A novel technique of handling the blade for videolaryngoscopy intubation in patients with a semi-rigid neck collar: a prospective randomized controlled trial

Intubation in cervical immobilization

Article information

Korean J Anesthesiol. 2023;76(5):451-460

Publication date (electronic) : 2023 March 13

doi : https://doi.org/10.4097/kja.22733

Myoung Hwa Kim ¹

, Ji Young Kim ¹

, Jong Seok Lee ¹

, Arim Jo ¹

, Do-Hyeong Kim^,²

¹Department of Anesthesiology and Pain Medicine, Gangnam Severance Hospital, Anesthesia and Pain Research Institute, Yonsei University College of Medicine, Seoul, Korea

²Department of Anesthesiology and Pain Medicine, Yonsei University College of Medicine, Seoul, Korea

Corresponding author: Do-Hyeong Kim, M.D., Ph.D. Department of Anesthesiology and Pain Medicine, Yonsei University College of Medicine, 50-1 Yonsei-ro, Seodaemun-gu, Seoul 03722, Korea Tel: +82-2-2019-6080 Fax: +82-2-312-7185 Email: BREADFANS@yuhs.ac

Previous presentations in conference: An abstract was presented at the AACA 2022 in November 2022 at Coex in Seoul, Korea.

Received 2022 November 14; Revised 2023 January 26; Accepted 2023 February 22.

Abstract

Background

Semi-rigid neck collars to protect the cervical spine can limit the extent of neck movement and mouth opening; this may further complicate orotracheal intubation. We aimed to compare intubation environments obtained with videolaryngoscopy using the technique of gliding a blade under the epiglottis and that obtained using the conventional Macintosh blade technique of blade tip placement on the vallecula.

Methods

This prospective randomized study included patients aged ≥ 20 years with American Society of Anesthesiologists physical status I–III scheduled for cervical spine surgery between October 2020 and August 2021. Patients were divided into two groups according to the placement of the blade of the McGrath^TM videolaryngoscope: the gliding and conventional groups. The percentage of glottic opening (POGO) score was the primary endpoint. We also recorded the time to obtain the optimal laryngoscopic view, intubation duration, and ease and satisfaction of the researcher performing intubation.

Results

Among 176 patients, the POGO scores were significantly higher in the gliding group than in the conventional group (88.9 ± 14.7 vs. 63.8 ± 27.4, P < 0.001). The time to achieve the optimal glottic view for intubation and duration of intubation were also shorter, and ease and satisfaction in performing intubation were better in the gliding group than in the conventional group.

Conclusion

Our findings demonstrated a superior glottic view and more favorable intubation environments when the blade tip was placed under the epiglottis than using the conventional Macintosh technique in patients with immobilized cervical spine.

Keywords: Airway management; Cervical vertebrae; Glottis; Immobilization; Intratracheal intubation; Laryngoscopes

Introduction

The appropriate use of a laryngoscope demands the patient to be in a typical posture with their mouth open, chin raised, and neck tilted back. However, certain patients need restrictions in the movement of their cervical spine that may require the head to be in a neutral position [1]. Therefore, using a semi-rigid neck collar can maintain a neutral head and neck position, but this allows very little movement of the neck and limits sufficient mouth opening. Unfortunately, this can deteriorate the environment for tracheal intubation and may lead to hypoxia or tissue damage [2–4]. Although advances in videolaryngoscopes have made tracheal intubation easier for patients with restricted cervical spine movement, patients with semi-rigid neck collars still need more adequate and established intubation techniques.

In the conventional Macintosh blade technique for orotracheal intubation, a blade tip is placed on the vallecula and lifts the glottis. Another recommended technique of handling a blade is inserting the blade under the epiglottis in case of a damaged or protruding tooth or if the patient has a soft epiglottis [5–7]. A cadaver study investigated inserting a laryngoscope with manual in-line stabilization for cervical spine fixation. They found that a straight blade designed to directly lift the glottis, similar to placing the blade tip under the epiglottis, could improve the intubation environment more than a curved blade [8].

