16.1.1 Myringotomy and Tubes (M&T)

Abnormal function of the eustachian tubes is common in children and may lead to otitis media with effusion (OME), or ‘glue-ear’. Small ventilation tubes, or grommets, are placed through the tympanic membrane to ventilate the middle ear and prevent hearing loss and speech delay. It is uncomplicated surgery lasting 10–15 min, with anesthesia using a LMA or facemask. Nitrous oxide is safe to use. The ears may be sore for a short time after surgery, and analgesia is required or the child may wake up distressed. Paracetamol with or without a small dose of opioid is usually sufficient for analgesia. Some anesthetists do not obtain intravenous (IV) access during anesthesia for M&T insertion. Proponents argue this saves time and avoids ‘handing over’ the airway while the IV is inserted. Analgesia is either omitted, given orally preoperatively, or with intranasal fentanyl intraoperatively. The obvious risk of this approach is the inability to administer IV drugs in an emergency, and prevention of emergence delirium is limited to fentanyl. It seems difficult to justify this risk when IV insertion only takes a matter of seconds in skilled hands.

16.1.2 Myringoplasty and Tympanoplasty

Myringoplasty is the repair of a chronic perforation of the tympanic membrane. Tympanoplasty is a more extensive repair that may include surgery to the middle ear bones. The surgical approach for both procedures is either transcanal or via an incision behind the ear. Anesthetic considerations include minimizing bleeding that may obscure the operative field and prevention of nausea and vomiting. Nitrous oxide may lift the graft off the tympanic membrane and should be discussed with the surgeon.

16.1.3 Cochlear Implant

Cochlear implant surgery can be life changing for children with severe sensorineural deafness by restoring hearing, speech development and communication. Electrodes run from a receiver under the soft tissue behind the ear through the mastoid and into the cochlea. These patients may have an underlying syndrome associated with their sensorineural deafness (such as Treacher Collins syndrome and Klippel-Feil anomaly), which may be associated with airway difficulties. Facial nerve monitoring is used during surgery, and the child is either intubated without a muscle relaxant or using a short-acting relaxant. TIVA is commonly used to help maintain tight blood pressure control and to reduce bleeding, and nausea and vomiting (PONV). Small doses of opioid and local infiltration by the surgeon achieve analgesia.

16.2.1 Obstructive Sleep Apnea

OSA is characterized by severely reduced or obstructed airflow during sleep caused by abnormal upper airway anatomy. The symptoms of OSA in children are different to adults. OSA is discussed further in Chap. 11, Sect. 11.​8. In summary however, there are three broad causes of OSA in children. The first is soft tissue occupying the limited space in the upper airway, most commonly adenotonsillar hypertrophy, but also a large tongue in Trisomy 21. Secondly it is caused by hypotonia or discoordination of the pharyngeal muscles, and finally by bony abnormalities in craniofacial syndromes. The cause is frequently a combination of these three factors, for example a child with Robin sequence has a reduced airway size from micrognathia, but also has tonsillar hypertrophy of a degree that might not be a problem in a normal-sized airway.

OSA is common in preschool-aged children because their tonsils and adenoids are large relative to the size of their airway. Adenotonsillectomy is the initial treatment for OSA in children, and improves sleep study parameters, behavior and quality of life in both obese and non-obese children. Non-surgical treatment for OSA includes noninvasive ventilation during sleep, and nasal steroid sprays to reduce inflammation of the adenoids. The ENT surgeon usually diagnoses OSA clinically, and not all children require a sleep study to confirm the diagnosis before tonsillectomy. There is no consensus however, on which sub-group of children need a pre-operative sleep study. Typical criteria include suspicion of severe OSA, presence of a craniofacial syndrome, morbid obesity, neuromuscular disorders and young age. In addition, children who are a high anesthetic risk (such as those with cardiac or pulmonary disease) should have a pre-operative sleep study, as a normal result might avoid surgery.

Very rarely, children with severe OSA and co-morbidities (such as morbid obesity or a craniofacial syndrome) may have chronic hypoxia and hypercarbia with a reduced ventilatory response to both. This is rare in modern practice, and screening with ECG or CXR is not warranted unless there are clinical signs of cardiac dysfunction or unusually long-standing and untreated severe OSA. These children may be polycythemic with pulmonary hypertension and right ventricular hypertrophy. The presence of polycythemia and a right ventricular strain pattern on ECG (increased P wave lead 2 and large R wave V1) would suggest a sleep study and echocardiogram should be performed. In very severely affected children with pulmonary hypertension secondary to OSA, a brief period of non-invasive ventilation (BIPAP) may optimize them preoperatively.

16.2.2 Anesthesia Technique

16.2.2.1 Airway Management

In many centers, endotracheal intubation is the routine airway of choice, but elsewhere the LMA is routinely used with endotracheal intubation reserved for small children and others at higher risk of airway obstruction during surgery.

Endotracheal Intubation

A south-facing oral RAE tube is used for intubation in tonsillectomy. In small children, intubation can be achieved without the use of muscle relaxants (using a bolus of propofol after inhalational induction instead), although in larger children a small dose of relaxant (such as 0.25 mg/kg of atracurium) may be required to optimize intubating conditions. The ETT sits in the midline between the blade of the mouth gag and the tongue and gives a secure airway unlikely to be displaced and does not impede the operative field. Throat packs are not used as they obscure the surgical view, although the surgeon may place a gauze swab above the vocal cords to limit air leak if an uncuffed ETT is used. One must consider if the advantages of intubation (better surgical access in a shared airway, more definitive airway securement) outweigh some of the disadvantages (risks of intubation, time taken for airway instrumentation for an often high-turnover list). Occasionally a malpositioned or incorrectly sized surgical gag can obstruct the ETT after insertion, and it is best to test ventilate following the gag insertion and before commencing surgery.

Laryngeal Mask Airway

Flexible, reinforced LMAs are often used instead of ETTs. Their advantages and disadvantages are listed in Table 16.3. Their main advantage is they are fast to insert and can be left in situ for awake removal in recovery. Their biggest disadvantage is they may dislodge or kink and become obstructed when the gag is inserted or opened. As a general rule, children less than 15 kg are more difficult to manage using an LMA, as tightening of the surgical gag tends to obstruct or dislodge the LMA. LMAs also reduce the ability for recruitment maneuvers, which may be particularly important in small children who are more at risk of atelectasis due to their small airways and often baseline chronic respiratory tract infections.

Table 16.3

Advantages and disadvantages of airway management using the LMA during tonsillectomy in children

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