INTRODUCTION — Obstructive sleep apnea (OSA) is common in the pediatric population. If untreated, the disease has been associated with a wide range of cardiovascular and cognitive morbidities [1-3]. Surgical removal of the tonsils and adenoids is considered the first-line treatment for OSA in otherwise healthy children over two years of age with adenotonsillar hypertrophy, as recommended in guidelines from the American Academy of Pediatrics (AAP) and the American Academy of Otolaryngology-Head and Neck Surgery (AAO-HNS) [4,5].
Adenotonsillectomy is one of the most common surgical procedures performed on children in the United States, with approximately 300,000 ambulatory procedures performed annually in children 15 years or younger [5,6]. In a survey of practice patterns by otolaryngologists in the United States, non-mutually exclusive indications for surgery included obstructed breathing of any type in 59 percent of cases, recurrent infections in 42 percent, and OSA in 39 percent of children, which indicates that obstructed breathing rivals recurrent infection as the most common surgical indication for adenotonsillectomy [7].
Although the majority of children undergoing adenotonsillectomy for SDB benefit from the procedure [8], the risk of complications or persistent disease after surgery mandates careful consideration of the risk-benefit ratio of surgical intervention for each individual patient. Moreover, children undergoing adenotonsillectomy for SDB should be evaluated postoperatively for symptom resolution to determine the need for additional evaluation or treatment [4].
PEDIATRIC SLEEP-DISORDERED BREATHING AND OBSTRUCTIVE SLEEP APNEA
Definitions
●Obstructive sleep-disordered breathing (SDB) includes a range of nocturnal breathing abnormalities, ranging from habitual snoring to frank OSA. Obstructive SDB is generally suspected initially based on symptoms and signs.
●OSA is defined as periodic episodes of nocturnal airflow restriction (hypopneas) or obstruction (apneas) in association with sleep disruption, arousals from sleep, oxygen desaturation, and possible hypercapnia [4]. A polysomnogram (PSG, also known as a sleep study) is required for a definitive diagnosis of OSA.
The broad term "SDB" also encompasses nonobstructive causes of sleep-related breathing disorders, such as sleep-related hypoventilation disorders and central sleep apnea syndromes. In this topic review we will use the term "obstructive SDB" to describe signs and symptoms of nocturnal airway obstruction, with or without confirmation of OSA on PSG. For example, the term "obstructive SDB" as used here could include a child who snores and has hyperactive behavior during the day, but his or her PSG would not show, or does not show OSA.
Prevalence — Obstructive SDB is exceedingly common in the pediatric population. Peak incidence is between two and eight years of age, likely due to the size of lymphoid tissue relative to airway diameter. Reports of the prevalence of primary snoring in children range from 4 to 12 percent [9-12]. A systematic review of epidemiologic studies found an overall prevalence of caregiver-reported snoring by any definition of 7.45 percent [13]. Prevalence estimates for PSG-documented OSA in the general pediatric population have consistently ranged from 1 to 5 percent, based on cross-sectional studies [13-15].
High-risk populations — Children with obesity (especially if severe) are far more likely than lean children to have OSA, with reports of prevalence that range from 13 to 59 percent [11,13,15,16]. Children with congenital syndromes, craniofacial abnormalities, and/or neuromuscular disorders also have a significantly higher risk for OSA than those without, with prevalence estimates of 30 to 100 percent in Down syndrome, 15 percent in cerebral palsy, 85 percent in Pierre-Robin sequence, and over 50 percent in children with achondroplasia [17-22]. Micrognathia or midfacial hypoplasia are important predictors of OSA in infants, but isolated cleft palate probably is not. In a small prospective cohort study, infants with isolated cleft palate (confirmed by cephalometric findings) had similar polysomnographic findings compared with controls [23]. Children and adolescents with sickle cell disease have reduced upper airway diameters and increased adenoid and tonsil size (known risk factors for OSA) compared with normal volunteers [24]. Somewhat increased prevalence of OSA also has been reported in African-American children and in children with a history of prematurity compared with the general population. (See "Evaluation of suspected obstructive sleep apnea in children", section on 'Risk factors' and "Mucopolysaccharidoses: Clinical features and diagnosis" and "Overview of the pulmonary complications of sickle cell disease", section on 'Sleep-disordered breathing'.)
SCREENING AND REFERRALS — Obstructive sleep-disordered breathing (SDB) is an important cause of morbidity in children. Untreated OSA may lead to growth failure, cognitive and behavioral abnormalities, and cardiovascular effects including cor pulmonale, right and left ventricular dysfunction, and systemic hypertension [1,2,9,25-28]. Less severe forms of obstructive SDB such as primary snoring (snoring in the absence of OSA) have also been associated with decreased cognitive skills, diminished quality of life, and behavioral disturbances in children [4,28-31].
Initial screening — Because obstructive SDB is common and is an important cause of morbidity, all children should be screened for SDB as part of routine health care. The American Academy of Pediatrics (AAP) recommends the following steps at each well child visit [4]:
●Ask the caregiver if the child snores and, if so, whether this is habitual (most nights), or only intermittent, and whether the snoring is loud.
●If habitual or unusually loud snoring is reported, determine whether any of the following signs or symptoms are present:
•Adenotonsillar hypertrophy (picture 1)
•Obesity (especially if severe)
•Mouth breathing
•Long ("adenoidal") facies (figure 1)
•Micrognathia, macroglossia, or other craniofacial abnormalities
•Hypertension
•Morning headaches
•Witnessed apneic episodes or gasping while sleeping, or "restless" sleep
•Poor school function or daytime behavioral concerns (hyperactivity, sleepiness, or irritability)
Referral to an otolaryngologist or sleep specialist — If the child has snoring and one or more of these signs or symptoms, consider referral to an otolaryngologist (ear, nose, and throat specialist) or sleep specialist for further evaluation. Existing literature does not indicate which referral serves best. If polysomnography (PSG) is indicated, this can be arranged by the specialist. Alternatively, the referring provider may be able to arrange for a PSG if a facility with experience in pediatric PSG is available; children with abnormal results of PSG or other significant sleep problems can then be referred to the appropriate specialist. (See 'Polysomnography' below.)
Referral to a tertiary care facility — Referral to a tertiary care center, or to a pediatric rather than a general otolaryngologist (where available), should be considered for children with additional risk factors for complications of adenotonsillectomy. These include:
●Severe sleep apnea (eg, PSG showing apnea-hypopnea index [AHI] ≥24 events per hour, oxygen saturation nadir of <80 percent, or peak PCO2 of ≥60 mmHg).
●Difficult-to-manage airway due to anatomical abnormalities (eg, syndromes or congenital anomalies).
●Increased potential for postoperative complications due to factors including severe obesity, very young age (eg, <24 months), craniofacial syndromes, neuromuscular disorders, coagulopathies, or other significant medical comorbidities.
