Laparoscopic surgery is a minimally invasive surgery that is widely used in gynecological patients and has the advantages of less damage and faster recovery, and its proportion in the field of gynecology has increased significantly.1 The establishment of pneumoperitoneum by injecting carbon dioxide (CO2) into the abdominal cavity is usually performed in laparoscopic surgery, which can cause a strong stress response resulting in large hemodynamic fluctuations.2 During CO2 pneumoperitoneum, the effect of CO2 activation of the sympathetic adrenergic system seems to dominate.3 However, the changes in the sympathetic stress response caused by laparoscopic surgical stimulation are the result of the simultaneous action of excision stimulation and carbon dioxide pneumoperitoneum stimulation. General anesthesia alone has difficulty inhibiting this stress response; too much depth of anesthesia can also lead to hemodynamic instability.4 General anesthesia combined with epidural or nerve block anesthesia may be effectively relieved.3,5,6
The minimum alveolar concentration (MAC) of inhaled anesthetic for blocking adrenergic response (BAR) in 50% of patients is defined as the MACBAR of inhalation anesthetic.7 Many pharmacological factors such as non-steroidal anti-inflammatory drugs,8 analgesics,9 anesthetics,10 and physiological factors such as hypercapnia were associated with changes in MACBAR of inhaled anesthetics.11 However, few studies have focused on the influence of nerve blocking factors on the MACBAR.
Transverse abdominis plane(TAP)block can block the abdominal wall afferent nerve by injecting local anesthetic into the neural plane between the internal oblique and transverse abdominal muscles and provides directive analgesia between the costal margin and the inguinal ligament.12 Several studies have shown that TAP block can reduce the visual analog scale (VAS) pain score and analgesic needs of abdominal surgery, in addition to having the advantages of good patient compliance and overall comfort.13,14 Moreover, it does not have complications of intraspinal anesthesia such as hypotension, bradycardia, urinary retention, postoperative headache, and motor block.15,16 Multiple studies have shown that TAP block is beneficial for pain management in laparoscopic surgery,17,18 but there are conflicting data that TAP block does not increase any analgesic effect in gynecological laparoscopic surgery.19 Therefore, the application of TAP block in gynecological laparoscopic surgery remains controversial.
Whether the TAP block affects MACBAR of sevoflurane during laparoscopic surgery is unknown. We hypothesized that bilateral TAP block can effectively reduce MACBAR of sevoflurane in gynecological patients undergoing laparoscopic surgery with pneumoperitoneal stimulation. Observing the effect of bilateral TAP block on sevoflurane MACBAR may help anesthesiologists carefully titrate sevoflurane concentration and analgesic dose during combined TAP block anesthesia.
Methods Study Design and EthicsThis single-center, randomized clinical controlled trial was approved by the Ethics Committee of the Affiliated Hospital of North Sichuan Medical University (approval number: 2021ER080-1, on July 8, 2021) and was registered at https://www.chictr.org.cn (ChiCTR2100046517, principal investigator: P.P.J., date of registration: May 18, 2021) before patient enrollment. This study was conducted in accordance with the Declaration of Helsinki and applicable CONSORT guidelines. Written informed consent was obtained from all participants and an approved protocol was followed throughout the study period.
ParticipantsFifty women aged 18–65 years with an American Society of Anesthesiologists (ASA) Physical Status of I or II were selected for elective gynecological laparoscopic surgery in our hospital. The exclusion criteria were history of cardiac, pulmonary, liver, or renal disease; history of hypertension, diabetes, or stroke; drug or alcohol abuse; preoperative acid-base electrolyte imbalance; coagulation dysfunction; current use of any vasoactive medications; recent use of any medications known to affect MAC or sympathetic adrenergic response; pregnant women; body mass index (BMI)< 18 or >30 kg m−2; contraindication for inhalation anesthesia or local anesthetics; and inability to comply with the protocol for any reason.
