British Journal of Anaesthesia 113 (5): 8 6 (14) Advance Access publication 1 August 14. doi:.93/bja/aeu229 PAEDIATRICS Nasotracheal intubation depth in paediatric patients M. Kemper 1, A. Dullenkopf 2, A. R. Schmidt 1, A. Gerber 1 and M. Weiss 1 * 1 Department of Anaesthesia, University Children s Hospital, Steinwiesstrasse 75, CH-832 Zurich, Switzerland 2 Institute of Anaesthesia and Intensive Care Medicine, Kantonsspital, Frauenfeld, Switzerland * Corresponding author. E-mail: markus.weiss@kispi.uzh.ch; www.safetots.org Editor s key points The depth of nasotracheal tube placement has traditionally been guided by formulae based on patient age, body weight, or both. These formulae are made for uncuffed tracheal tubes, but cuffed tracheal tubes are increasingly used in neonates and children. In this study, using different formulae to guide Microcuff paediatric endotracheal tube (PET) placement would have caused misplacement in most cases. The depth mark of the Microcuff PET should be used to determine proper tube placement. lintubationdepthinchildreniscriticalbecauseof their short trachea. 1 Correct insertion depth of tracheal tubes is essential to avoid accidental endobronchial intubation, irritation of the carina, misplacement of the cuff between the vocal cords, and accidental tracheal extubation. Moreover, there is an increased risk of tube malpositioning, mainly for neonates, infants, and small children, during head neck movement. 2 5 Nasotracheal intubation is consideredtoallowmorestabletubeplacementwithinthetrachea. 6 In the past, several formulae and recommendations for adjusting nasotracheal intubation depth at the nose have been published (Tables 1 and 2). In recent years, cuffed tracheal tubes have become standard in paediatric anaesthesia. 7 However, there are no data so far with regard to proper Background. The aim of this study was to compare intubation depth using the Microcuff paediatric endotracheal tube (PET) placed with the intubation depth mark between the vocal cords with that of different published formulae/recommendations for nasotracheal intubation depth in children. Methods. Children aged from birth to yr undergoing elective surgery with nasotracheal intubation were included. l tubes were adjusted according to the intubation depth mark between the vocal cords using direct laryngoscopy. Nasal intubation depth was recorded and the distance tube tip to carina was measured endoscopically. Based on the recorded nasal intubation depth and measured distance tube tip to carina, the position of tube tip and cuff was calculated according to six published formulae/recommendations. Results. Seventy-six children were studied. For the Microcuff PET, the median tube tip advancement within the trachea was 52.9% (41.1 73.8%) of tracheal length. The shortest distance from the tube tip to carina was 15 mm for a 3.5 mm internal diameter tube. If the six published formulae/recommendations had been used, this would have resulted in endobronchial tube placement in up to 9.1% of cases, and the tube tip would have been placed above the glottis in up to 2.6% of cases. The upper border of the cuff would have been placed in the subglottic area in up to 42.1% of cases and in a supraglottic position in up to 63.2% of cases. Conclusions. This study indicates that nasal intubation with the intubation depth mark placed between the vocal cords was superior to formula-based nasotracheal tube positioning. The latter would result in a high rate of endobronchial intubations, excessively high cuff positions and even tracheal extubations. Keywords: airway; children; complications, intubation nasotracheal; tracheal tube; intubation Accepted for publication: 22 April 14 positioning of tracheal tube tip and cuff, when using common formulae for nasotracheal intubation depth in cuffed paediatric tracheal tubes. The aim of this study was to compare intubation depth using