In these cases, pediatric specialists and anesthesiologists or admission to a pediatric intensive care unit (PICU) for monitoring may be indicated [5].
EVALUATION BY THE SPECIALIST
Evaluation for obstructive sleep apnea
History and physical examination — The physical examination by the specialist includes evaluation of tonsil size and adenoidal tissue. Tonsillar size is most often described on a scale from 0 to 4+ (figure 2) [32]:
●0 – Tonsils are entirely within the tonsillar pillar or previously removed by surgery
●1+ – Tonsils occupy 0 to 25 percent of the posterior pharynx
●2+ – Tonsils occupy 26 to 50 percent of the posterior pharynx
●3+ – Tonsils occupy 51 to 75 percent of the posterior pharynx
●4+ – Tonsils occupy 76 to 100 percent of the posterior pharynx (picture 2)
Indirect mirror examination of the nasopharynx and adenoid pad is often difficult in children. Transnasal fiberoptic laryngoscopy can be used as needed to assess adenoid size and the posterior or inferior extent of the pharyngeal tonsils, and can also identify other anatomical abnormalities such as lingual tonsillar hyperplasia or laryngomalacia. This procedure can generally be performed on awake children in the arms of their caregiver without sedation.
The child should be examined for a submucous cleft palate, which may be accompanied by a bifid uvula, midline deficiency or absence of muscular tissue, or a palpable notch in the hard palate. Children in whom submucous cleft of the palate is detected or those in whom velopharyngeal insufficiency is suspected should undergo additional evaluation by a specialist or a team skilled in cleft palate evaluation and management. In these children, limited or superior adenoidectomy can be performed in order to minimize the risk of velopharyngeal insufficiency.
Although history and physical examination are important components of the preoperative evaluation, they are not sufficient to confirm or exclude the diagnosis of OSA in children. Caregiver reports of snoring and tonsillar size have high sensitivity but low specificity for OSA, whereas daytime somnolence or observed apneas have high specificity but low sensitivity [33]. Furthermore, a systematic review concluded that there is only a weak association between tonsil size (as evaluated by the physical examination) and OSA severity (as measured by polysomnography [PSG]) in the pediatric population [34]. Accordingly, in a systematic review, only 55 percent of children with suspected OSA on clinical evaluation subsequently had the disease confirmed when PSG was performed [35].
Questionnaires designed to assess nocturnal and daytime symptoms in children with suspected sleep-disordered breathing (SDB) are not sufficiently accurate to replace PSG in the clinical evaluation [36-39]. However, some questionnaires predict PSG results to an extent that is useful for clinical research, and other questionnaires may be useful to assess for OSA-related behavioral disturbance and poor quality of life, and thereby help to determine the need for additional evaluation and support. At least two studies suggest that a pediatric OSA symptom inventory may predict some key outcomes of adenotonsillectomy more effectively than PSG [37,40]. (See "Evaluation of suspected obstructive sleep apnea in children", section on 'Questionnaires'.)
Polysomnography — Attended in-laboratory nocturnal PSG (overnight PSG) is considered the gold standard for diagnosis of OSA in children, as it is the only method able to definitively identify the presence of obstructive events and quantify the severity of OSA, including gas-exchange abnormalities and sleep disruption.
●Higher-risk children – We suggest PSG prior to adenotonsillectomy for children with conditions that increase the risk of perioperative respiratory complications. These conditions include children <2 years of age and children with obesity (especially if severe), Down syndrome, craniofacial abnormalities, neuromuscular disorders, sickle cell disease, or mucopolysaccharidoses (table 1) [4,5,41]. The purpose of the PSG in these children is to improve diagnostic accuracy in high-risk populations and define the severity of OSA to optimize perioperative planning.
●Standard-risk children – For all other children, the necessity of preoperative PSG is controversial. Guidelines from the American Academy of Pediatrics (AAP) recommend that all children undergo PSG if this service is readily available but acknowledge that alternative testing or referral to a specialist can be substituted [4]. By contrast, guidelines from the American Academy of Otolaryngology-Head and Neck Surgery (AAO-HNS) recommend PSG only if there is discordance between tonsil size and the reported severity of SDB symptoms [41].
The controversy arises from several recognized limitations of PSG: PSG has never been validated as a reliable tool to predict the risk of adverse outcomes of SDB or response to treatment [42]. There is also often a disparity between PSG measures and the severity of clinical symptoms. Children with severe daytime and nighttime symptoms may have a normal PSG, and snoring and symptoms of SDB have been associated with cognitive and behavioral abnormalities even in the absence of documented OSA on PSG [29-31]. Conversely, snoring children who are otherwise asymptomatic occasionally have severe respiratory disturbances on PSG [30]. Children with symptoms and signs of OSA, but negative PSGs, may still benefit from adenotonsillectomy [30]. Finally, pediatric PSG is expensive, labor-intensive, requires specially trained personnel, and may not be readily available in all areas.
In view of these limitations, it is not a surprise that the use of PSG to confirm OSA prior to surgical intervention in clinical practice is somewhat selective, especially by otolaryngologists. In a 2004 practice pattern survey of pediatric otolaryngologists, 75 percent of respondents reported that they requested PSG in less than 10 percent of otherwise healthy children presenting with symptoms of SDB prior to performing adenotonsillectomy [43]. An updated internet practice survey conducted in 2017 showed that only 10 percent of pediatric otolaryngologists frequently referred children with SDB for PSG before performing adenotonsillectomy, 64 percent sometimes referred them, and 27 percent rarely or never referred them [44].
Other diagnostic testing for OSA — If attended in-laboratory nocturnal PSG is not available, clinicians may consider alternate diagnostic tests including home sleep apnea tests, which are increasingly used in adults but are not adequately validated in children [45]. Other alternatives to in-laboratory PSG include "nap" PSG, overnight continuous pulse oximetry, or audio and video monitoring. All of these tests have a low negative predictive value, indicating that a negative result is insufficient to exclude OSA [46]. (See "Evaluation of suspected obstructive sleep apnea in children", section on 'Alternatives to polysomnography' and "Overview of polysomnography in infants and children", section on 'Alternative studies'.)
SURGICAL CONSIDERATIONS
Indications for surgery — The decision to initiate treatment for obstructive sleep-disordered breathing (SDB) is made on a case-by-case basis. Important considerations include severity of symptoms, the child's age, polysomnographic (PSG) abnormalities, and any underlying medical comorbidities or OSA-related complications. Treatment decisions for children with OSA are discussed in more detail in a separate topic review. (See "Management of obstructive sleep apnea in children", section on 'Choice of therapy'.)