Videolaryngoscopes have lenses mounted at the end of the blade and the tip as well as fiberscopes. Partly resembling the technique used in the maneuver of the flexible fiberoptic bronchoscope, gliding a blade of the videolaryngoscope under the epiglottis to expose vocal cords can achieve a better glottic view. However, the best technique for handling the blade of videolaryngoscopes in patients with a semi-rigid neck collar has not yet been definitely established.

Therefore, we aimed to compare the overall intubation environment, including the glottic view, obtained with a videolaryngoscope using the technique of gliding a blade under the epiglottis and the conventional Macintosh blade technique of placing a blade tip on the vallecula in patients wearing a semi-rigid neck collar undergoing cervical spine surgery.

Materials and Methods

Participant enrolment and assignment

This prospective randomized parallel study was conducted at Gangnam Severance Hospital, Yonsei University Health System, Seoul, Republic of Korea, in accordance with the Declaration of Helsinki 2013. The study protocol was approved by the Institutional Review Board and Hospital Research Ethics Committee of Gangnam Severance Hospital, Yonsei University Health System (IRB No. 3-2020-0318) on September 1, 2020, and registered at ClinicalTrials.gov (NCT04578119) on October 19, 2020. Written informed consent was obtained from all the participants. Patients aged ≥ 20 years with an American Society of Anesthesiologists physical status I–III scheduled for elective cervical spine surgery in the neurosurgery department at our institution between October 2020 and August 2021 were assessed for eligibility. Patients requiring rapid sequence induction or planned awake intubation, those with symptomatic asthma or reactive airway disease requiring daily pharmacological treatment, and those with the inability or unwillingness to provide informed consent were excluded.

On the day of the surgery, the patients were randomly allocated to undergo orotracheal intubation either by placing the blade tip on the vallecula (conventional group) or by gliding it under the epiglottis (gliding group). The allocation was performed in a 1 : 1 ratio based on a computer-generated sequence using permuted block randomization with a block size of four. Copies of the random sequence were kept in sealed opaque envelopes that were opened by only two attending anesthesiologists immediately before anesthesia induction, following which intubation was performed in the assigned groups.

Preparation and anesthesia

A researcher, blinded to the group assignment, performed an airway assessment in the preoperative holding area. The Mallampati’s classification score, thyromental distance, inter-incisor distance (before and after semi-rigid neck collar placement), and neck circumference were measured. The condition of the teeth (no teeth, missing, mobile, or broken teeth, and partial or complete dentures), limited range of the cervical spine movement (extension, flexion, and instability), and inability to protrude the lower jaw (< 1 cm) were also checked. Subsequently, the Stifneck Select^® Collar (Laerdal Medical Corp., Norway)—a semi-rigid neck collar—was worn by all patients. Upon arrival at the operating room, electrocardiography, pulse oximetry, non-invasive blood pressure measurement, and bispectral index monitoring were performed. After the patients were preoxygenated with 100% oxygen for 3 min, remifentanil (0.2–0.4 μg/kg/min), propofol (1% 1.5–2.0 mg/kg), and rocuronium (0.8–1.0 mg/kg) (degree of muscle relaxation appropriate for tracheal intubation: train-of-four, 0/4) were administered to induce anesthesia.

Intubation technique

Orotracheal intubation was performed by two attending anesthesiologists with at least 10 years of experience and who had used the McGrath^TM videolaryngoscope (Medtronic, UK) 100 times or more. They had prior experience with the gliding technique using the McGrath^TM videolaryngoscope, each having managed at least 50 cases. Cuffed Mallinckrodt Hi-Contour Tracheal Tubes^TM (Covidien, USA; 7.0 mm for females, 8.0 mm for males) were used, and malleable stylets (Satin-Slip^®; Mallinckrodt Inc., USA) were mounted on the tubes. The stylets were prepared with the distal end angulated to a ‘hockey stick’ shape (Hockey-Stylet) that consisted of a 100° angle created 8 cm from the distal tip of the cuffed tracheal tube, as this was reported to be the best shape in a previous study [9]. We inserted a blade of McGrath^TM videolaryngoscope into the patient’s mouth in the midline, and the tip of the blade was then guided around the base of the tongue. After the blade approached the epiglottis, in the conventional group, the blade tip was placed on the vallecula and tilted to lift the epiglottis anteriorly, similar to the conventional Macintosh blade technique. In the gliding group, a blade was introduced from the epiglottis tip to the posterior wall of the epiglottis that partly resembled the maneuver of a flexible fiberoptic bronchoscope without aligning the axis by moving the blade anteriorly. As the vocal cords became visible, the blade was glided in a little more (Fig. 1).