the Microcuff paediatric endotracheal tube (PET) placed with the intubation depth mark between the vocal cords with different published formulae/recommendations for nasotracheal intubation depth in children. Methods After obtaining Hospital Ethics Committee approval in 3 (StV 23-3) and informed parental consent, a prospective study including paediatric patients aged between birth and Downloaded from https://academic.oup.com/bja/article-abstract/113/5/8/2993 by guest on 5 October 18 Contribution similar to that of first author. & The Author 14. Published by Oxford University Press on behalf of the British Journal of Anaesthesia. All rights reserved. For Permissions, please email: journals.permissions@oup.com
Nasotracheal intubation depth in paediatric patients BJA Table 1 Formulae/recommendations for nasotracheal intubation depth No. Formula/recommendation age (yr), weight (kg) Source, author, year 1 14+(age/2) Paediatric Anaesthesia, Davenport, 3rd Edn, 198 8 2,4 yr Antona and colleagues,.5+(weight/2) 2 9 3.3 kg Yates and colleagues, L¼(3 S)+2 S¼ internal diameter (ID) in mm 1987 4 (a),1 yr: 9+(weight/2) Lau and colleagues, (b).1 yr: 15+(age/2) 6 11 5 Recommendation (see Table 2) Manual of Pediatric Anesthesia, Steward, 5th Edn, 1 12 6 Recommendation Kim and colleagues, Tube tip to carina distance of 2 cm in paediatric patients aged from to 7 (yr) 3 13 Table 2 Nasal intubation depth according to recommendation 5 12 Approximate age of patient (yr) Nasal intubation length (cm) Newborn 14 1 15 2 16 4 17 6 19 8 21 22 yr was conducted from 3 until 9. Patients included were undergoing elective surgery or dental procedures requiring general anaesthesia and nasotracheal intubation. Exclusion criteria were known or suspected airway anomalies and difficult tracheal intubation. Premedication and induction of anaesthesia (inhalation or i.v.) depended on the patient s medical condition and preference. A non-depolarizing neuromuscular blocking agent was administered and anaesthesia was maintained with sevoflurane in oxygen/nitrous oxide. The patient s trachea was intubated using the Microcuff PET (Microcuff GmbH, Weinheim, Germany) and tracheal tube size was selected according to the manufacturer s instructions (Table 3). Nasotracheal intubation was performed inall patients and the glottic intubation mark was placed between the vocal cords using direct laryngoscopy (depth mark-based tracheal tube placement). Subsequently, intubation depth at the base of the nose was recorded and the tube was secured by tapes. With the patient supine and the head in a neutral position, the distance from the tube tip to the carina was measured endoscopically using the drawback technique. 14 Table 3 Age-based tube size selection of the Microcuff PET (4) 14 ID (mm) Distance depth mark to tube tip (mm) 3. Newborn ( 3 kg) to,1 Data analysis l length(vocal cordsto carina distance) was calculatedby adding the intubation depth mark to tube tip distance to the measured distance from the tube tip to carina. The percentage of tube tip advancement within the trachea was then calculated. The position of the tracheal tube tip relatedto the carinawas calculated when the tracheal tube would have been inserted according to one of the formulae (1 4) and recommendation (5) for nasotracheal intubation depth. Tube tip position with formula 3 [formula including internal diameter (ID)] was also calculated for age-related uncuffed tubes (ID+.5 mm ID), resulting in formula 3b. The number of tracheal tubes placed endobronchially (below the carina) and the numberof tracheal tubes at risk of endobronchial intubation after 8 head neck flexion {maximal downward tube movement (mm) ¼ [(.83 age (yr)]+9.3} were calculated. 15 Similarly, the number of tracheal tube tips placed in the supraglottic area and the number of tracheal tubes at risk for tracheal extubation after 8 head neck extension [maximal upward tube movement (mm)¼.71 age (yr)+9.9] were calculated. 