 15 min till the end of the procedure compared to Group C. This decline in both vital parameters was more evident in Group R compared to Group S (Fig. 4) (Fig. 5).

Heart rate changes in the study groups: R groupRhomboid intercostal block group, S group Serratus anterior plane block group, C group Control group

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MAP changes in the study groups: R groupRhomboid intercostal block group, S group Serratus anterior plane block group, C group Control group

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VAS score was significantly lower in both R and S groups compared to Group C starting from PACU admission till 24 h postoperatively. VAS score was superior in Group R compared to Group S in most of the recorded readings, apart from the PACU and 24-h readings, that were comparable between the two blocks (Table 2).

The time to the first rescue analgesic showed a significant decline in Group C (40.07 min) compared to the other two groups (730.7 min and 562.39 min in Groups R and S, respectively). Additionally, Group C showed a significant increase in fentanyl consumption (107.99 µg) compared to the other two block groups (47.11 and 66.55 µg in Groups R and S, respectively). Group R showed significantly better outcomes compared to Group S regarding both the first analgesic request and fentanyl consumption. Patient satisfaction showed no significant difference between R and S groups, and it was significantly better than group C (Table 3). No block-related complication was encountered in the three studied groups.

The current study demonstrates that both RIB and SAPB were effective techniques in providing analgesia for patients undergoing VATS. RIB and SAPB were performed before the skin incision, "preemptive analgesia," to induce better analgesia compared to blocks performed after surgery owing to its protective effect on the human nociceptive system [17].

Both block techniques were effective in pain control after the procedure, and the analgesic profile was much better in RIB (rejecting our null hypothesis). That could be explained by the extent of the block in both techniques. RIB covers the entire hemithorax anteriorly and posteriorly, while SAPB covers the anterolateral chest wall region as it mainly affects the lateral intercostal nerve branches and omits the posterior main sensory branch [11, 18].

Our finding correlate with those of Zhang et al., who conducted a prospective trial comparing RIB, SAPB, and erector spinae plane block (ESPB) in patients undergoing VATS. Postoperative pain scores, the time to first analgesic request, and opioid consumption were comparable between RIB and ESPB and more superior to SAPB [19].

Similar results have been reported in a retrospective study compared RIB to SAPB in VATS procedures and found that pain scores were significantly reduced with RIB. Nonetheless, opioid consumption was statistically comparable between the two block techniques (122 mg vs. 151 mg in Groups R and S, respectively – p > 0.05) [20].

RIB was initially described by Elsharkawy and his associates. The local anesthetic agent is administered into the fascial plane between the rhomboid and intercostal muscles, providing analgesia for the region supplied by T 2–9 dermatomes in both anterior and posterior chest walls by targeting the lateral cutaneous branches of the ventral thoracic nerves. The spread of the local anesthetic in both craniocaudal and anteroposterior directions could explain its wide coverage, even when the injectate is administered into a single level [11, 21].

SAPB was first described by Blanco and his associates for pain management after chest and breast operations [18]. Serratus muscle is superficial, easily identified, and considered a landmark for thoracic wall blocks as intercostal nerves pierce it. The block procedure provided sufficient analgesia extending from T2 to T9 dermatomes [22, 23].

As regard RIB, our finding was in agreement with Deng et al., who evaluated RIB for elective unilateral VATS. The total amount of sufentanil in 24 h after the surgery in the RIB group was less than those in the control group at (p < 0.001). Time to first analgesic request in group RIB was significantly prolonged in the RIB group than those in the control group (p < 0.001) [24].

Similar results have been reported by Altıparmak et al., who demonstrated that RIB was associated with a significant improvement in patient recovery (recovery score 164.8 vs. 153.5 in controls – p < 0.001) and Postoperative morphine consumption (5 vs. 10 mg in controls – p < 0.001) [25].

As regard SAPB, our findings correlate with those of Park et al., who evaluated SAPB on postoperative pain and opioid consumption after thoracoscopic surgery. SAPB reduced the worst median (IQR [range]) pain score 6 (5–7 [3,4,5,6,7,8,9,10]) vs. 7 (6–7 [3,4,5,6,7,8,9,10]), p = 0.027. Also, fentanyl consumption was significantly reduced in the block group for the first 24 h after thoracoscopic surgery (3.8 vs. 5.7 μg/kg in controls) [26].

Moreover, Chen and his associates evaluated the effects of SAPB on postoperative pain after thoracoscopic surgery compared with local anesthetic (LA) infiltration. Postoperative sufentanil consumption in the SAPB group was significantly lower compared with the LA group (P < 0.01). The amount of rescue analgesia also decreased significantly in the SAPB group (P = 0.02) during 0–12 h [27].

There are limitations of our study as the patients were collected from a single medical center, both block techniques were performed as a single shot, and its effect on chronic postoperative pain was not evaluated. That is why we recommend performing more studies with a larger patient sample.

Both RIB and SAPB are safe and effective in pain management after VATS procedures for hyperhidrosis. However, RIB is superior to SAPB as it is associated with better analgesic outcomes.

The individual participant data will be available upon reasonable request with the corresponding author after the local IRB approval.

We acknowledge the Egyptian K knowledge Bank- Enago for providing proof reading of the article. http://www.enago.com

Open access funding provided by The Science, Technology & Innovation Funding Authority (STDF) in cooperation with The Egyptian Knowledge Bank (EKB). We did not receive any specific funds. We only used institutional resources.

Authors and Affiliations

1. Faculty of Medicine, Mansoura University, Mansoura, Egypt

   Mohamed G. Elhouty, Khaled Elbahrawy & Mostafa S. Elawady

Contributions

M.G.E., principal investigator, formulated the research, study design, data acquisition, and interpretation and drafted the manuscript. K.M.E., M.S.E., helped in the study design and revising of the final manuscript. All authors approved the final manuscript.

Corresponding author

Correspondence to Mohamed G. Elhouty.

Ethical approval and consent to participate

All methods were performed in accordance with the declaration of Helsinki. We obtained Mansoura Faculty of Medicine, Institutional Research Board (MFM-IRB) approval (R.21.09.1462) before patient enrollment. All patients gave their written informed consent (or their guardians if their age was less than 18 years) during the preoperative visits.

Consent for publication

Not applicable.

Competing interests

Nil.

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