Fig. 1.

Two techniques of intubation using the McGrath^TM videolaryngoscope. (A) We inserted a blade of the McGrath^TM videolaryngoscope into the patient’s mouth along the midline, and the tip of the blade was then guided around the base of the tongue. After the blade approached the epiglottis, (B) in the conventional group, the tip of the blade was placed on the vallecula, and the epiglottis was indirectly lifted to expose the glottis, similar to the typical Macintosh blade technique, (C) in the gliding group, the blade was glided, as in a fiberoptic bronchoscopy handling, and placed under the surface of the epiglottis directly exposing the glottis.

Outcomes assessment

The primary outcome was the percentage of glottic opening (POGO) score [10]; two independent investigators, who were not involved in the real intubation procedure, evaluated the POGO scores. An image of the glottic views was captured on the monitor display when an optimal view of the glottis was obtained, and intubation was conducted. Successful tracheal intubation was confirmed by auscultation of both sides of the chest and end-tidal carbon dioxide graphs on the ventilator monitor. More than two intubation attempts were considered failure of intervention in our study protocol; such cases were dropped out from the study. The time taken to obtain an optimal visual condition (optimal glottic view)—in other words, the time until the glottic view with the best POGO score was secured—was evaluated as that shown at the final (successful) attempt; the time taken to confirm successful tracheal intubation (duration of intubation) was recorded as the total time from the first attempt to the final successful intubation. Additional aid for making good processing of intubation that included manipulation of backward, upward, and rightward pressure (BURP) was also assessed. Moreover, an independent researcher asked the researcher who performed the intubation whether there was an upward lifting force of the hand while handling the blade and recorded the answer. The Intubation Difficulty Scale (IDS) [11] score was determined based on documented data. Following tracheal intubation, the Cormack–Lehane (CL) grade [12] and the ease and satisfaction in performing intubation were recorded on a scale of 1–5 (1, worst; 5, best), respectively by two attending anesthesiologists. Injury to the patients’ lips, mucosa, or teeth during the intubation process was checked, and the hemodynamic parameters were also monitored. Following extubation, all complications associated with intubation, including hypoxic events (reduction of oxygen saturation to < 90%), lip injury, mucosal bleeding, tooth damage, sore throat, difficulty in swallowing, and voice changes, were assessed in the post-anesthetic recovery room and the ward.

Statistical analysis

In a previous study [13], intubation with the McGrath^TM videolaryngoscope showed average POGO scores and standard deviations (SD) of 82 and 23, respectively. We assumed that the POGO score differs by an average of ≥ 10 points when using the gliding technique compared to the conventional Macintosh blade technique. Considering this, with a power of 80%, significance level of 5%, and drop-out rate of 5%, we calculated the sample size to be 178 participants (89 per group). The Kolmogorov–Smirnov test was used to determine the distributions of all continuous variables. Student’s t-test was performed for normally distributed data, while the Mann–Whitney U test was used for data that were not normally distributed. Chi-square or Fisher’s exact tests were used to analyze the frequency variables. The inter-rater reproducibility of the POGO measurements was also assessed in all datasets by calculating the intraclass correlation coefficient and coefficient of variation. All data were analyzed using IBM SPSS Statistics for Windows Version 25.0 software (IBM Corp., USA). Differences were considered significant at P < 0.05.

Results

Of the 199 patients assessed for eligibility, 21 were excluded. Therefore, 178 patients were randomized to either the conventional or gliding group; two dropped out, and 88 patients in each group were ultimately analyzed (Fig. 2). There were no differences in patient- and surgery-related characteristics, as well as pre-anesthesia airway assessments between the groups (Table 1).

Fig. 2.

Consolidated Standards of Reporting Trials (CONSORT) flow diagram.

Table 1.

Patient Characteristics and Preoperative Airway Assessments

Table 2 describes the comparison of the POGO scores. The average POGO scores were significantly higher in the gliding group compared with those in the conventional group (88.9 ± 14.7 vs. 63.8 ± 27.4, P < 0.001). The inter-rater reproducibility for estimating the POGO score was excellent, with an intraclass correlation coefficient of 0.93 (95% CI [0.90, 0.94]) and a coefficient of variation of 9.2% (within-subject SD 7.0%).