15 Under the assumption that the upper cuff border of the Microcuff PET is placed just below the level of the cricoid cartilage if inserted according to the intubation depth mark, the resulting position of the upper cuff border of the Microcuff PET related to the cricoid ring was calculated with each of the four formulae and two recommendations. 16 The numberof tubes withcuff position in the subglottic and supraglottic area were calculated. The subglottic areawas derived from previous anatomical data of the vocalcordtocricoidring,thedistancebeing9mminanewborn 17 18 and 14 mm in an 11-yr-old child. Data are presented as mean (SD) or median (range) as appropriate. Results 24 9 3.5 1 to,2 27 4. 2 to,4 12 4.5 4 to,6 34 12 5. 6 to,8 39 16 5.5 8 to, 45 16 Distance depth mark to upper cuff border (mm) In total, 76 paediatric patients ( females, 36 males) aged from 3 weeks to yr (mean 5. yr) were included in the study. Depth mark-based nasotracheal intubation resulted in a minimum tube tip to carina distance of 15 mm in a 1.9-yr-old infant to a maximum of 56 mm in a 7.4-yr-old girl. The mean tube tip advancement into the trachea was 52.8% 841 Downloaded from https://academic.oup.com/bja/article-abstract/113/5/8/2993 by guest on 5 October 18
BJA Kemper et al. 9 8 7 6 5 Depth mark vs formula 1 Depth mark vs formula 2 9 8 7 6 5 6 7 8 9 1 2 3 4 5 1 2 3 4 5 6 7 8 9 Depth mark vs formula 3a Depth mark vs formula 3b 9 8 7 6 5 9 8 7 6 5 1 2 3 4 5 6 7 8 9 1 2 3 4 5 6 7 8 9 Depth mark vs formula 4 9 8 7 6 5 1 2 3 4 5 6 7 8 9 Depth mark vs recommendation 6 9 8 7 6 5 1 2 3 4 5 6 7 8 9 9 8 7 6 5 Depth mark vs recommendation 5 1 2 3 4 5 6 7 8 9 Downloaded from https://academic.oup.com/bja/article-abstract/113/5/8/2993 by guest on 5 October 18 Fig 1 Tube tip to carina distance with depth mark-based tracheal tube placement (filled diamond) and recalculated with each of the four formulae and two recommendations (open diamond). Shaded areas indicate tube tip at risk for endobronchial intubation after 8 head neck flexion and endobronchially placed tubes. 842
Nasotracheal intubation depth in paediatric patients BJA Formula 1 Formula 2 1 2 3 4 5 6 7 8 9 1 2 3 4 5 6 7 8 9 Formula 3a 1 2 3 4 5 6 7 8 9 Formula 4 1 2 3 4 5 6 7 8 9 Recommendation 6 1 2 3 4 5 6 7 8 9 Formula 3b 1 2 3 4 5 6 7 8 9 Recommendation 5 1 2 3 4 5 6 7 8 9 Downloaded from https://academic.oup.com/bja/article-abstract/113/5/8/2993 by guest on 5 October 18 Fig 2 Position of tube upper cuff border (thick line) with nasotracheal intubation depth calculated with each of the four formulae and two recommendations. The position of the uppercuff borderof the Microcuff trachealtube (not shownin the figure) is placeddirectly belowthe cricoid, as given by the anatomically based design of the Microcuff tracheal tube. Shaded areas indicate the upper cuff border located within the subglottic area and in the supraglottic area. 843
844 Table 4 Number of tracheal tube tips and tube cuffs placed in an abnormal and critical position when used with the four formulae or two recommendations for nasotracheal tube positioning. Calculation 3b: modified if uncuffed tubes (+.5 mm ID) had been used in this study No. Formula/ recommendation (length in cm) age (yr), weight (kg) No. of tubes at risk for endobronchial intubation No. of tubes placed endobronchial No. of cuffs in the subglottic space No. of cuffs placed supraglottically No. of tube tips at risk for tracheal extubation No. of tube tips placed supraglottically No. of tube tips placed in correct position 1 14+(age/2) 3/76 (3.9%) 2/76 (2.6%) 32/76 (42.1%) /76 (26.3%) 1/76 (1.3%) 7/76 (92.1%) 2,4 yr:.5+(weight/2) 11/33 (33.3%) 3/33 (9.1%) 1/33 (3.