RandomizationPatients were randomly allocated (1:1) into two groups (TAP block group and control group) using Statistical Product Service Solutions (SPSS, IBM) 23.0 software. The TAP block group received a bilateral transverse abdominis plane block (injection of 0.33% ropivacaine 20 mL on each side) 30 min before anesthesia guided by ultrasound. An equal volume of normal saline was administered in the transverse abdominal muscle plane to the control group. The TAP block technique in both groups was performed by a specialized anesthesiologist who administered the medication according to a sterile envelope prepared by a nurse who prepared two 20 mL syringes containing 0.33% ropivacaine or saline in a sterile envelope according to the group number.
Anesthesia ProcessAll patients fasted for 8 hours, did not drink for 4 hours before surgery, and did not receive premedication. Electrocardiography (ECG), pulse oxygen saturation (SPO2), and left invasive radial arterial pressure (IAP) were routinely monitored using a multifunction monitor (Mindray Medical International Limited, BeeVisionN15). Oxygen was delivered at a rate of 2 L min−1 through the nasal prongs. The nurse opened the venous channel on one side of the patient’s upper limb and injected lactate Ringer’s solution at a rate of 15–20 mL kg−1 h−1. Remifentanil was injected simultaneously to reach a plasma target-controlled concentration of 2 ng mL−1.
The patient was placed in the supine position with an ultrasound high-frequency line probe placed at the midaxillary line, iliac crest, or costal margins. The operator gently slid the ultrasonic probe back and forth to the proximal or distal end of the patient. When the abdominal wall muscle structure on the ultrasonic display was clear, a 22-gauge, 8-cm short-beveled needle was inserted from the middle to the lateral using an in-plane technique until the needle tip was demonstrated in the plane between the transverse abdominis and the internal oblique muscle. When the negative pressure test showed no blood, 1–2 mL of local anesthetic was slowly injected to confirm the position of the needle tip, and then 20 mL of 0.33% ropivacaine or normal saline was injected with an intermittent negative aspiration test. The contralateral TAP block was performed in the same manner. Remifentanil injection was discontinued after completion of the transversal plane block, and the patients were transferred to the operating room 30 minutes later. The skin cold sensation test20 on the bilateral abdominal walls was performed 20 min after the block was completed by a specified anesthesiologist using an ice cube placed in a disposable plastic glove. Compared to patient’s cold sensation at the neck skin, if the cold sensation on two sides of the abdominal wall was reduced or absent, the TAP block was considered to be effective. The boundaries of sensory changes in the abdominal skin were marked on the skin. If the cold sensation persisted in the patient’s bilateral abdominal wall, the TAP block was considered a failure and was excluded from the study. The TAP-blocking process and labeling results are shown in Figure 1.
Figure 1 The TAP-blocking process and labeling results. (A) Ultrasound-guided TAP block. (B) The abdominal muscle structure was shown on ultrasound. (C) Area of hypoesthesia measured 20 min after TAP block. (D) TAP blocks the process of LA injection.
Abbreviations: TAP, transverse abdominis plane; LA, local anesthetic.
The bispectral index (BIS), ECG, SPO2 and IAP were routinely monitored in the operating room before induction. General anesthesia was induced by intravenous injection of propofol 2–3 mg kg−1 and remifentanil 1–2 μg kg−1. Cisatracurium besilate 0.15 mg kg−1 was injected to facilitate insertion of the tracheal tube. Mechanical ventilation was controlled using 85% oxygen at a flow rate of 2 L min−1. A preset concentration of sevoflurane was inhaled to maintain anesthesia, and end-expiratory carbon dioxide partial pressure (PETCO2) was maintained within the normal range (35–45 mmHg) by regulating respiratory parameters. PETCO2 and end-tidal sevoflurane concentrations (CETSevo) were measured using the above-mentioned multifunctional monitor. Carbon dioxide pneumoperitoneum was established at a pressure of 13 mmHg after reaching the preset target sevoflurane concentration and maintaining stability for 15 min. The establishment of CO2 pneumoperitoneum requires four laparoscopic ports (one for a periumbilical balloon trocar of 10 mm, two accessory ports of 5 mm inserted into the right and left lower quadrants, and one accessory port of 10 mm in the right or left lower quadrant as the main operating hole). The patient’s heart rate (HR) and mean arterial pressure (MAP) were recorded 1 and 3 minutes before and after the creation of CO2 pneumoperitoneum. When MACBAR measurement was completed, the depth of anesthesia was maintained by pumping remifentanil (4–6㎍ kg−1 h−1) and inhaled sevoflurane (1–3%). The infusion of remifentanil was stopped and sufentanil 0.2㎍ kg−1 was intravenously injected at the end of surgery. When the patient’s consciousness and spontaneous breathing had recovered, the tracheal tube was removed and the patient was sent to the anesthesia recovery room for further observation.
