Anesthesia Intubation Complication Clinical Trial
Official title:
Prediction of Optimal Pediatric Endotracheal Tube Size "Aged Based Formula Versus Ultrasonography"
Background: Ultrasound (US) imaging technique has recently emerged as a novel, simple,
portable, noninvasive tool helpful for airway assessment and management. Initial few
published reports were on soft tissue imaging of neck, focusing on pre-tracheal structure and
anterior tracheal wall. In our study, we compared the measurement of subglottic diameter
using ultrasonography and the aged based formula in prediction of endotracheal tube size in
children underwent elective surgical operation under general anesthesia.
Methods: Patients were randomly divided in 2 groups (27 patients each) using a
computer-generated randomization schedule. The first group was aged based group (group AB) (n
= 27): the endotracheal tube size was determined according to age of the child [inner
diameter [ID] in mm = (age in yr/4) +4. The second group was ultrasound based group (group
UB) (n = 27): the endotracheal tube size was determined according to the subglottic
transverse diameter that was estimated with ultrasonography (the outer diameter of
endotracheal tube (ETT OD) = 0.55*(subglottic diameter)+1.16) .
Introduction:
Pediatric tracheal intubation requires considerable expertise and can represent a challenge
to many anesthesiologists(Marciniak et al.,2009). Anatomically; the larynx of a pediatric
patient assumes a funnel shape with its narrowest part at the level of the cricoid ring,
which cannot be seen during conventional laryngoscopy (Karsli et al.,2002).
Choosing the correct endotracheal tube (ETT) size needed for intubation of pediatric patients
is important because an inappropriately too large tracheal tube can cause upper airway damage
(e.g., local ischemia, ulceration, scar formation) and the potential for subsequent
subglottic stenosis. In contrast, an ETT that is too small may result in insufficient
ventilation, poor reliability of end-tidal gas monitoring, leakage of anesthetic gases into
the operating room environment, and an enhanced risk of aspiration(Karsli et al.,2002).
Different algorithms and formula have been proposed to choose the best-fitting size of the
endotracheal tube. Age-based formulas, such as those of Cole and Motoyama, have been used to
estimate optimal ETT size for more than half a century (Motoyama,1990) and this formula is
[inner diameter (ID) in mm = (age in yr/4) +4]. Predictive formulas for appropriate ETT size
have also been based on patient weight and height as[ID in mm = 2 + height in cm/30] and [ID
in mm = 2.44 + age in yr ×0.1 + height in cm ×0.02 + weight in kg ×0.016] and other formula
as the width of the 5th fingernail is used for ID prediction of the ETT [ID in mm = maximum
width of the 5th fingernail] (Shibasaki et al.,2010). However, these methods are not always
suitable because the size of the airway varies considerably between patients.
Ultrasound guided is helpful for evaluate the subglottic transverse diameter which is safe ,
sample, painless and non invasive modality for prediction of proper endotracheal tube size
(Jagadish G Sutagatti et al., 2017).
In this study, we compared the measurement of subglottic diameter using ultrasonography and
the aged based formula in prediction of endotracheal tube size in children underwent elective
surgical operation under general anesthesia.
Patients and methods:
Study design and participants After getting approval from the institutional research
board(MS/16.01.143), faculty of medicine , Mansoura University, written informed consents
were obtained from parents of fifty children aged from 1 to 6 years of either sex scheduled
for elective surgery not exceeded 90 minutes underwent general anesthesia with uncuffed
endotracheal tube. This randomized controlled study was conducted in Emergency Hospital,
Mansoura University between April/2016 to April/2017 .
Patient exclusion criteria include: an anticipated difficult airway, any respiratory disease
that might cause airway narrowing, pre-exiting laryngeal or tracheal pathology, any lesion
that could cause airway deformity due to fibrosis or the presence of a neck anatomical
pathologies that might have unpredictable effect on the ultrasound assessment of the airway
and prolonged surgery more than 90 minutes .
Sample size calculation:
The appropriateness of ETT size was adopted as a primary parameter for effective size used
for sample size calculation. A power of 80% was accepted with alpha error of 0.05. fifty four
patients in both groups were found to be enough to detect a 20% difference between groups.