Adenotonsillectomy is generally considered first-line therapy for otherwise healthy children who have moderate or severe OSA and adenotonsillar hypertrophy. Adenotonsillectomy may also be initial therapy for children with multifactorial OSA, including contributions from obesity, if appreciable adenotonsillar tissue is present. OSA in obese children usually improves following adenotonsillectomy, although the outcome may be less satisfactory than in lean children. Finally, adenotonsillectomy should be considered in a child with OSA who does not have clear adenotonsillar hypertrophy. This is because in these circumstances the lymphoid tissue can still occupy a significant proportion of the potential upper airway.
Children with Down syndrome, craniofacial anomalies, neuromuscular disorders, or mucopolysaccharidoses typically have multifactorial OSA, with airway obstruction at multiple sites. They are therefore more likely to have respiratory complications in the perioperative period, and to have persistent OSA after adenotonsillectomy, as discussed below. Nonetheless, adenotonsillectomy is often the most appropriate initial therapy for these children if appreciable adenotonsillar tissue is present, and usually leads to improvement in OSA, even if the OSA does not fully resolve [47,48]. Medical therapy and/or adjuvant surgical procedures are used as alternatives or supplements to adenotonsillectomy, depending on the severity and specific locations of airway obstruction in the individual patient, and on associated comorbidities. (See 'Risk factors for persistent disease' below and 'Management of patients with residual OSA after adenotonsillectomy' below.)
Relative contraindications to adenotonsillectomy include little or no adenotonsillar tissue, submucous cleft palate, a bleeding disorder that cannot be adequately controlled for surgery, or other underlying disorders that render the patient medically unstable for surgery [4].
Alternatives to adenotonsillectomy:
●Watchful waiting for several months may be an acceptable alternative for otherwise healthy children with mild or moderate OSA without significant oxygen desaturation and with tolerable symptoms. If this approach is chosen, the child should be reevaluated within six months for worsening of clinical symptoms. (See "Management of obstructive sleep apnea in children", section on 'Choice of therapy'.)
●Positive airway pressure therapy can be used when adenotonsillectomy is contraindicated (eg, due to comorbid diseases that increase the risk of surgery). It can also be employed when a patient with OSA has minimal adenotonsillar tissue, persistent OSA despite adenotonsillectomy, or a strong preference for a nonsurgical approach. (See "Continuous positive airway pressure (CPAP) for pediatric obstructive sleep apnea", section on 'Treatment decisions'.)
●Weight loss is recommended as an adjunctive therapy for obese children with OSA because obesity contributes to the increased upper airway resistance. However, adenotonsillectomy also should be considered if adenotonsillar hypertrophy is present.
●Other interventions for selected children with OSA include rapid maxillary expansion (RME), corticosteroids/antiinflammatory therapy, and positional therapy. (See 'Rapid maxillary expansion' below and "Management of obstructive sleep apnea in children", section on 'Adjunct therapies'.)
Preoperative assessment — The history should explore symptoms of unusual bleeding or bruising, or a family history of bleeding disorders.
Routine preoperative laboratory testing and cardiac evaluation are not necessary unless the patient has specific risk factors. (See "Tonsillectomy and/or adenoidectomy in children: Preoperative evaluation and care", section on 'Hematologic evaluation' and "Tonsillectomy and/or adenoidectomy in children: Preoperative evaluation and care", section on 'Cardiac evaluation'.)
If PSG was not already performed for diagnostic purposes, it is recommended as part of preoperative planning for patients with conditions that increase the risk for respiratory complications, including severe obesity, Down syndrome, craniofacial abnormalities, neuromuscular disorders, sickle cell disease, or mucopolysaccharidoses, as discussed above (see 'Polysomnography' above). When severe OSA is suspected clinically, PSG documentation of severity is sometimes used to justify overnight admission after surgery rather than same-day discharge. This is because of increased risk for postoperative respiratory complications in patients with severe OSA. (See 'Operative setting' below.)
Children with the following disorders require additional evaluation and disease-specific management (see "Tonsillectomy and/or adenoidectomy in children: Preoperative evaluation and care", section on 'Preoperative care in specific patient populations'):
●Bleeding disorders (eg, von Willebrand disease or platelet function defects).
●Sickle cell disease – Because of risk for complications including acute chest syndrome in the perioperative period.
●Down syndrome – To assess for hypothyroidism and manage anesthesia-related respiratory complications. Children with Down syndrome are also at risk for atlantoaxial instability.
Operative setting — For the majority of children, adenotonsillectomy can be safely performed in an ambulatory setting. Reasons for overnight hospitalization after tonsillectomy may include a complex medical history, a history of severe OSA (defined in this case as an apnea-hypopnea index [AHI] of >10, oxygen saturation nadir less than 80 percent, or both), or age younger than three years [5,41]. For children younger than three years whose OSA is not severe and who have no other risk factors, complication rates are low and the need for inpatient admission has been questioned [49]. (See "Tonsillectomy (with or without adenoidectomy) in children: Postoperative care and complications", section on 'Setting of care'.)
Guidelines and clinical practice vary regarding indications for performing adenotonsillectomy in a tertiary care setting and for postoperative admission to a pediatric intensive care unit (PICU) or extended observation in a postanesthesia care unit (PACU). These precautions are usually recommended for children with very severe OSA, very young children (eg, <24 months), cardiac complications of OSA, failure to thrive, severe obesity, craniofacial or chromosomal anomalies, neuromuscular disorders, or current upper respiratory infections [5,46,50]. However, the threshold for defining very severe OSA varies. Suggested criteria include AHI ≥24; rapid eye movement (REM) AHI ≥60 [51]; and/or oxygen saturation nadir <70 percent [52].
Perioperative medications — Perioperative medications, including the use of dexamethasone to prevent postoperative nausea, and pain management are discussed in a separate topic review. (See "Anesthesia for tonsillectomy with or without adenoidectomy in children", section on 'Antiemetics' and "Anesthesia for tonsillectomy with or without adenoidectomy in children", section on 'Analgesia'.)
The use of antimicrobial prophylaxis at the time of, or for short periods following, adenotonsillectomy does not improve postoperative outcomes and is not recommended [5,53]. (See "Tonsillectomy (with or without adenoidectomy) in children: Postoperative care and complications", section on 'No role for antimicrobial prophylaxis'.)
Surgical techniques — A variety of instruments have been devised for the removal of tonsillar and adenoid tissue. Traditionally, the most common approach has been extracapsular (complete) tonsillectomy, but intracapsular (partial) tonsillectomy is increasingly used.
Extracapsular tonsillectomy — Extracapsular tonsillectomy (also known as complete, total, or sub-capsular tonsillectomy) consists of removal of the entire palatine tonsil and the surrounding fascia or capsule with either cold or hot techniques (figure 3 and picture 1).
●For "cold" or sharp dissection, the mucosa is sharply excised from the tonsillar pillar with a scissor or scalpel and then blunt instruments are used to divide the tonsillar capsule from the underlying musculature. Hemostasis is then achieved with a combination of pressure, cautery, ligation, or hemostatic agents.