The visual analogue scale (VAS) pain score was determined by an appointed anesthesia nurse based on the standard from 0 (no pain at all) to 10 (worst imaginable pain) at 30 min, 2 h, 4h, 6 h, 12 h, 24 h and 48h after the operation. In the anesthesia recovery room, 0.1 mg kg−1 of oxycodone was administered intravenously when the VAS score was ≥4. Postoperative nausea and vomiting (PONV) were assessed at two post-operative intervals: 0–2h and 2–24h, and the incidence of nausea and vomiting and the use of emergency antiemetic (4mg ondansetron per dose) were recorded. After the patient was admitted to the ward, tramadol was administered orally at 100 mg day−1 for postoperative analgesia and demerol 50 mg for remedial analgesia was administered intravenously if severe pain persisted. Postoperative analgesic drug requirements and local anesthetic toxicity (nerve block, tongue numbness, convulsion, apnea, arrhythmia, and other symptoms) were recorded. Patients were followed up after surgery for complications, such as abdominal wall hematoma, intestinal perforation, and intraoperative awareness.
Determination of MACBARThe MACBAR of sevoflurane was determined using the Dixon up-and-down sequential allocation technique.21 The mean values of HR or MAP at 1 and 3 min before pneumoperitoneum establishment were taken as the baseline values. The mean values of HR or MAP at 1 and 3 min after pneumoperitoneum pressure stabilization were taken as the change in values. A sympathetic adrenergic positive response was defined as an increase in HR or MAP greater than or equal to 20% of its baseline value after pneumoperitoneum establishment. In contrast, if the increase in HR or MAP was less than 20% of the baseline value, the sympathetic adrenergic response was defined as negative. A designated observer, who was blinded to the study design, completed the judgment of sympathetic adrenergic positive or negative responses. The first patient’s predetermined CETSevo in the control group (4.8%) and TAP block group (4.4%) was obtained by a pilot test. If the response after pneumoperitoneum stimulation was positive (negative), the CETSevo score in the next patient increased (decreased) by 0.2%. Patients with HR <50 bpm or MAP <50 mmHg who required treatment with vasoactive drugs such as atropine or ephedrine during the study period were excluded from the study, and CETSevo was repeated in the next patient to continue the sequential test. Positive responses to negative responses or negative responses to positive responses were used as intersection points for successive patients. The determination was continued until six intersection points from positive to negative and negative to positive occurred in each group,22 and the intervention ceased when the target sample size was reached.
OutcomesThe primary objective of this study was to evaluate the effect of TAP block on the MACBAR of sevoflurane during pneumoperitoneum stimulation. The MACBAR value for sevoflurane was obtained using the sequential allocation technique described above. The mean CETSevo in 12 patients with 6 intersection points was the MACBAR value of sevoflurane in each group.
The secondary observation indexes of this study included HR, MAP, and BIS before and after pneumoperitoneum establishment; VAS pain score at 30 min, 2 h, 4 h, 6 h, 12 h, 24 h and 48h after surgery; intraoperative analgesic drug dosage; analgesic demand within 48 h after surgery; PONV and the use of antiemetics and related complications.
Sample Size CalculationUsing PASS 2021 software to calculate the sample size based on the pre-experimental results, we assumed that the MACBAR of sevoflurane in the control and TAP block groups was 4.8% and 4.4%, respectively. The standard deviation was set to 0.5%. Thus, to achieve a power of 80% and a type I error of 0.05 to detect a difference of 0.4% with a possible dropout rate of 20%, 25 patients per group were required.