Patients were randomly divided in 2 groups (27 patients each) using a computer-generated
randomization schedule.
Aged based group (group AB) (n = 27): ETT size was determined according to age of the child,
inner diameter [ID] in mm = (age in yr/4) +4(Van den Berg and Mphanza, 1997).
Ultrasound based group (group UB) (n = 27): ETT was determined according to the subglottic
transverse diameter that was estimated with ultrasonography.
Technique:
On arrival to the operating room, basic monitors were applied {ECG, pulse oximetry,
non-invasive blood pressure (NIBP)}, baseline values were recorded and An intravenous cannula
(24G) was inserted and secured . General anesthesia was induced by inhalation of sevoflurane.
Muscular relaxation was achieved with atracurium (0.5mg/kg) to facilitate the endotracheal
intubation under direct laryngoscopy. The patients were ventilated with sevoflurane in 100%
oxygen via a facemask before intubation for 3 min for proper muscles relaxation. ETT was
chosen according to each group. Aged based formula (inner diameter [ID] in mm = (age in yr/4)
+4) was used in group AB and in group UB, during mask ventilation ultrasound guided
subglottic transverse diameter was measured with assistant anesthesiologist help. To avoid
observer bias by anesthesiologist who performs the leak test by the absence of ultrasound
machine in the operating room, the ultrasound assessment also was done in group
AB(aged-based).
Ultrasonography technique:
The subglottic diameter was estimated with B-mode ultrasonography (Korean, Siemens, Acuson,
x300) with a 10-13-MHz linear probe positioned on the midline of the anterior neck (figure1).
The evaluation began by identifying the true vocal folds as paired hyperechoic linear
structures that moved with respiration and swallowing before patients were paralyzed. The
probe was then moved caudally to visualize the cricoid arch which appears as an arched,
rounded and hypoechoic structure (figure2). The transverse air-column diameter was measured
at the lower edge of the cricoid cartilage after patients were paralyzed (figure3).
The measurements of the subglottic diameter was used to select the outer diameter of
endotracheal tube by the equation [ETT OD=0.55*(subglottic diameter)+1.16] (Shibasaki et al.,
2010), since the outer diameter of endotracheal tube differs among different manufactures, we
used uncuffed Mallinckrodt tracheal tube with a Murphy's eyes.
The inner diameter of endotracheal tube that was calculated according to table (1) which show
the correlation between outer and inner diameter of the endotracheal tube.
Determination of appropriateness of ETT size:
Another anesthesiologist who was blinded to the group allocation did the air leak test in all
patients. The air leak test was done after successful intubation of ETT chosen on the basis
of either of two methods, The correct tracheal tube size was considered optimal when an
audible air leak around the tube at an inspiratory airway pressure was detected between 10-30
cm H2O, with the head and neck in a neutral position. The presence of an air leak was
assessed by closing off the pop-off valve and allowing pressure to rise slowly until an
audible leak was heard using a stethoscope on the tube. If there was no audible leak when the
lung were inflated to a pressure of 30 cm H2O, the tube was exchanged with one that was 0.5
mm smaller. But if a leak occurred at an inflation pressure of less than 10 cm of H2O, the
ETT was exchanged for one with the 0.5 mm larger tube.
The following parameters were monitored:
1. Primary outcome: Number of optimum tube selection was monitored in both group (group AB
and group UB).2- Number of reintubation due to large or small tube.
2. Secondary outcome: 1- Time of intubation. 2- Complication after extubation.
Statistical analysis:
All statistical analyses were performed using SPSS for windows version 20.0 (SPSS, Chicago,
IL). Continuous data we re-expressed in mean ±standard deviation (SD) white categorical data
were expressed in number and percentage. The differences between two groups were determined
using Student's t test for variables with continuous data and chi-square test for variables
with categorical data. The 95% confidence interval (CI) for the frequency of correct size of
the endotracheal tube (ETT) was calculated. Statistical significance was set at p<0.05.
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