%) 19/33 (57.6%) 3a.3 kgl¼(3 ID)+2 1/76 (1.3%) 16/76 (21.1%) 48/76 (63.2%) 24/76 (31.6%) 2/76 (2.6%) 49/76 (64.5%) 3b*.3kg L¼(3 (ID+.5))+2 4/76 (5.3%) 1/76 (1.3%) 27/76 (35.5%) 8/76 (.5%) 1/76 (1.3%) 7/76 (92.1%) 4a,1 yr: 9+(weight/2) 2/7 (28.6%) 1/7 (14.3%) 7/7 (%) 4b.1 yr: 15+(age/2) /69 (14.5%) 17/69 (24.6%) 4/69 (5.8%) 59/69 (85.5%) 5 Recommendation (age-based list) 6 Recommendation 2 cm above the carina 7 Depth mark-based intubation 9/76 (11.8%) 4/76 (5.3%) 13/76 (17.1%) 2/76 (2.6%) 63/76 (82.9%) 7/76 (9.2%) 76/76 (%) /76 /76 /76 /76 /76 /76 76/76 (%) Downloaded from https://academic.oup.com/bja/article-abstract/113/5/8/2993 by guest on 5 October 18 No. of cuffs placed in correct position 24/76 (31.6%) 32/33 (97.%) 12/76 (15.8%) 31/76 (.8%) 4/7 (57.1%) 48/69 (69.6%) 61/76 (8.3%) 69/76 (9.8%) 76/76 (%) Median (range) tube tip advancement within the trachea in % 47.% (16.1 129.3%) 78.7% (5.9 111.1%) 28.4 (212.7 82.%) 51.3% (11.1 6.6%) 51.% (26. 71.4%) 6.5% (26.7 99.7%) 6.7% (27. 128.6%) 69.% (52.4 79.%) 52.9% (41.1273.8%) BJA Kemper et al.
Nasotracheal intubation depth in paediatric patients BJA (6.4) of the tracheal length, with a minimum of 41.1% and a maximum of 73.8%. Using depth mark-based intubation, none of the tube tips was at risk for endobronchial intubation after potential 8 head neck flexion (Fig. 1). The measured tube tip positions for the depth mark-based intubation and the calculated tube tip positions are shown and compared in Figure 1. The position of the upper cuff border of a Microcuff PET when intubated according to the depth mark or according to the formulae/recommendations is shown and compared in Figure 2. Table 4 explicitly lists the number of tracheal tube tips and cuffs placed in an undesirable or critical position using one of the four formulae and two recommendations. Discussion This study compared depth mark-based nasotracheal tube placement with the Microcuff PET with standard formulae and recommendations for adjusting nasotracheal intubation depth with regard to safe tracheal tube tip and cuff placement. The main finding was that depth mark-based tracheal intubation allowed safe positioning of the tracheal tubes in all patients. However, standard formulae/recommendations used for adjusting nasotracheal intubation depth resulted in a high number of misplaced or critical tracheal tube tip and cuff positions with the exception of recommendation 6, which advises using a constant, clinically determined distance tube tip to carina of 2 cm in paediatric patients. 13 Standard formulae/recommendations for nasotracheal intubation depth have been introduced for adjusting tracheal tubes if depth marks are missing or not visible at direct laryngoscopy and providing a quick guide for appropriate tracheal tube positioning. As shown in this study, all formulae and recommendation 5 resulted in tubes that risked either accidental endobronchial intubation, especially with assumed head neck flexion, or extubation, especially with head neck extension, respectively. These results apply equally to cuffed and uncuffed tracheal tubes. Neither were the formulae and recommendations useful for proper cuff position, even with correction of ID for cuffed tracheal tubes in formula 3b. Surprisingly, recommendation 6 revealed safe tracheal tube positioning and onlyavery low rate of tube cuffs reaching the subglottic area, by advising placement of all tracheal tubes 2 cm above the carina. However, using auscultation of breath sounds or inspiratory pressure decrease during drawback of a tube placed endobronchially as a method for tube positioning 2 cm above the carina does not appear to be very practicable in clinical practice and can be interfered with by a Murphy eye, still present in some tube brands. 19 Tube positioning 2 cm above the carina would be helpful if fibreoptic nasotracheal intubation is performed in children. Occasionally, depth mark-based tracheal tube placement is criticized as being imprecise because of head-extension (if at all) during direct laryngoscopy which leads to caudal displacement of the tracheal tube when the head is again placed in a neutral position. However, as shown in this study by endoscopy, all tracheal tube tips were placed within a safe tracheal range. There are only limited data and no follow-up clinical studies confirming safety and appropriateness of published formulae. 