Statistical AnalysisSPSS software (version 23.0) was used for statistical analysis. The statistical data of HR, MAP, and BIS were derived from 12 patients, with six intersections of positive responses to negative responses in each group. Differences (delta values) in HR, MAP, and BIS before and after pneumoperitoneum stimulation were calculated. Data are expressed as mean ± SD for numerical variables and as numbers for categorical variables.
The MACBAR of sevoflurane; age; BMI; operative time; consumption of sufentanil, remifentanil, oxycodone, and dolantin; and HR, MAP, BIS, and VAS pain scores were compared between the two groups using an independent sample T test. Probit regression was used to estimate MACBAR with 95% confidence interval (CI). ASA classification, type of surgery, PONV and the use of antiemetics were compared between the two groups using the chi-squared test. p < 0.05 was considered statistically significant based on a two-tailed probability.
ResultsA consort diagram of this study is shown in Figure 2. In the anticipant 50 patients, 2 patients in the control group did not receive the allocated intervention owing to the six intersection points were obtained, and 2 patients in the TAP block group did not receive the further intervention owing to the TAP block failed. In the control and TAP block groups, 3 cases and 2 cases with MAP <50 mmHg or HR<50 bpm were excluded from the test. Finally, to obtain six intersections, 20 and 21 cases were used for the control and TAP block groups, respectively (Figure 3).
Figure 2 Consort diagram for the trail. In this study, 50 patients were randomly allocated into 2 groups with 25 patients in each group. To obtain six intersection points in each group, 20 and 21 patients in the control group and TAP group were needed respectively. Finally, remaining 2 patients did not undergo the experimental intervention because a sufficient number of intersections were obtained.
Figure 3 The measurement of sevoflurane MACBAR in the two groups. The positive reaction was represented by ○,while the negative reaction was represented by ●. The intersections from positive to negative reactions are represented by ▲, and the intersections from negative to positive reactions are represented by ■.To get six crossovers, 20 and 21 patients were needed in the control group and TAP block group, respectively.
Abbreviation: TAP, transverse abdominis plane.
The demographic and clinical characteristics of patients are shown in Table 1. The intraoperative doses of remifentanil, oxycodone, and dolantin in the TAP block group were significantly lower than those in the control group (p < 0.05).
Table 1 The Demographic and Clinical Characteristics of Patients in Two Groups
MACBAR of sevoflurane is shown in Table 2. The MACBAR of sevoflurane at six consecutive intersections from positive to negative in both groups was (5.03%[95% CI, 4.89% ~ 5.18%] vs 4.20%[95% CI, 4.02%~4.38%]; difference, 0.83% [95% CI, 0.62% to 1.05%], p < 0.001), the MACBAR of sevoflurane at six consecutive intersections from negative to positive was (4.90%[95% CI, 4.77%~5.03%] vs 4.10%[95% CI, 3.97% ~ 4.23%]; difference, 0.82% [95% CI, 0.63% to 0.97%], p < 0.001); similar MACBAR of sevoflurane results was obtained by using probit regression in the control group and TAP group (4.91%[95% CI, 4.61%~5.07%] vs 4.14%[95% CI, 3.79%~4.37%], p < 0.001).
Table 2 The MACBAR of Sevoflurane Were Compared Between the Two Groups by Means of Independent Sample and Probit Regression
Comparisons of the HR, MAP, and BIS between the control and TAP block groups are shown in Table 3. The HR before and after pneumoperitoneum in the TAP block group was significantly lower than that in the control group (p < 0.05). MAP before and after pneumoperitoneum, delta values of HR and MAP, and BIS were not significantly different between the two groups (p> 0.05).
Table 3 Comparison of the HR, MAP, BIS Between Two Groups
A comparison of the postoperative VAS pain scores between the two groups is shown in Figure 4. The postoperative VAS scores between the two groups showed significant differences at 30 min and 2 h after surgery (p < 0.001), but no significant differences were found at 4, 6, 12, 24, and 48 h after surgery (p> 0.05).
Figure 4 Comparison of VAS scores between the two groups. There were significant differences in VAS scores between the two groups within 2 hours after surgery (p <0.001), but no differences at 4, 6, 12, 24 and 48 hours after surgery (p > 0.05).
Abbreviations: VAS, visual analogue scale; TAP, transverse abdominis plane.