●For "hot" techniques, electrosurgical or thermal instruments are utilized to excise the tonsillar tissue (movie 1). A variety of instruments and technologies have been developed for this purpose including monopolar electrocautery (Bovie), lasers, diathermy, bipolar electrosurgical scissors or forceps, and bipolar radiofrequency ionic dissociation. Hot techniques allow for simultaneous cauterization of blood vessels and enable surgeons to perform the procedure quickly and with minimal blood loss in most cases.
Each of these approaches has advantages. Hot techniques allow for simultaneous cauterization of blood vessels and enable surgeons to perform the procedure quickly and with minimal blood loss in most cases. On the other hand, some studies have shown that use of cold dissection and radiofrequency techniques are associated with less pain and more rapid return to normal function. As an example, a systematic review comparing cold dissection with diathermy tonsillectomy in 254 patients found that the diathermy group had reduced intraoperative bleeding, but increased pain [54]. Therefore, no current clinical guidelines advocate for use of any one specific surgical technique for extracapsular tonsillectomy over others, and the decision is generally based on surgeon preference and training [55].
Intracapsular tonsillectomy (tonsillotomy) — Intracapsular tonsillectomy (also known as subtotal or partial tonsillectomy, or "tonsillotomy") is increasingly used for the treatment of obstructive SDB. In this technique, microdebriders, bipolar electrosurgical scissors, or radiofrequency ablation (including "coblation") devices are used to debulk the obstructing portions of the tonsil parenchyma [56-58].
Limited evidence suggests that the tonsillotomy technique permits more rapid recovery compared with traditional tonsillectomy and possibly reduces the risk of postoperative complications including hemorrhage, as suggested by three meta-analyses [59-61]. However, tonsillotomy also may be associated with a greater risk of tonsillar regrowth, which usually is clinically insignificant but occasionally requires revisional surgery. In view of these potential benefits and uncertainties, intracapsular tonsillectomy is sometimes used for surgical treatment of obstructive SDB in children. In a practice pattern survey of pediatric otolaryngologists in the United States, 73 percent of surgeons reported always performing complete extracapsular tonsillectomy for a surgical indication of SDB [62].
●Recovery time – The evidence that this technique permits more rapid recovery comes from multiple randomized trials of adenotonsillectomy techniques for children with SDB. As an example, a randomized study with 156 patients compared treatment with intracapsular tonsillectomy with microdebrider, intracapsular tonsillectomy with coblation, and traditional extracapsular tonsillectomy with electrocautery dissection [63]. Patients undergoing intracapsular tonsillotomy with either coblation or microdebrider returned to a normal diet and activity between one and two days earlier than those undergoing extracapsular tonsillectomy, and the subgroup using coblation required pain medication for two days fewer than patients in the other groups. There were no statistically significant differences in postoperative complications between the three techniques.
●Postoperative complications – Rates of postoperative complications including hemorrhage may be lower after intracapsular tonsillectomy performed for airway obstruction compared with extracapsular tonsillectomy. This was shown in the above meta-analyses [59-61], although a separate review found no difference in postoperative hemorrhage or dehydration among high-quality studies [64]. In a large registry study from Sweden, children who underwent intracapsular tonsillectomy, in comparison with extracapsular tonsillectomy, had substantially lower risk of hospital admission for postoperative hemorrhage (0.6 versus 2.5 percent) [65].
●Tonsillar regrowth – Reported rates of tonsillar regrowth or symptom recurrence after intracapsular tonsillectomy range from 0.5 to 16.6 percent, which is of particular concern when the technique is used for treatment of SDB [66-69]. The regrowth can be clinically significant. As an example, one study reported regrowth in 7 of 42 children after intracapsular tonsillectomy (16.6 percent), and 5 of these children required revision tonsillectomy (12 percent overall) [68]. In a randomized trial of intracapsular tonsillectomy versus extracapsular tonsillectomy for OSA, 5 of 39 (13 percent) of children who underwent intracapsular tonsillectomy for OSA needed repeat surgery for regrowth and recurrence of OSA, compared with 0 of 40 children who underwent extracapsular tonsillectomy [69]. Two meta-analyses also found that symptom recurrence was more common among children undergoing intracapsular tonsillectomy compared with extracapsular tonsillectomy [59,60].
Longitudinal cohort studies have found that tonsillotomy results in reoperation specifically on the tonsils in 3.9 percent of children within three years [70]. Overall, the risk of regrowth requiring reoperation in the cohort was seven times higher for tonsillotomy than for tonsillectomy [71]. This is strongly age dependent, with the highest rates of reoperation in children less than four years of age.
Adenoidectomy — During adenoidectomy, the obstructing portions of adenoid tissue are removed from the nasopharynx with the use of ether sharp curettes (sharp or cold dissection), electrocautery, coblation, or microdebrider (picture 3). The procedure is generally done trans-orally after retraction of the soft palate, taking care to avoid trauma to the undersurface of the palate or Eustachian tube orifices. Occasionally, a transnasal approach may be necessary.
Complications of adenotonsillectomy — Children will have throat pain, otalgia, halitosis, and odynophagia for up to two weeks after adenotonsillar surgery until the tonsillar fossae are fully mucosalized. Transient nausea and vomiting are not uncommon, and occasionally require admission for dehydration [72]. Good hydration is associated with decreased postoperative pain, and immediate resumption of oral intake after surgery should be encouraged [73]. Post-tonsillectomy bleeding can occur either within 24 hours (termed early, immediate, or primary hemorrhage) or at any subsequent time (termed delayed or secondary hemorrhage). Primary hemorrhage typically ranges from 0.2 to 2.2 percent and secondary hemorrhage between 0.1 and 3 percent [74]. (See "Tonsillectomy (with or without adenoidectomy) in children: Postoperative care and complications", section on 'Complications'.)
Postoperative respiratory complications are also frequent after adenotonsillectomy and can range from transient laryngospasm or mild desaturation requiring patient repositioning or supplemental oxygen, to life-threatening airway obstruction or pulmonary edema. OSA is an important risk factor for developing postoperative respiratory complications, particularly if the OSA is severe [75]. Other risk factors include cardiac morbidity (due to the OSA or other factors), obesity, craniofacial or neuromuscular disorders, Down syndrome, history of seizures, asthma or prematurity, or recent upper respiratory infections [76]. Children with any of these risk factors should be carefully observed for respiratory complications during the postoperative period. (See "Tonsillectomy (with or without adenoidectomy) in children: Postoperative care and complications", section on 'Respiratory complications'.)