13 19 21 All of these formulae (1 4) and recommendations (5/6) were developed for uncuffed tracheal tubes and were only focused on tube tip position. The present work is the first study investigating cuff position with these formulae and recommendations, clearly demonstrating that these tube positioning techniques do not guarantee proper cuff position below the cricoid. cuff placement may cause vocal cord palsy by compressing the recurrent laryngeal nerve. cuff position will lead to cranial movement of the tracheal tube with cuff inflation and may result in accidental extubation. Other control techniques of tube tip or cuff position (palpation, fibreoptic, ultrasound, lighted stylet, X-ray) do not reliably 21 28 prevent such complications. The clinical implication of the present study is that for the Microcuff PET, depth mark-based intubation is reliable, whereas the use of standard formulae/recommendations for nasal intubation depth is not helpful and may lead to dangerous tube tip or cuff position. The fact that formulae and recommendations for nasotracheal intubation depth are not sufficientlyreliableis notsurprising, since craniofacial dimensions and tracheal lengths vary among children with the same age or weight, whose tracheas will be intubated with the same tube size. Thus, similar to orotracheal intubation, placing a nasotracheal tube relying on depth marks is superior to formula-based tube placement. 29 Accordingly, tracheal tube cuffs can only be placed properly using an intubation depth mark which is situated at an anatomically correct distance from the upper cuff border. 16 A limitation to our study is the number of patients included. However, only patients from birth to yr were studied, so the number of patients is comparable with that of other studies. 13 11 Our results are only representative for the Microcuff PET that was used in this study for two reasons: first, as known from prior investigations, other paediatric cuffed tracheal tube brands have longer, higher, or both tube cuffs. This would have resulted in an even higher incidence of subglottic and supraglottic cuff position. 19 Secondly, many cuffed paediatric tracheal tubes have no, misleading, or incorrectly 19 placed intubation depth marks. In conclusion, depth mark-based nasotracheal intubation is superior to formula and recommendation-based nasotracheal tube placement. The latter resulted in a high rate of endobronchial intubations, excessively high cuff positions and even tracheal extubations. Authors contributions M.K.: calculations, graphs, and writing of the manuscript. A.D.: patient recruitment. A.R.S.: calculations and writing of the manuscript. A.G.: measurements. M.W.: ethical protocol, study protocol, measurements, and writing of the manuscript. Declaration of interest None declared. 845 Downloaded from https://academic.oup.com/bja/article-abstract/113/5/8/2993 by guest on 5 October 18
BJA Kemper et al. Funding The study was supported by a research grant obtained from Microcuff GmbH, Weinheim, Germany (4). References 1 Griscom NT, Wohl ME. Dimensions of the growing trachea related to age and gender. Am J Roentgenol 1986; 146: 233 7 2 Todres ID, debros F, Kramer SS, Moylan FM, Shannon DC. Endotracheal tube displacement in the newborn infant. J Pediatr 1976; 89: 126 7 3 Donn SM, Kuhns LR. Mechanism of endotracheal tube movement with change of head position in the neonate. Pediatr Radiol 198; 9:37 4 Sugiyama K, Yokoyama K. Displacement of the endotracheal tube caused by change of head position in pediatric anesthesia: evaluation by fiberoptic bronchoscopy. Anesth Analg 1996; 82: 251 3 5 Conrardy