PONV and the use of antiemetics are shown in Table 4. The incidence of PONV and the use rate of antiemetic drugs at 0–2 hours and 2–24 hours after surgery showed no statistical difference between the control group and TAP block group (p> 0.05).
Table 4 Postoperative Nausea and Vomiting outcomes
Abdominal wall hematoma and local anesthetic intoxication were not found in any patient, and no intraoperative awareness was found during postoperative follow-up.
DiscussionThe establishment of CO2 pneumoperitoneum by laparoscopic surgery can cause a stress response in patients, produce a large amount of endogenous substances such as catecholamine hormones that participate in perioperative myocardial ischemia,3 and lead to a series of adverse effects such as organ function suppression, immune function decline, and metabolic enhancement.6,23 This study showed that bilateral TAP block significantly reduced the MACBAR of sevoflurane in gynecological patients with laparoscopic pneumoperitoneal stimulation. This indicates that sevoflurane combined with bilateral TAP block can effectively inhibit the sympathetic stress response, mainly because the TAP block can effectively block neuromuscular excitatory transmission in the abdominal wall and lead to the suspension of surgical noxious stimulation in the central nervous system.24 TAP block causes the abdominal skin and peritoneal parietal sensory nerve to be blocked at T6-L1 level and provides effective pain control.15Carney et al25 even reported that TAP block not only blocked distal sensory efference, but also might affect the more proximal paravertebral space. Therefore, in this study, bilateral TAP block before surgery not only reduced the stimulation of skin incision, but also reduced the stimulation of CO2 pneumoperitoneum to the parietal peritoneum, which would greatly reduce the sympathetic stress response caused by laparoscopic pneumoperitoneum stimulation, thus reducing the MACBAR of sevoflurane.
In this study, MACBAR of sevoflurane was determined using a sequential up-down method. In contrast to previous studies,21,26,27 the average end-expiratory concentration of sevoflurane was the MACBAR value not only for 12 patients with six consecutive intersections from positive to negative, but also for 12 patients with six consecutive intersections from negative to positive. Both results are similar to those obtained by the probit regression used in this study (Table 2). This demonstrates the accuracy of our research and practicability of our method.
In this study, we found that preoperative bilateral TAP block reduced the MACBAR of sevoflurane by approximately 16% (Table 2). However, in our earlier studies, we discovered that a plasma target-controlled remifentanil concentration of 1 ng mL−1 could reduce the MACBAR of sevoflurane during pneumoperitoneum stimulation by 48% and 36% in adults21 and children,27 respectively. Therefore, we assumed that intravenous opioids are more effective in depressing the stress response than bilateral TAP block by pneumoperitoneum stimulation, possibly because CO2 activates the central nervous system to induce sympathetic adrenaline activation, and the TAP block lacks visceral analgesia,3,25 but it needs further study to confirm this.
In this study, no statistically significant differences were found in the changes in BIS, HR, and MAP between the two groups before and after pneumoperitoneum stimulation (Table 3). This might imply that when the adrenergic response was inhibited in half of patients, the hemodynamic changes and the depth of anesthesia measured by BIS were not related to whether the abdominal wall was blocked by local anesthesia. The reason for a faster heart rate in the control group than that in the TAP block group before and after pneumoperitoneum establishment may be related to the use of a high concentration of sevoflurane as described by Goo’s study.28
The MACBAR of the TAP block group was significantly lower than that of the control group, indicating that the TAP block before surgery required a lower CETSevo to achieve a similar MACBAR effect with CO2 pneumoperitoneum stimulation compared to the control group (Table 2). We found that the consumption of intraoperative and postoperative analgesic drug in the TAP block group was significantly lower than that in the control group (Table 1), demonstrating that bilateral TAP block before surgery can effectively reduce the use of perioperative analgesic drug dosage and consumption of sevoflurane, thereby reducing the incidence of postoperative hyperalgesia,29 delayed awakening, and other related complications,30 which is consistent with the findings of.31 However, the results of this study found that there was no difference in PONV and the use of antiemetic drugs between the control group and the TAP block group. Therefore, the influence of TAP block on PONV in gynecological laparoscopic surgery needs to be further studied in additional cases.