Table 2.

Intubation-Related Environment

Table 2 also presents parameters related to the intubation environments. The time to obtain an optimal view for intubation and the duration of intubation were significantly shorter in the gliding group than in the conventional group (19.0 [6.9] vs. 27.5 [15.6] s and 45.8 [8.2] vs. 55.8 [15.5] s, respectively; P < 0.001). The CL grade was significantly different between the groups (P < 0.001), and more patients required lifting force and BURP manipulation in the conventional group than in the gliding group (59 [67%] vs. 23 [26.1%] patients and 23 [26.1%] vs. 6 [6.8%] patients, respectively; P < 0.001). In addition, IDS scores were significantly different between the groups (P < 0.001), and both the ease and satisfaction of the anesthesiologists in terms of performing intubation were superior in the gliding group than in the conventional group (P < 0.001). Vital signs, such as blood pressure, heart rate, and peripheral saturation, were comparable between the groups at baseline and before and after intubation (Supplementary Table 1).

Table 3 shows the profile of intubation-related complications. These were not significantly different between the two groups, and all patients were discharged without residual complications.

Table 3.

Intubation-Related Complication Profiles

Discussion

In the present study, a superior laryngoscopic view and more favorable intubation environment were observed with the gliding blade technique than with the conventional Macintosh blade technique in patients undergoing cervical surgery where the cervical movement and mouth opening are restricted with a semi-rigid neck collar. The primary outcome was the laparoscopic glottic view measured using POGO scores when performing intubation with a McGrath^TM videolaryngoscope in patients undergoing cervical spine surgery with the need for cervical immobilization. Usually, the quality of the glottic view can be graded using the CL grading system; however, it has several problems, including grade ambiguity between grades 1 and 2 [12,14], and the CL description of the view is not quantitative. For this reason, alternate systems of description, such as the POGO scale [15], have been described that require the viewer to estimate a numerical score; these have the advantage of better inter-rater reliability [15,16]. The POGO score also appears superior to the CL scale in comparing devices—such as videolaryngoscopes—that always provide grade 1 on the CL scale [17]. The findings of our study regarding the POGO score, CL grade, and IDS score indicated that the gliding technique is better than the conventional Macintosh blade technique for intubation using a videolaryngoscope.

Cervical immobilization significantly deteriorates ideal intubation conditions in emergency rooms or operating theaters [1]. It may preclude adequate alignment of the oral, pharyngeal, and tracheal axes, thus jeopardizing the visualization of the glottis when using a direct laryngoscopy [3]. Additionally, wearing a neck collar has been associated with a decreased ability to open the mouth [3,4] that limits the direct view that can be captured with a laryngoscope and consequently reduces the success rate of tracheal intubation [18]. In such situations, intubation using a flexible fiberoptic bronchoscope is a reliable approach to acquire a high success rate of tracheal intubation and minimize cervical spine movement. However, the loss of pharyngeal muscle tone under general anesthesia narrows the oropharyngeal space necessary for the flexible fiberoptic bronchoscope to pass through and makes it difficult to maintain the flexible fiberoptic bronchoscope in the midline while advancing its tip into the pharynx and the laryngeal inlet [19–21]. Moreover, a well-trained and experienced anesthetist is required for flexible fiberoptic bronchoscope-guided intubation. Hence, several studies have attempted using videolaryngoscopes for intubation of patients requiring cervical immobilization [22–24].

Macintosh blade technique is generally used for intubation using a videolaryngoscope as well as a direct laryngoscope. However, since videolaryngoscopes use the indirect glottic view of the camera close to the glottis, it is considered more appropriate to have the blade glide gently under the epiglottis to expose the glottis [25]. As the camera lens of a videolaryngoscope is in the pharynx in any case, the alignment of the airway axes is not important for the maneuver of a flexible fiberoptic bronchoscope. It can easily enter the posterior aspect of the epiglottis; therefore, it is less affected by the anatomy of the larynx. Nevertheless, a good laryngeal view does not always translate to easy intubation [26,27]. In particular, proximal placement of a blade of the videolaryngoscope results in poor glottis visualization (higher CL grades and lower POGO scores). This may be pointed out as a noticeable weakness of using videolaryngoscopy. Therefore, the clinical significance of our results is inevitably substantial because the technique of gliding a blade under the epiglottis similar to that used during the maneuver of a flexible fiberoptic bronchoscope provided an optimal glottic view and increased ease of orotracheal intubation.