POSTOPERATIVE OUTCOMES
Success rates
Polysomnographic outcomes — PSG outcomes after adenotonsillectomy for children with OSA vary considerably, with reported success rates ranging from 27 to 80 percent, depending on study design and PSG criteria used to define a successful outcome [8,77-79]. The range of PSG outcomes are illustrated by the following studies:
●A randomized trial compared the outcomes of adenotonsillectomy with those of watchful waiting and supportive care (Childhood Adenotonsillectomy Trial [CHAT] trial) [8]. The subjects were 464 children, five to nine years of age with PSG-documented OSA (apnea-hypopnea index [AHI] 2 to 30 events/hour) without significant oxygen desaturation. At seven month's follow-up, 79 percent of children treated with adenotonsillectomy had normalization of PSG findings, compared with 46 percent of the group who did not undergo surgery. Resolution of OSA was less common in children with obesity and higher AHI at baseline. Of note, children with severe OSA and significant comorbidities or syndromes were excluded from this study.
●In a meta-analysis of studies involving over 1000 children who underwent tonsillectomy for OSA, 59 percent had complete normalization of PSG parameters, defined by AHI <1 [79]. The resolution rate was 39 percent in patients with severe obesity or severe OSA, compared with 74 percent in uncomplicated patients.
●In a retrospective multisite study involving 578 children, only 27 percent had resolution of OSA defined by AHI <1, although significant reduction in mean AHI was seen (from 18.2 ± 21.4 to 4.1 ± 6.4 events per hour) [78]. This trial included a higher proportion of children with risk factors associated with residual disease following adenotonsillectomy, including older age, obesity, or more severe OSA at baseline (AHI >5), which may explain the lower rate of resolution.
Symptomatic outcomes
Quality of life — There is moderately good evidence that adenotonsillectomy improves quality of life for children with OSA [80]. The best evidence for short-term improvement is from the randomized CHAT trial described above [8,81]. The group treated with adenotonsillectomy experienced greater improvements in several standardized measures of quality of life and sleep quality, although improvements in OSA severity explained only a small portion of the observed changes. Similarly, a meta-analysis of observational studies found improvements in a disease-specific quality of life survey, and these improvements persisted in longer-term follow-up [82].
Cognitive and behavioral — There is somewhat weaker evidence that adenotonsillectomy may improve cognitive function and behavior in children with OSA. Observational studies have reported postoperative improvements in objective measures of impulsivity, inattention, and cognitive function after adenotonsillectomy [30,83,84], or in behavior reported by parents or caregivers [85]. In the CHAT trial described above, children treated with adenotonsillectomy had improvement in behaviors as reported by caregivers and teachers, but no differences in an objective measure of attention and executive functioning, which was the primary outcome of the trial [8]. (See "Cognitive and behavioral consequences of sleep disorders in children", section on 'Sleep-related breathing disorders'.)
Risk factors for persistent disease — Although adenotonsillectomy improves PSG measures in most children with OSA, a substantial proportion of patients have persistent disease, ranging from 13 to 79 percent depending on the criteria used to define persistent disease and the study population [4]. Recurrence of OSA can also be seen long after adenotonsillectomy, even when initial resolution of disease was achieved. As an example, in a prospective study of 62 children ages 7 to 13 years who underwent adenotonsillectomy for documented OSA, postoperative PSGs were obtained at six weeks, six months, and one year after surgery [86]. A trend toward increasing AHI was seen in the period from six months to one year after surgery; obesity, African American race, and rapid increase in body mass index (BMI) were risk factors for recurrent OSA. In a separate prospective longitudinal study of 135 children undergoing adenotonsillectomy for documented OSA, a worsening of postoperative AHI was seen in 68 percent of children during the 36-month follow-up period [87].
The likelihood of persistent disease is increased in the patients with the following characteristics [48,78,88-92]:
●Obesity
●More severe OSA at baseline
●Craniofacial anomalies, Down syndrome, Prader-Willi syndrome, or mucopolysaccharidoses
The increased rates of persistent disease among children with obesity were demonstrated by a meta-analysis of adenotonsillectomy outcomes in children with obesity [88]. Although most children had improvement in their OSA postoperatively, only one-half had postoperative AHI <5, and one-quarter had postoperative AHI <2. Among children with Down syndrome, 50 to 75 percent have persistent OSA requiring additional therapy [48,93,94].
Weight gain — The relationship between OSA, adenotonsillectomy, and weight gain is complex. In some cases, OSA appears to restrict weight gain in some children, and adenotonsillectomy can reverse the restriction or promote weight gain, at least in the short term [95]. In a retrospective case-control series of 154 children undergoing adenotonsillectomy and 182 controls, those children undergoing surgery gained more weight over the subsequent two years. A statistically significant increase in weight was seen in the obese children after surgery, but not in those who were overweight or of normal weight at baseline [96].
In the CHAT trial, weight gain was also greater in children who had early adenotonsillectomy compared with the observation-only controls [97]. However, this effect was primarily due to catch-up weight gain in children who were underweight or of low-normal weight at baseline; rates of undesirable weight gain in already overweight or obese children were similar between the early adenotonsillectomy and control groups [98,99]. Nonetheless, providers should be aware that overweight and obese children with OSA are at risk for further weight gain whether they are observed or treated and take steps to minimize or reverse this tendency where possible. (See "Definition, epidemiology, and etiology of obesity in children and adolescents", section on 'Sleep' and "Evaluation of suspected obstructive sleep apnea in children", section on 'Examination'.)
INDICATIONS FOR POSTOPERATIVE POLYSOMNOGRAPHY — We recommend a clinical reevaluation of all children several months after adenotonsillectomy to determine whether snoring and other symptoms of SDB have resolved. For those with persistent symptoms or concerns, we suggest proceeding to postoperative PSG. In children with higher risk of persistent disease, such as those with severe baseline OSA, severe obesity, or craniofacial syndromes, a postoperative PSG should be considered even in the absence of snoring or other symptoms [4].
In clinical practice, postoperative testing is generally performed several months after surgery to ensure stable healing of the operative site. No studies to date have evaluated the timing of postoperative PSG evaluation, and this issue is not specifically addressed in practice guidelines regarding management of pediatric OSA.
MANAGEMENT OF PATIENTS WITH RESIDUAL OSA AFTER ADENOTONSILLECTOMY
Diagnostic procedures — Patients with clinically significant OSA after adenotonsillectomy should be further evaluated to determine the site(s) of obstruction and guide further interventions. In most cases, the first step is flexible fiberoptic nasolaryngoscopy, which may identify nasopharyngeal stenosis, lingual tonsillar hypertrophy, or laryngomalacia. If more information is needed, drug-induced sleep endoscopy (DISE) or cine magnetic resonance imaging (MRI) can help to identify specific sites of obstruction.
Drug-induced sleep endoscopy — DISE, also known as drug-induced sedation endoscopy, consists of assessment of the entire airway using a flexible fiberoptic laryngoscope during anesthetically-simulated sleep with preservation of spontaneous respiration. DISE is increasingly used to evaluate site of airway collapse prior to surgical intervention in children anatomically predisposed to multilevel collapse, or in those with persistent OSA after adenotonsillectomy [100-104].