By observing the effect of preoperative TAP block on the postoperative VAS pain score, we found that the VAS pain score in the TAP block group was significantly lower than that in the control group within 2 h after surgery (Figure 4). However, there were no significant differences in the VAS pain scores between the two groups at 4, 6, 12, 24, and 48 h after surgery, which may be related to the timely use of oxycodone and demerol for remedial analgesia, and the dose of ropivacaine for TAP block was small. Azawi’s32 article noted that the half-life of ropivacaine is approximately two hours and that postoperative TAP-block administration may be the optimal choice if prolonged analgesia is required. In addition, it has been confirmed that increasing the concentration of local anesthetics can also prolong the block time.33
In this study, the ultrasound-guided TAP block had the imaging advantages of real-time needle trajectory and local anesthetic diffusion. It can effectively avoid abdominal wall hematoma, intestinal perforation, and local anesthetic intoxication.
This study has several limitations. First, changes in plasma catecholamine concentrations and inflammatory cytokines in the two groups were not monitored simultaneously; however, our previous studies have shown that catecholamine hormone changes in the body are consistent when half of the adrenergic response is suppressed during laparoscopic surgical stimulation. Second, since we measured MACBAR of sevoflurane using the up-and-down sequential allocation method and the properties of abdominal wall skin anesthesia in the TAP group, double blindness was not used in this study. Third, the HR and MAP data only analyzed 12 patients with six intersections of positive to negative responses in each group; other patient data were not analyzed.
ConclusionBilateral TAP block guided by preoperative ultrasound can significantly reduce the MACBAR of sevoflurane and the need for intraoperative and postoperative analgesics during laparoscopic surgical stimulation in gynecological patients.
Data Sharing StatementAll data generated or analyzed during this study have been included in the published article. Further inquiries regarding the datasets can be directed to the corresponding author upon reasonable request.
AcknowledgmentsThe authors thank all the nurses, anesthesiologists, and surgeons who participated in this study at the Affiliated Hospital of North Sichuan Medical College.
FundingThis study was supported by no. CBY21-QA47 from the program of the North Sichuan Medical College of Nanchong City, Sichuan, China.
DisclosureThe authors have no competing interests in this work.
References1. Molina-Gil J, Fernández-Díaz Á, Caminal-Montero L. Complex regional pain syndrome following laparoscopic gynecological surgery. Síndrome de dolor regional complejo tras cirugía ginecológica por laparoscopia. Med Clin. 2020;154(11):469–470. doi:10.1016/j.medcli.2019.04.010
2. Sun C, Yang Q, Wang C, Zhao J, Dai M. Efficacy of Different Preemptive Analgesia on Postoperative Analgesia, Oxidative Stress, and Inflammatory Response after Gynecological Laparoscopic Surgery [retracted in: evid Based Complement Alternat Med. 2023 Jun 21;2023:9872470]. Evid Based Complement Alternat Med. 2021;2021:4233716. doi:10.1155/2021/4233716
3. Han C, Ding Z, Fan J, Sun J, Qian Y. Comparison of the stress response in patients undergoing gynecological laparoscopic surgery using carbon dioxide pneumoperitoneum or abdominal wall-lifting methods. J. Laparoendosc Adv Surg Tech A. 2012;22(4):330–335. doi:10.1089/lap.2011.0412