Failure to perform adequate immobilization of the cervical spine during orotracheal intubation in patients with cervical spine instability or at risk of spinal cord injury can potentially lead to devastating neurological outcomes. A recent case report described a patient with ankylosing spondylitis who experienced substantial cervical spine injury following videolaryngoscopy intubation [28]. International guidelines recommend manual or mechanical cervical immobilization for trauma patients who require tracheal intubation because of the possibility of radiological or clinical cervical cord injury [29]. Although both manual in-line stabilization and cervical collar are preferred techniques to maintain cervical spine immobility during tracheal intubation, the latter has been shown to limit cervical spine displacements more during orotracheal intubation [8,30]. Accordingly, several studies have simulated difficult intubation by applying a cervical collar to a mannequin; only a few studies have conducted the same investigation in a real clinical field [31–35]. We applied a semi-rigid neck collar to patients who actually needed cervical immobilization during intubation for safety and did not intentionally simulate a difficult airway situation.

There were a few limitations in our study. First, we could not blind the intubating anesthetists to the randomization of the videolaryngoscope. However, the POGO scores were obtained by two independent (blinded) investigators who were not involved in intubation, and the other data were also well defined and objective. Moreover, inter-rater producibility between the two investigators who assessed the POGO scores was reliable. Second, this study was conducted by an experienced anesthetist, and the results may vary when applied in other clinical situations. Moreover, the gliding intubation technique presented in our study may have potential risks that have not yet been fully proven; hence, caution is necessary when applying it in clinical practice. However, the McGrath^TM videolaryngoscope was used according to the guidelines as much as possible, and the difference between the two groups was adequately clear. In addition, the strength of our findings was that our results were obtained in a real clinical setting. While most previous studies were conducted using mannequins and showed results of airway assessment in a simulated difficult airway situation, our study has great clinical significance as it sought a better orotracheal intubation method by applying it to actual patients.

In conclusion, the technique of gliding a blade under the epiglottis improved the intubation environment compared with the conventional Macintosh blade technique when using the videolaryngoscope in patients with a semi-rigid neck collar. Moreover, tracheal intubation was performed in a shorter duration with more ease and satisfaction for the anesthetists. We expect that intubation with a McGrath^TM videolaryngoscope using the gliding blade technique will be greatly helpful in an emergency setting for patients with cervical spine instability who require a semi-rigid neck collar.

Acknowledgements

We greatly thank the medical illustrator (Dong Soo Jang) at Yonsei University College of Medicine for his contribution to this study.

Notes

Funding

None.

Conflicts of Interest

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

Data Availability

The datasets generated during and/or analyzed during the current study are available from the corresponding author on reasonable request.

Author Contributions

Myoung Hwa Kim (Conceptualization; Data curation; Formal analysis; Investigation; Methodology; Writing – original draft)

Ji Young Kim (Conceptualization; Investigation; Methodology)

Jong Seok Lee (Conceptualization; Supervision)

Arim Jo (Data curation)

Do-Hyeong Kim (Conceptualization; Data curation; Formal analysis; Investigation; Methodology; Supervision; Writing – review & editing)

Supplementary Material

Supplementary Table 1.

Intraoperative vital signs.

kja-22733-Supplementary-Table-1.pdf

References

1. Thiboutot F, Nicole PC, Trépanier CA, Turgeon AF, Lessard MR. Effect of manual in-line stabilization of the cervical spine in adults on the rate of difficult orotracheal intubation by direct laryngoscopy: a randomized controlled trial. Can J Anaesth 2009;56:412–8.

2. Nolan JP, Wilson ME. Orotracheal intubation in patients with potential cervical spine injuries. An indication for the gum elastic bougie. Anaesthesia 1993;48:630–3.

3. Heath KJ. The effect of laryngoscopy of different cervical spine immobilisation techniques. Anaesthesia 1994;49:843–5.