DISE evaluates the extent and orientation of obstruction anatomical sites of potential collapse (adenoids, palate or velum, lateral pharyngeal wall, tongue base, and epiglottis or supraglottis). The scoring systems have substantial intra- and interrater agreement (>0.6), and children with multilevel obstruction tend to have more severe OSA as measured by polysomnography (PSG) [105,106]. In a study of 82 children with mild-severe OSA, DISE revealed oropharyngeal and lateral wall collapse in most patients (72 of 82), and the majority had obstruction at multiple sites [107]. In a separate study in 56 children with either persistent OSA following adenotonsillectomy or infant OSA, DISE-directed surgery at any of several potential sites of obstruction led to significant improvements in the apnea-hypopnea index (AHI) [104]. After DISE-directed surgery, mean obstructive AHI (oAHI) decreased from 14.9 to 10.3 events per hour. Postoperatively, 54 percent of the children had oAHI <5, and 16 percent had oAHI <1.
Increasing evidence suggests that DISE may also be a useful tool prior to any type of surgical intervention for children with OSA who are considered at high risk for persistent disease after adenotonsillectomy due either to syndromes (trisomy 21, craniofacial conditions, or neuromuscular disorders with hypotonia) or other risk factors such as age >7 years, small tonsils, obesity, or severe baseline OSA. In a group of 62 surgically naïve children whose type of surgical intervention was determined by DISE, an intervention other than adenotonsillectomy was performed in 58 of the patients [108]. DISE-directed surgery was successful in reducing the total number of obstructive respiratory events in 79 percent of subjects, and postoperative obstructive AHI was mild (<5) in 61 percent of patients in this high-risk group. Larger studies are needed to better evaluate the success and utility of DISE-directed surgery to address OSA in children.
Magnetic resonance imaging — Cine magnetic resonance imaging (MRI) is done under sedation and allows for three-dimensional analysis of the upper airway. This technique is useful for surgical planning in children in whom multiple sites of obstruction are suspected due to obesity, craniofacial syndromes, or neuromuscular disorders, or in children with persistent OSA after adenotonsillectomy [109,110]. As an example, in a group of 27 patients with Down syndrome and persistent OSA after adenotonsillectomy, cine MRI identified multiple sites of anatomical collapse, including glossoptosis and recurrent adenoid tissue (each in 63 percent of patients), hypopharyngeal collapse (22 percent), lingual tonsillar hypertrophy (30 percent), and macroglossia (74 percent) [111].
Nonsurgical therapeutic options
Watchful waiting — In children with mild residual OSA after adenotonsillectomy but few or no symptoms, continued observation may be appropriate, as suggested by data on watchful waiting for children who have not had surgery. Asymptomatic children with mild residual OSA after adenotonsillectomy may not require active intervention. (See "Management of obstructive sleep apnea in children", section on 'Choice of therapy'.)
Weight loss — There is good evidence that weight loss can reduce OSA severity in obese adults [112], but limited evidence in children.
Several studies in obese children and adolescents suggest that OSA is likely to improve with weight loss. In a study of 31 obese teenagers in a residential weight loss program, 62 percent had resolution of obstructive symptoms after a median weight loss of 24.0 kg, prompting a conclusion that weight loss was a successful treatment option for OSA in obese teenagers [113]. This is supported by a study of 34 obese teenagers undergoing weight loss surgery, of whom 19 children had moderate OSA (AHI >5) preoperatively. Of the 10 children for whom postoperative PSG data were available, the mean AHI decreased from 9.2 to 0.62 events/hour [114]. Given the strong association between obesity and OSA in children, children with obesity and residual OSA after adenotonsillectomy should be encouraged to lose weight and offered support to assist these efforts. Weight loss surgery may also be an option for adolescents with severe obesity and OSA and/or other obesity-associated morbidities [115].
Medical therapy — Intranasal corticosteroids or leukotriene modifier therapy have been used primarily to treat mild OSA as an alternative to adenotonsillectomy or continuous positive airway pressure (CPAP) therapy. Medication use in children with OSA who have not undergone adenotonsillectomy is discussed separately [116-118]. (See "Management of obstructive sleep apnea in children", section on 'Intranasal corticosteroids or montelukast'.)
These medical therapies may also be helpful in children with mild residual OSA after adenotonsillectomy, especially if concurrent nasal obstruction is present. In one study, children with mild residual OSA after adenotonsillectomy experienced modest improvement after treatment with the combination of montelukast and intranasal budesonide for 12 weeks, compared with controls who had residual OSA but were not treated with medical therapy [119].
Rapid maxillary expansion — Rapid maxillary expansion (RME) is an orthodontic treatment in which a dental appliance contacts the hard palate and is held in position by connections to the posterior teeth (picture 4). The appliance is gradually expanded, which widens the palate and nasal passages, thereby increasing airway patency and reducing nocturnal obstruction. The technique is used prior to midline fusion of the maxilla, which generally occurs shortly prior to puberty. RME can be used for children with OSA and narrow palate (crossbite) who have little adenotonsillar tissue, or for those with residual OSA after adenotonsillectomy. (See "Management of obstructive sleep apnea in children", section on 'Orthodontics'.)
Positive airway pressure — Continuous positive airway pressure (CPAP) and bilevel positive airway pressure (BPAP) therapy have been used successfully in many children with OSA. They are generally effective, but adherence to therapy can be challenging as in adults, and its use requires a motivated family. Given the problems with adherence and high frequency of improvement by adenotonsillectomy, positive airway pressure is typically reserved for children who have significant residual OSA after surgical intervention, or for those who are not considered appropriate surgical candidates. The use of CPAP or BPAP in children with OSA is discussed in more detail in a separate topic review. (See "Continuous positive airway pressure (CPAP) for pediatric obstructive sleep apnea".)
CPAP or BPAP are sometimes used to provide temporary airway support in selected patients in the immediate postoperative period after adenotonsillectomy, as documented in a small case series of nine children with medical comorbidities undergoing adenotonsillectomy [120].
Adjuvant surgical procedures — Surgical procedures other than adenotonsillectomy are sometimes considered to treat OSA in children without significant tonsillar hypertrophy, or with residual disease after adenotonsillectomy. These adjuvant surgical procedures may also be beneficial in patients with a high probability that OSA is due to factors other than adenotonsillar hypertrophy alone, such as in children with obesity, Down syndrome, craniofacial syndromes, or neuromuscular disease.
In these cases, additional evaluation to determine site of obstruction is often helpful. Flexible fiberoptic nasolaryngoscopy may identify adenoid regrowth, nasopharyngeal stenosis, lingual tonsillar hypertrophy, or laryngomalacia. DISE and cine MRI are increasingly used to identify dynamic obstruction that occurs during sleep and assist in surgical planning for children with residual OSA after adenotonsillectomy. (See 'Drug-induced sleep endoscopy' above and 'Magnetic resonance imaging' above.)