4. Zhen SQ, Jin M, Chen YX, Li JH, Wang H, Chen HX. Ultrasound-guided paravertebral nerve block anesthesia on the stress response and hemodynamics among lung cancer patients. World. J Clin Cases. 2022;10(7):2174–2183. doi:10.12998/wjcc.v10.i7.2174
5. Lin X, Cai Y, Chen X, et al. Analgesia and stress attenuation of ultrasound-guided modified pectoral nerve block type-II with different volumes of 0.3% ropivacaine in patients undergoing modified radical mastectomy for breast cancer: a prospective parallel randomized double-blind controlled clinical trial. J Clin Pharm Ther. 2022;47(10):1676–1683. doi:10.1111/jcpt.13720
6. Zhan Y, Chen G, Huang J, Hou B, Liu W, Chen S. Effect of intercostal nerve block combined with general anesthesia on the stress response in patients undergoing minimally invasive mitral valve surgery. Exp Ther Med. 2017;14(4):3259–3264. doi:10.3892/etm.2017.4868
7. Roizen MF, Horrigan RW, Frazer BM. Anesthetic doses blocking adrenergic (stress) and cardiovascular responses to incision--MAC BAR. Anesthesiology. 1981;54(5):390–398. doi:10.1097/00000542-198105000-00008
8. Fukui S, Ooyama N, Tamura J, et al. Interaction between maropitant and carprofen on sparing of the minimum alveolar concentration for blunting adrenergic response (MAC-BAR) of sevoflurane in dogs. J. Vet Med Sci. 2017;79(3):502–508. doi:10.1292/jvms.15-0666
9. Albertin A, Casati A, Bergonzi P, Fano G, Torri G. Effects of two target-controlled concentrations (1 and 3 ng/mL) of remifentanil on MAC(BAR) of sevoflurane. Anesthesiology. 2004;100(2):255–259. doi:10.1097/00000542-200402000-00012
10. Love L, Egger C, Rohrbach B, Cox S, Hobbs M, Doherty T. The effect of ketamine on the MACBAR of sevoflurane in dogs. Vet Anaesth Analg. 2011;38(4):292–300. doi:10.1111/j.1467-2995.2011.00616.x
11. Wu Z, Yu J, Zhang T, et al. Effects of Etco2 on the Minimum Alveolar Concentration of Sevoflurane that Blunts the Adrenergic Response to Surgical Incision: a Prospective, Randomized, Double-Blinded Trial. Anesth Analg. 2022;135(1):62–70. DOI:10.1213/ANE.0000000000005784
12. Keir A, Rhodes L, Kayal A, Khan OA. Does a transversus abdominis plane (TAP) local anaesthetic block improve pain control in patients undergoing laparoscopic cholecystectomy? A best evidence topic. Int. J Surg. 2013;11(9):792–794. doi:10.1016/j.ijsu.2013.05.039
13. Petersen PL, Stjernholm P, Kristiansen VB, et al. The beneficial effect of transversus abdominis plane block after laparoscopic cholecystectomy in day-case surgery: a randomized clinical trial. Anesth Analg. 2012;115(3):527–533. doi:10.1213/ANE.0b013e318261f16e
14. Ra YS, Kim CH, Lee GY, Han JI. The analgesic effect of the ultrasound-guided transverse abdominis plane block after laparoscopic cholecystectomy. Korean. J Anesthesiol. 2010;58(4):362–368. doi:10.4097/kjae.2010.58.4.362
15. Demir HB, Atalay A, Uc C, Ö F, Ersin S. Tension-free inguinal hernia repair with transversus abdominis plane (TAP) block in elderly high-risk patients. ANZ. J Surg. 2022;92(10):2500–2504. doi:10.1111/ans.17866
16. Güner Can M, Göz R, Berber İ, Kaspar Ç, Çakır Ü. Ultrasound/Laparoscopic Camera-Guided Transversus Abdominis Plane Block for Renal Transplant Donors: a Randomized Controlled Trial. Ann Transplant. 2015;20:418–423. doi:10.12659/AOT.893926
17. Abdallah FW, Chan VW, Brull R. Transversus abdominis plane block: a systematic review. Reg Anesth Pain Med. 2012;37(2):193–209. doi:10.1097/AAP.0b013e3182429531
18. El-Dawlatly AA, Turkistani A, Kettner SC, et al. Ultrasound-guided transversus abdominis plane block: description of a new technique and comparison with conventional systemic analgesia during laparoscopic cholecystectomy [published correction appears in Br. J Anaesth. 2009;102(6):763–767. doi:10.1093/bja/aep067