4. Goutcher CM, Lochhead V. Reduction in mouth opening with semi-rigid cervical collars. Br J Anaesth 2005;95:344–8.

5. Benumof JL. Difficult laryngoscopy: obtaining the best view. Can J Anaesth 1994;41:361–5.

6. Salem MR, Mathrubhutham M, Bennett EJ. Difficult intubation. N Engl J Med 1976;295:879–81.

7. King TA, Adams AP. Failed tracheal intubation. Br J Anaesth 1990;65:400–14.

8. Gerling MC, Davis DP, Hamilton RS, Morris GF, Vilke GM, Garfin SR, et al. Effects of cervical spine immobilization technique and laryngoscope blade selection on an unstable cervical spine in a cadaver model of intubation. Ann Emerg Med 2000;36:293–300.

9. McElwain J, Malik MA, Harte BH, Flynn NH, Laffey JG. Determination of the optimal stylet strategy for the C-MAC videolaryngoscope. Anaesthesia 2010;65:369–78.

10. Bradley WP, Bain C, Mehra R, Symons J. Scoring systems for videolaryngoscopes. Anaesth Intensive Care 2013;41:122.

11. Seo SH, Lee JG, Yu SB, Kim DS, Ryu SJ, Kim KH. Predictors of difficult intubation defined by the intubation difficulty scale (IDS): predictive value of 7 airway assessment factors. Korean J Anesthesiol 2012;63:491–7.

12. Yentis SM, Lee DJ. Evaluation of an improved scoring system for the grading of direct laryngoscopy. Anaesthesia 1998;53:1041–4.

13. Taylor AM, Peck M, Launcelott S, Hung OR, Law JA, MacQuarrie K, et al. The McGrath® Series 5 videolaryngoscope vs the Macintosh laryngoscope: a randomised, controlled trial in patients with a simulated difficult airway. Anaesthesia 2013;68:142–7.

14. Cook TM. A grading system for direct laryngoscopy. Anaesthesia 1999;54:496–7.

15. Levitan RM, Ochroch EA, Kush S, Shofer FS, Hollander JE. Assessment of airway visualization: validation of the percentage of glottic opening (POGO) scale. Acad Emerg Med 1998;5:919–23.

16. Ochroch EA, Hollander JE, Kush S, Shofer FS, Levitan RM. Assessment of laryngeal view: percentage of glottic opening score vs Cormack and Lehane grading. Can J Anaesth 1999;46:987–90.

17. O’Loughlin EJ, Swann AD, English JD, Ramadas R. Accuracy, intra- and inter-rater reliability of three scoring systems for the glottic view at videolaryngoscopy. Anaesthesia 2017;72:835–9.

18. Lewis SR, Butler AR, Parker J, Cook TM, Schofield-Robinson OJ, Smith AF. Videolaryngoscopy versus direct laryngoscopy for adult patients requiring tracheal intubation: a cochrane systematic review. Br J Anaesth 2017;119:369–83.

19. Brück S, Trautner H, Wolff A, Hain J, Mols G, Pakos P, et al. Comparison of the C-MAC(^®) and GlideScope(^®) videolaryngoscopes in patients with cervical spine disorders and immobilisation. Anaesthesia 2015;70:160–5.

20. Kleine-Brueggeney M, Greif R, Schoettker P, Savoldelli GL, Nabecker S, Theiler LG. Evaluation of six videolaryngoscopes in 720 patients with a simulated difficult airway: a multicentre randomized controlled trial. Br J Anaesth 2016;116:670–9.

21. Kleine-Brueggeney M, Greif R, Urwyler N, Wirthmüller B, Theiler L. The performance of rigid scopes for tracheal intubation: a randomised, controlled trial in patients with a simulated difficult airway. Anaesthesia 2016;71:1456–63.

22. Paik H, Park HP. Randomized crossover trial comparing cervical spine motion during tracheal intubation with a Macintosh laryngoscope versus a C-MAC D-blade videolaryngoscope in a simulated immobilized cervical spine. BMC Anesthesiol 2020;20:201.