Tongue base procedures — Airway obstruction at the level of the base of tongue is increasingly recognized as a cause of persistent OSA after adenotonsillectomy, especially in children with obesity, Down syndrome, and craniofacial or neuromuscular disorders [100,101,105,107,109,111]. The site of obstruction is often identified by fiberoptic nasolaryngoscopy, cine MRI or DISE, as discussed above. (See 'Diagnostic procedures' above.)
Previous methods to reduce tongue tissue, primarily with the use of lasers, were limited by morbidity and not widely performed [121]. Newer minimally invasive techniques and technical advancements have made these techniques more accessible and have increased patient acceptance. Several small studies have evaluated the use of procedures to reduce tongue tissue, advance tongue musculature, or ablate lingual tonsil tissue to address collapse at this site in children, as illustrated by the following case series:
●Endoscopic-assisted radiofrequency ablation lingual tonsillectomy has emerged as a safe and effective technique to treat tongue base obstruction due to lingual tonsil hypertrophy in children with OSA. A retrospective case series described the use of this technique in 26 patients with PSG-documented OSA after adenotonsillectomy in whom obstructive lingual tonsillar hypertrophy was identified by DISE [122]. The procedure resulted in significant reduction in the mean obstructive apnea index (OAI) from 18.1 to 2.2 events/hour. Two patients developed adhesions between the epiglottis and tongue base, which were not clinically significant. A systematic review and meta-analysis identified a total of five studies reporting outcomes of lingual tonsillectomy for persistent OSA after adenotonsillectomy, which was most common in children with hypotonia, craniofacial anomalies, and obesity [123]. Rates of OSA resolution after lingual tonsillectomy ranged between 57 and 88 percent, although in three of the studies additional sites of obstruction were noted and supplemental surgical procedures were also performed. A separate systematic review and meta-analysis of isolated lingual tonsillectomy for persistent post-adenotonsillectomy OSA included five studies of 123 patients and found an overall success rate of 52 percent, defined as postoperative AHI <5 events/hour [124]. Complication rates, including postoperative bleeding, are similar to adenotonsillectomy [124,125].
●Tongue base advancement combined with radiofrequency ablation was described in a group of 31 patients with persistent OSA after adenotonsillectomy, including 19 (61 percent) with Down syndrome [126]. The tongue base was identified by cine MRI as the major site of collapse in 28 of 31 patients prior to surgery. The mean AHI improved from 14.1 to 6.4 events/hour, and mean nadir oxygen saturation increased from 87.4 to 90 percent (p <0.001 and 0.7 respectively). The success rate was 61 percent (defined as postoperative AHI <5 events/hour). Of note, some patients underwent concurrent surgical procedures to address additional areas of collapse identified on imaging.
Hypoglossal nerve stimulation — This technique employs an implantable device that stimulates branches of the hypoglossal nerve in order to protrude the tongue base during inspiration (picture 5). The procedure is sometimes used to alleviate upper airway obstruction due to tongue base prolapse in adults with OSA. The device is investigational in children, but experience with it has grown in children with trisomy 21 who have not responded adequately to adenotonsillectomy [127,128]. A prospective multicenter cohort study included 42 non-obese children age 10 to 21 years with trisomy 21 and severe OSA after adenotonsillectomy who were intolerant of CPAP therapy or were dependent on tracheostomy at night [128]. Hypoglossal nerve stimulation resulted in sustained improvement in OSA, with a mean reduction in AHI of 51 percent from baseline to 12 months postoperatively. Thirty-four percent of patients had an AHI <5 events/hour on 12-month follow-up polysomnography, and 73 percent had an AHI <10 events/hour. The device was well tolerated, with median nightly usage of more than nine hours/night. Four device- or surgery-related readmissions occurred, two of which required minor revisional surgery. No long-term complications were reported. (See "Surgical treatment of obstructive sleep apnea in adults", section on 'Global upper airway procedures'.)
Expansion pharyngoplasty and lateral pharyngoplasty — In some children, OSA is associated with collapse of the lateral pharyngeal wall [107,109]. Surgical procedures to correct this problem include expansion sphincter pharyngoplasty (ESP) or lateral pharyngoplasty.
In ESP, the palatopharyngeus muscle (posterior tonsillar pillar) is rotated superiorly and laterally and sutured in place to effectively pull the palate forward away from the posterior pharyngeal wall. A complete or partial uvulectomy is then performed [129]. The outcomes of ESP were reported for a group of 25 children with severe OSA and lateral pharyngeal wall collapse identified on DISE who underwent ESP with adenotonsillectomy, and compared with 25 AHI-matched children who underwent adenotonsillectomy alone [130]. The AHI after surgery was lower in both groups. Cure (defined by AHI <1 event/hour) was seen in 64 percent of children in the group treated with ESP, compared with 8 percent in the group that underwent adenotonsillectomy alone (p <0.001), despite higher body mass index (BMI) and age in the ESP group.
Lateral pharyngoplasty (suturing of the tonsillar pillars) after adenotonsillectomy may also address lateral pharyngeal wall collapse and provide better control of OSA. In a prospective controlled study, 24 children with OSA alternately assigned to adenotonsillectomy with suturing of the tonsillar pillars (intervention group) or adenotonsillectomy alone (control group) [131]. The AHI improved by 79.9 percent in the intervention group, compared with 42.6 percent in the control group (p = 0.037). Success (defined by reduction of AHI of >50 percent) was seen in 91.6 percent of children in the intervention group, compared with 50 percent of children in the control group (p = 0.03). Complete resolution of OSA (defined by AHI <1) was seen in 50 percent of the children in the intervention group, compared with 16.7 percent in the control group (p = 0.097) [131].
Techniques to expand the lateral pharyngeal wall may therefore improve PSG measures of OSA compared with adenotonsillectomy alone in some children whose OSA arises in part from lateral pharyngeal wall collapse.
Supraglottoplasty — Supraglottoplasty is moderately effective for treating children with laryngomalacia and OSA. A systematic review examining studies of supraglottoplasty in children with persistent OSA after adenotonsillectomy identified four studies reporting on 77 children [123]. The pooled mean AHI improved from 12.1 events per hour to 4.4 events per hour after supraglottoplasty. Another systematic review and meta-analysis included 13 studies (three of which were also included the previously mentioned review) with a total of 138 pediatric patients [132]. In the subgroup of children with sleep-exclusive laryngomalacia, most of whom had prior adenotonsillectomy, AHI improved from pooled mean AHI of 14.0 to 3.3 events per hour, but only 10.5 percent had resolution of OSA, defined as an AHI <1. In the subgroup of children with congenital laryngomalacia, for whom the prior adenotonsillectomy status was not reported, the mean AHI improved from 20.4 to 4.0 events per hour, and oxygen saturation nadir also improved, while 26.5 percent had resolution of their OSA.