19. Kane SM, Garcia-Tomas V, Alejandro-Rodriguez M, Astley B, Pollard RR. Randomized trial of transversus abdominis plane block at total laparoscopic hysterectomy: effect of regional analgesia on quality of recovery. Am J Obstet Gynecol. 2012;207(5):419.e1–419.e4195. doi:10.1016/j.ajog.2012.06.052
20. Albi-Feldzer A, Dureau S, Ghimouz A, et al. Preoperative Paravertebral Block and Chronic Pain after Breast Cancer Surgery: a Double-blind Randomized Trial. Anesthesiology. 2021;135(6):1091–1103. doi:10.1097/ALN.0000000000003989
21. Zou ZY, Zhao YL, Yang XL, Zhang GY, Zhou HG. Effects of different remifentanil target concentrations on MAC BAR of sevoflurane in gynaecological patients with CO2 pneumoperitoneum stimulus. Br. J Anaesth. 2015;114(4):634–639. doi:10.1093/bja/aeu400
22. Paul M, Fisher DM. Are estimates of MAC reliable? Anesthesiology. Anesthesiology. 2001;95(6):1362–1370. doi:10.1097/00000542-200112000-00014
23. Arfanis K, Fioratou E, Smith A. Safety culture in anaesthesiology: basic concepts and practical application. Best Pract Res Clin Anaesthesiol. 2011;25(2):229–238. doi:10.1016/j.bpa.2011.01.006
24. Murauski JD, Gonzalez KR. Peripheral Nerve Blocks for Postoperative Analgesia. AORN J. 2002;75(1):134,136,142–134,140,147. doi:10.1016/S0001-2092(06)61721-3
25. Carney J, Finnerty O, Rauf J, Bergin D, Laffey JG, Mc Donnell JG. Studies on the spread of local anaesthetic solution in transversus abdominis plane blocks. Anaesthesia. 2011;66(11):1023–1030. doi:10.1111/j.1365-2044.2011.06855.x
26. Jiang PP, Guo YX, Yang XL, Xu J, Wang D. Effects of different remifentanil target concentrations on MACBAR of sevoflurane in patients with liver dysfunction under carbon dioxide pneumoperitoneum stimulus: a randomized controlled trial. J Clin Pharm Ther. 2021;46(6):1776–1783. doi:10.1111/jcpt.13524
27. Wang D, Xu J, Yang XL, Guo YX, Jiang PP, Zhang GY. Effects of different plasma target concentrations of remifentanil on the MACBAR of sevoflurane in children with laparoscopic surgery. BMC Anesthesiol. 2021;21(1):231. doi:10.1186/s12871-021-01453-z
28. Goo EK, Lee JS, Koh JC. The optimal exhaled concentration of sevoflurane for intubation without neuromuscular blockade using clinical bolus doses of remifentanil: a randomized controlled trial. Medicine. 2017;96(9):e6235. doi:10.1097/MD.0000000000006235
29. Méleine M, Rivat C, Laboureyras E, Cahana A, Richebé P. Sciatic nerve block fails in preventing the development of late stress-induced hyperalgesia when high-dose fentanyl is administered perioperatively in rats. Reg Anesth Pain Med. 2012;37(4):448–454. doi:10.1097/AAP.0b013e318257a87a
30. Carney J, McDonnell JG, Ochana A, Bhinder R, Laffey JG. The transversus abdominis plane block provides effective postoperative analgesia in patients undergoing total abdominal hysterectomy. Anesth Analg. 2008;107(6):2056–2060. doi:10.1213/ane.0b013e3181871313
31. Nair P, Behera CR, Patra RK, et al. Efficacy and Cost-Effectiveness of Laparoscopic Transversus Abdominis Plane (TAP) Block in Laparoscopic Cholecystectomy: a Comparison With the Non-TAP Group. Cureus. 2022;14(11):e32038. doi:10.7759/cureus.32038
32. Azawi NH, Mosholt KS, Fode M. Unilateral Ultrasound-Guided Transversus Abdominis Plane Block After Nephrectomy; Postoperative Pain and Use of Opioids. Nephrourol Mon. 2016;8(2):e35356. doi:10.5812/numonthly.35356
33. Fredrickson MJ, Abeysekera A, White R. Randomized study of the effect of local anesthetic volume and concentration on the duration of peripheral nerve blockade. Reg Anesth Pain Med. 2012;37(5):495–501. doi:10.1097/AAP.0b013e3182580fd0
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