PA, Goodman LR, Lainge F, Singer MM. Alteration of endotracheal tube position. Flexion and extension of the neck. Crit Care Med 1976; 4:7 12 6 Boulain T. Unplanned extubations in the adult intensive care unit: a prospective multicenter study. Association des Reanimateurs du Centre-Ouest. Am J Respir Crit Care Med 1998; 157: 1131 7 7 Litman RS, Maxwell LG. Cuffed versus uncuffed endotracheal tubes in pediatric anesthesia: the debate should finally end. Anesthesiology 13; 118: 5 1 8 Davenport HT. Paediatric Anaesthesia, 3rd Edn. London: Heinemann Medical Books, 198 9 Antona MdlS, López-Herce J, Rupérez M, García C, Garrido G. Estimation of the length of nasotracheal tube to be introduced in children. J Pediatr 2; 1: 772 4 Yates AP, Harries AJ, Hatch DJ. Estimation of nasotracheal tube length in infants and children. Br J Anaesth 1987; 59: 524 6 11 Lau N, Playfor SD, Rashid A, Dhanarass M. New formulae for predicting tracheal tube length. Paediatr Anaesth 6; 16: 1238 43 12 Steward DJ, Lerman J. Manual of Pediatric Anesthesia, 5th Edn. New York: Churchill Livingstone, 1 13 Kim KO, Um WS, Kim CS. Comparative evaluation of methods for ensuring the correct position of the tracheal tube in children undergoing open heart surgery. Anaesthesia 3; 58: 889 93 14 Weiss M, Gerber AC, Dullenkopf A. Appropriate placement of intubation depth marks in a new cuffed paediatric tracheal tube. Br J Anaesth 5; 94: 8 7 15 Weiss M, Knirsch W, Kretschmar O, et al. l tube-tip displacement in children during head neck movement a radiological assessment. Br J Anaesth 6; 96: 486 91 16 Weiss M, Dullenkopf A, Gerber AC. Microcuff pediatric tracheal tube. A new tracheal tube with a high volume low pressure cuff for children. Anaesthesist 4; 53: 73 9 17 Kahane JC. Growth of the human prepubertal and pubertal larynx. J Speech Hear Res 1982; 25: 446 55 18 Schild JA. Relationship of laryngeal dimensions to body size and gestational age in premature neonates and small infants. Laryngoscope 1984; 94: 1284 92 19 Weiss M, Dullenkopf A, Gysin C, Dillier CM, Gerber AC. Shortcomings of cuffed paediatric tracheal tubes. Br J Anaesth 4; 92: 78 88 Cavo JW Jr. True vocal cord paralysis following intubation. Laryngoscope 1985; 95: 1352 9 21 Pollard RJ, Lobato EB. Endotracheal tube location verified reliably by cuff palpation. Anesth Analg 1995; 81: 135 8 22 Bednarek FJ, Kuhns LR. Endotracheal tube placement in infants determined by suprasternal palpation: a new technique. Pediatrics 1975; 56: 224 9 23 Okuyama M, Imai M, Sugawara K, Okuyama A, Kemmotsu O. Finding appropriate tube position by the cuff palpation method in children. Masui 1995; 44: 845 8 24 McKay WP, Klonarakis J, Pelivanov V, O Brien JM, Plewes C. l palpation to assess endotracheal tube depth: an exploratory study. Can J Anaesth 14; 61: 229 34. 25 Phipps LM, Thomas NJ, Gilmore RK, et al. Prospective assessment of guidelines for determining appropriate depth of endotracheal tube placement in children. Pediatr Crit Care Med 5; 6: 519 22 26 Dennington D, Vali P, Finer NN, Kim JH. Ultrasound confirmation of endotracheal tube position in neonates. Neonatology 12; 2: 185 9 27 SongY, Oh J, Chee Y, Lim T, Kang H, Cho Y. A novel method to position an endotracheal tube at the correct depth using an infrared sensor stylet. Can J Anaesth 13; 6: 444 9 28 Dietrich KA, Strauss RH, Cabalka AK, Zimmerman JJ, Scanlan KA. Use of flexible fiberoptic endoscopy for determination of endotracheal tube position in the pediatric patient. Crit Care Med 1988; 16: 884 7 29 Weiss M, Balmer C, Dullenkopf A, et al. Intubation depth markings allow an improved positioning of endotracheal tubes in children. Can J Anaesth 5; 52: 721 6 Goel S, Lim SL. The intubation depth marker: the confusion of the black line. Paediatr Anaesth 3; 13: 579 83 Handling editor: J. P. Thompson Downloaded from https://academic.oup.com/bja/article-abstract/113/5/8/2993 by guest on 5 October 18 846