Nasotracheal Intubation Clinical Trial
Official title:
Nasotracheal Intubation in Children for Outpatient Dental Surgery: Is Fiberoptic Bronchoscopy Useful?
The aim of study was to compare the hemodynamic responses and adverse events associated with nasotracheal intubation (NTI) using a fiberoptic bronchoscope (FOB) and a direct laryngoscope (DLS) in children undergoing general anesthesia for outpatient dental surgery. Eighty children (aged 5-15 years) were scheduled to undergo outpatient dental surgery under general anesthesia and who required nasotracheal intubation were included.
Investigators obtained confirmation from the Inonu University Medical Faculty Hospital Ethics
Committee (2015/101) and written informed consent from the guardians of all 80 children.
These children, who had a American Society of Anesthesia physical status of I-II, had a
Mallampati Score of 1-2, were aged 5-15 years, were scheduled to undergo outpatient dental
surgery under general anesthesia, and required nasotracheal intubation were included in this
prospective and randomized study. Exclusion criteria included the following: the patient's
refusal for study consent, active upper respiratory infection, airway abnormalities, nasal
mass or nasal injury, bleeding disorders, allergies to anesthetics, uncontrolled
hypertension, morbid obesity, hepatic or renal failure, cardiovascular diseases, a history of
nasopharyngeal surgery and those who were difficult to intubate. Children were randomly
assigned into the direct laryngoscopy group (n = 40) or the fiberoptic bornchoscopy group (n
= 40) according to a computer-randomized table. General anesthesia was administered to
children due to the learning difficulties. The number of models was decided by a statistical
power analysis after the conclusions from the pretest were obtained. All children fasted at
least for 6 h before surgery, and the oral intake of clear fluids was restricted for 2-3 h.
Premedication of midazolam (0.5 mg/kg) was orally administered in apple juice (0.5 mL/kg of
body weight) 1 h prior to anesthesia. After being admitted to the operating room, the
patient's systolic blood pressure (SBP) and heart rate (HR) were continually monitored with a
multichannel physiologic monitor and the baseline values for SBP and HR were recorded. Thirty
min before the intubation attempt, the nasal mucosa of both nostrils were anesthetized with a
topical vasoconstrictor (0.05% xylometazoline spray, and 2% lidocaine 1 mL two times in each
nostril) (9) to attenuate cardiovascular responses and adverse events in all children.
Anesthesia was induced with 8% sevoflurane with eight deep breaths via a face mask, and the
patient was maintained on 4% end-tidal sevoflurane, fentanyl 2 µr/kg and rocuronium 0.6
mg/kg. NTI was achieved 2 min after rocuronium injection. The more patent nostril was
selected for intubation. An experienced anesthetist performed all intubations in the study
and an assistant applied the maneuvers (jaw trust) and evaluated the patient during the
postoperative visits. All NTIs, both DLS and FOB, were conducted by the same experienced
anesthetist (the anesthetist had performed DLS and the FOB nasal intubation in more than 150
patients, including in at least 100 children before the study). A study nurse documented the
anesthetic data and timing. In the DLS group, the spiral tube was inserted into the nose and
intubated with a Macintosh laryngoscope according to conventional procedures using Magill
forceps. In the FOB group, NTI was conducted using an FOB with an outer diameter of 3.1 mm
through the selected clear nasal passage with a spiral tracheal tube. The appropriate size of
the tracheal tube for a child was determined with the following formula (10): Internal
diameter (mm) = age/3 + 3.5 in both groups. The same type of tube was used in each group.
Before intubation, enough lidocaine gel was placed on the tracheal tube, and the FOB was
guided into patients with a suitable spiral tracheal tube. All tracheal tubes were cuffed and
heat-softened in warm normal saline and lubricated to reduce mechanic stimuli to airway
structures. During the intubation, the head of the patient was the in supine position, and an
assistant applied a jaw thrust for opening the nasopharyngeal passage and improved the image
in all patients in the FOB group. If indicated (a suboptimal laryngeal view or resistance in
passing of the tracheal tube), anterior laryngeal pressure and tongue withdrawal by digital
traction was performed to improve the laryngeal field of view. When the glottis was clearly
visible, the FOB was advanced through the vocal cords, and jaw thrust movement was released.
To prevent the stimulation of the carina, the tube was placed 4 cm below the glottis, sliding
over the FOB. Intubation was verified with the FOB, and end-tidal CO2 concentrations at 35-40
mmHg were monitored. A throat pack was inserted by the anesthetist after the measurements
were taken. Anesthesia was maintained with 2% sevoflurane and 50% N20 in oxygen with 1.5 l
min-1 fresh gas flow and 35-40 mmHg end-tidal CO2 concentrations. Isolyte-P was administered
at rate of 15 mL/kg/h IV, and acetaminophen (15 mg kg-1) was infused for postoperative
analgesia in all children.
SBP and HR were recorded at baseline, after induction of anesthesia, at the time of
intubation, and 1, 3 and 5 min after intubation. The intubation time (the time from when
manual ventilation with a facemask stopped to restarting ventilation via the nasotracheal
tube and when carbon dioxide (CO2) was detected by capnography) was recorded by another
anesthetist with a digital stopwatch. Nose bleeding after intubation (epistaxis),
laryngospasms, bradycardia (HR<65 beat min-1), hypoxic episodes (SpO2<90%) and the surgery
type were also recorded. Adverse events (hoarseness, sore throat) were assessed 24 h after
surgery. If a sore throat developed, additional analgesics were not administered. If
bradycardia or desaturation (SpO2<90%) occurred for more than 2 min, the intubation was
interrupted, and patients were ventilated with 100% oxygen and were administered IV atropine
(5-10 µg / kg).
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