23. Hung KC, Chang YJ, Chen IW, Lin CM, Liao SW, Chin JC, et al. Comparison of video-stylet and video-laryngoscope for endotracheal intubation in adults with cervical neck immobilisation: a meta-analysis of randomised controlled trials. Anaesth Crit Care Pain Med 2021;40:100965.

24. Zhang J, Tan LZ, Toh H, Foo CW, Wijeratne S, Hu H, et al. Comparing the first-attempt tracheal intubation success of the hyperangulated McGrath^® X-blade vs the Macintosh-type CMAC videolaryngoscope in patients with cervical immobilization: a two-centre randomized controlled trial. J Clin Monit Comput 2022;36:1139–45.

25. Oh JY, Lee JH, Kim YY, Baek SM, Jung DW, Park JH. A comparative study of glottis visualization according to the method of lifting the epiglottis in video laryngoscopy: indirect and direct lifting methods. Anesth Pain Med (Seoul) 2021;16:196–200.

26. Sharma DJ, Weightman WM, Travis A. Comparison of the Pentax Airway Scope and McGrath videolaryngoscope with the Macintosh laryngoscope in tracheal intubation by anaesthetists unfamiliar with videolaryngoscopes: a manikin study. Anaesth Intensive Care 2010;38:39–42.

27. O’Leary AM, Sandison MR, Myneni N, Cirilla DJ, Roberts KW, Deane GD. Preliminary evaluation of a novel videolaryngoscope, the McGrath Series 5, in the management of difficult and challenging endotracheal intubation. J Clin Anesth 2008;20:320–1.

28. Epaud A, Levesque E, Clariot S. Dramatic cervical spine injury secondary to videolaryngoscopy in a patient suffering from ankylosing spondylitis. Anesthesiology 2021;135:495–6.

29. Mayglothling J, Duane TM, Gibbs M, McCunn M, Legome E, Eastman AL, et al. Emergency tracheal intubation immediately following traumatic injury: an Eastern Association for the Surgery of Trauma practice management guideline. J Trauma Acute Care Surg 2012;73:S333–40.

30. Lennarson PJ, Smith DW, Sawin PD, Todd MM, Sato Y, Traynelis VC. Cervical spinal motion during intubation: efficacy of stabilization maneuvers in the setting of complete segmental instability. J Neurosurg 2001;94(2 Suppl):265–70.

31. Byhahn C, Iber T, Zacharowski K, Weber CF, Ruesseler M, Schalk R, et al. Tracheal intubation using the mobile C-MAC video laryngoscope or direct laryngoscopy for patients with a simulated difficult airway. Minerva Anestesiol 2010;76:577–83.

32. Theiler LG, Kleine-Brueggeney M, Kaiser D, Urwyler N, Luyet C, Vogt A, et al. Crossover comparison of the laryngeal mask supreme and the i-gel in simulated difficult airway scenario in anesthetized patients. Anesthesiology 2009;111:55–62.

33. Bathory I, Frascarolo P, Kern C, Schoettker P. Evaluation of the GlideScope for tracheal intubation in patients with cervical spine immobilisation by a semi-rigid collar. Anaesthesia 2009;64:1337–41.

34. Jeon WJ, Shim JH, Cho SY, Baek SJ. Stylet- or forceps-guided tube exchanger to facilitate GlideScope intubation in simulated difficult intubations--a randomised controlled trial. Anaesthesia 2013;68:585–90.

35. Ali QE, Das B, Amir SH, Siddiqui OA, Jamil S. Comparison of the Airtraq and McCoy laryngoscopes using a rigid neck collar in patients with simulated difficult laryngoscopy. J Clin Anesth 2014;26:199–203.

Article information Continued

This is an open-access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0/) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