Mandibular distraction osteogenesis — Mandibular distraction osteogenesis had been used successfully to address severe OSA due to mandibular hypoplasia (micrognathia) in infants and children. The mandible is divided bilaterally and internal or external distraction devices are placed on each side. The distraction devices are then used to move the mandible forward at a rate of 1 to 2 mm/day until the desired advancement is achieved.
Outcomes of mandibular distraction osteogenesis were examined in a meta-analysis that included 74 articles with a total of 711 patients with a variety of craniofacial anomalies that were included in the analysis, including isolated and syndromic Pierre Robin sequence in 52.9 and 7 percent of children, respectively, and Treacher Collins syndrome in 6.8 percent of children [133]. Successful treatment of airway obstruction (defined as either tracheotomy avoidance or decannulation, avoidance of need for CPAP, or significant improvement or absence of OSA symptoms) was observed in 89.3 percent of children. Specifically, among the 181 patients with OSA, complete resolution or significant improvement in symptoms was reported in 95.6 percent of patients. Analysis was complicated by the fact that a variety of outcome measures were included and specific PSG values were not provided. Of note, a 23.8 percent complication rate was seen, most often in the form of infection, abscess, open bite deformity, nerve injuries, or hypertrophic scarring. The mean follow-up time was 28.7 months.
These data suggest that distraction osteogenesis can be considered as a treatment for severe OSA in selected patients with mandibular hypoplasia from congenital craniofacial defects, but the high complication rate mandates careful consideration when contemplating the procedure.
Uvulopalatopharyngoplasty — Uvulopalatopharyngoplasty (UPPP) is not widely used for the management of OSA in children, but has been successfully combined with adenotonsillectomy in small studies of children with neuromuscular disorders who are thought to be at high risk for persistent upper airway obstruction after adenotonsillectomy alone, including children with Down syndrome or other developmental delays [134-137]. Only one of these studies employed objective evaluation of improvement in OSA. In this study, 15 children with neurologic impairments and OSA were treated with UPPP in conjunction with adenotonsillectomy [137]. There was a statistically significant improvement in mean oxygen saturation nadir from 65 to 85 percent (p = 0.005). In long-term follow-up, 77 percent (10 of 13) of the patients did not require additional airway intervention. Small sample size, absence of control groups, and paucity of validated outcome measures preclude analysis of the utility of this procedure in the broader pediatric population. Potential complications include nasopharyngeal stenosis, palatal incompetence, and speech difficulties [138,139].
Tracheotomy — Tracheotomy can be considered in children with persistent severe OSA despite surgical intervention, especially if they are intolerant of CPAP therapy. It can also be considered as a first-line treatment in children with severe OSA and airway obstruction who are not considered appropriate candidates for other surgical procedures. Although tracheotomy is an effective treatment for OSA and airway obstruction, it is associated with complications in as many as 43 to 77 percent of children, including bleeding, tracheoesophageal fistula, accidental decannulation, or tube occlusion [140,141].
SOCIETY GUIDELINE LINKS — Links to society and government-sponsored guidelines from selected countries and regions around the world are provided separately. (See "Society guideline links: Sleep-related breathing disorders including obstructive sleep apnea in children".)
INFORMATION FOR PATIENTS — UpToDate offers two types of patient education materials, "The Basics" and "Beyond the Basics." The Basics patient education pieces are written in plain language, at the 5th to 6th grade reading level, and they answer the four or five key questions a patient might have about a given condition. These articles are best for patients who want a general overview and who prefer short, easy-to-read materials. Beyond the Basics patient education pieces are longer, more sophisticated, and more detailed. These articles are written at the 10th to 12th grade reading level and are best for patients who want in-depth information and are comfortable with some medical jargon.
Here are the patient education articles that are relevant to this topic. We encourage you to print or e-mail these topics to your patients. (You can also locate patient education articles on a variety of subjects by searching on "patient info" and the keyword(s) of interest.)
●Basics topics (see "Patient education: Sleep apnea in children (The Basics)")
SUMMARY
●Role of surgery – Surgical removal of the tonsils and adenoids (adenotonsillectomy) is the first-line treatment of documented obstructive sleep apnea (OSA) or obstructive sleep-disordered breathing (SDB, without confirmation of OSA on polysomnography) in the general pediatric population. (See 'Indications for surgery' above and 'Symptomatic outcomes' above.)
●Preoperative evaluation – Risk factors for respiratory and other complications after adenotonsillectomy and for persistent disease after recovery include obesity (especially if severe), severe OSA at baseline, Down syndrome, craniofacial abnormalities, neuromuscular disorders, mucopolysaccharidosis, and sickle cell disease (table 1).
For these high-risk patients, we recommend the following precautions:
•Preoperative polysomnography (PSG) to assist in surgical decision-making. (See 'Polysomnography' above.)
•Operative setting that permits tertiary care if needed, including observation in hospital or pediatric intensive care unit (PICU) after adenotonsillectomy. (See 'Referral to a tertiary care facility' above and 'Operative setting' above.)
•Close clinical follow-up after adenotonsillectomy, with low threshold for performing postoperative PSG for many or all of these high-risk patients, especially if persistent symptoms are present. (See 'Indications for postoperative polysomnography' above.)
For standard-risk children who are otherwise healthy:
•Adenotonsillectomy can be safely performed as an outpatient procedure. (See 'Operative setting' above.)
•Expert opinion varies as to whether PSG should be routinely performed preoperatively for children with obstructive SDB, and whether young children (<3 years) should be routinely observed in-hospital overnight after the surgery. (See 'Preoperative assessment' above.)
•All patients should have a clinical reevaluation to determine whether snoring and other symptoms of SDB have resolved, and those with ongoing symptoms should have a postoperative PSG. (See 'Indications for postoperative polysomnography' above.)
●Surgical technique – The optimal technique for adenotonsillectomy for OSA in children has not been established. Traditionally, extracapsular (complete) tonsillectomy has been used. Intracapsular tonsillectomy (also known as partial tonsillectomy or tonsillotomy) may permit more rapid recovery, but also may increase risk of tonsillar regrowth in some patients. (See 'Surgical techniques' above.)
●Persistent OSA – For patients who have minimal adenotonsillar tissue, are poor candidates for adenotonsillectomy for any other reason, or who have persistent clinically significant OSA after adenotonsillectomy, treatment options may include continuous positive airway pressure (CPAP) or adjuvant surgical procedures. (See 'Nonsurgical therapeutic options' above and 'Adjuvant surgical procedures' above.)
Adjuvant surgical procedures are most needed for patients with OSA risk factors other than adenotonsillar hypertrophy alone, such as in children with obesity, Down syndrome, craniofacial syndromes, or neuromuscular disease. Additional preoperative evaluation with drug-induced sleep endoscopy (DISE) or cine-magnetic resonance imaging can help to determine the site(s) of obstruction to assist operative planning. (See 'Diagnostic procedures' above.)