Variable	Conventional group (n = 88)	Gliding group (n = 88)	P value
Age (yr)	54.9 ± 10.2	55.5 ± 10.2	> 0.999
Sex (M/F)	59/29	60/28	> 0.999
Height (cm)	166.4 ± 8.5	167.3 ± 8.2	0.474
Weight (kg)	68.9 ± 11.9	69.3 ± 11.9	0.815
BMI (kg/m²)	24.7 ± 2.8	24.7 ± 3.0	0.843
ASA-PS			0.097
I	11 (12.5)	9 (10.2)
II	63 (71.6)	53 (60.2)
III	14 (15.9)	26 (29.5)
Surgical name			0.661
ACDF	65 (73.9)	63 (71.6)
Laminoplasty	9 (10.2)	13 (14.8)
Laminectomy	7 (8.0)	4 (4.5)
Others	7 (8.0)	8 (9.1)
Mallampati’s score			0.365
Ⅰ	33 (37.5)	24 (27.3)
Ⅱ	42 (47.7)	44 (50)
Ⅲ	12 (13.6)	17 (19.3)
Ⅳ	1 (1.1)	3 (3.4)
Thyromental distance (cm)	7.5 ± 1.2	7.2 ± 1.2	0.151
Inter-incisor distance (cm)
Before neck collar	5.4 ± 0.9	5.3 ± 0.9	0.660
After neck collar	3.3 ± 0.9	3.3 ± 1.0	0.563
Neck circumference (cm)	38.4 ± 3.9	38.7 ± 3.6	0.602
Poor dentition^*	10 (11.4)	13 (14.8)	0.655
Limited range of motion of cervical spine^†	28 (31.8)	40 (45.5)	0.088
Inability to protrude the lower jaw	0 (0.0)	2 (2.3)	0.497

Variable	Conventional group (n = 88)	Gliding group (n= 88)	P value
POGO (%)^*	63.8 ± 27.4	88.9 ± 14.7	< 0.001
Time to obtain optimal view (s)	27.5 ± 15.6	19.0 ± 6.9	< 0.001
Duration of intubation (s)	55.8 ± 15.5	45.8 ± 8.2	< 0.001
Attempts of intubation			> 0.999
1	86 (97.7)	87 (98.7)
2	2 (2.3)	1 (1.1)
CL grade			< 0.001
Ⅰ	1 (1.1)	0 (0.0)
Ⅱa	18 (20.5)	48 (54.5)
Ⅱb	59 (67.0)	40 (45.5)
Ⅲ	9 (10.2)	0 (0.0)
Ⅳ	1 (1.1)	0 (0.0)
Lifting force	59 (67.0)	23 (26.1)	< 0.001
Vocal cord position			0.496
Abduction	82 (93.2)	85 (96.6)
Adduction	6 (6.8)	3 (3.4)
Alternative methods	0	0	> 0.999
Additional operator	2 (2.3)	0 (0.0)	0.497
‘BURP’ maneuver	23 (26.1)	6 (6.8)	0.001
IDS			< 0.001
N0	13 (14.8)	41 (46.6)
N1	21 (23.9)	23 (26.1)
N2	25 (28.4)	18 (20.5)
N3	22 (25.0)	5 (5.7)
N4	4 (4.5)	1 (1.1)
N5	3 (3.4)	0 (0.0)
Easiness of intubation			< 0.001
1	36 (40.9)	69 (78.4)
2	30 (34.1)	16 (18.2)
3	14 (15.9)	1 (1.1)
4	8 (9.1)	1 (1.1)
5	0 (0.0)	1 (1.1)
Satisfaction for intubation			< 0.001
1	5 (5.7)	1 (1.1)
2	8 (9.1)	0 (0.0)
3	16 (18.2)	2 (2.3)
4	35 (39.8)	22 (25.0)
5	24 (27.3)	63 (71.6)

Variable	Conventional group (n = 88)	Gliding group (n = 88)	P value
During intubation
Lip injury	3 (3.4)	0 (0.0)	0.246
Mucosal bleeding	4 (4.5)	1 (1.1)	0.368
Teeth injury	0	0	> 0.999
Hypoxic event^*	0	0	> 0.999
After extubation at PACU
NRS of sore throat	1.9 ± 2.0	1.8 ± 1.8	0.723
Visible blood	5 (5.7)	4 (4.5)	> 0.999
Teeth injury	0 (0.0)	0 (0.0)	> 0.999
Dysphasia	1 (1.1)	1 (1.1)	> 0.999
Voice change	2 (2.3)	4 (4.5)	0.682
Hypoxic event	0	0	> 0.999
Postoperatively in a ward
Hoarseness	3 (3.4)	3 (3.4)	> 0.999
Dysphagia	3 (3.4)	1 (1.1)	0.621
Vocal cord palsy	0 (0.0)	2 (2.3)	0.497