Hostname: page-component-7b9c58cd5d-g9frx Total loading time: 0 Render date: 2025-03-14T04:29:52.891Z Has data issue: false hasContentIssue false
  • English
  • Français

Laryngomalacia: is there an evidence base for management?

Published online by Cambridge University Press:  25 October 2017

C McCaffer ,
K Blackmore  and
L M Flood
C McCaffer
Affiliation:
ENT Department, James Cook University Hospital, Middlesbrough, UK
K Blackmore
Affiliation:
ENT Department, James Cook University Hospital, Middlesbrough, UK
L M Flood*
Affiliation:
ENT Department, James Cook University Hospital, Middlesbrough, UK
*
Address for correspondence: Mr Liam M Flood, ENT Department, James Cook University Hospital, Marton Rd, Middlesbrough TS4 3BW, UK E-mail: Liam.flood@nhs.net
Rights & Permissions [Opens in a new window]

Abstract

Background:

The advent of supraglottoplasty clearly has transformed the surgical management of severe laryngomalacia. The condition, however, generally runs a milder course, with spontaneous resolution the norm.

Objectives:

To identify gaps in the knowledge and identify topics for future study.

Method:

Systematic review of the literature.

Results:

The literature suggests that there is a range of abnormalities leading to the typical collapsing upper airway, and that neurological disease, other airway abnormalities, syndromes and gastroesophageal reflux all contribute to disease severity and influence outcomes. The procedures involved in supraglottoplasty are rarely specified, the indications for surgery are vaguely defined and the role of medical therapy is unclear.

Conclusion:

Every review article or survey of opinion suggests that there is still a marked variation in individual practice and a lack of consensus.

Keywords

LaryngomalaciaDiagnosisSurgeryReviewSystematic
Type
Review Articles
Information
The Journal of Laryngology & Otology , Volume 131 , Issue 11 , November 2017 , pp. 946 - 954
Copyright
Copyright © JLO (1984) Limited 2017 

Introduction

Surgical procedures are rarely supported by a sound evidence base, but it is human nature to be influenced by personal experience and make assumptions as to efficacy and safety. Systematic reviews in surgery, however flawless the methodology, usually conclude that the evidence sought is sorely lacking and call for further research. However, repeating the exercise after a long interval rarely shows that this call has been heeded.

Common sense may well triumph over the demands of evidence-based medicine (EBM), especially with the ethical and administrative challenges of creating a control group for any surgical intervention. This was memorably illustrated in a humorous and iconoclastic systematic review lamenting the lack of randomised controlled trials to confirm the efficacy of a parachute in preventing death or major trauma in a ‘gravitational challenge’.Reference Smith and Pell 1 This article concluded that, in such a situation, observational data are surely sufficient, whilst amusingly calling for the protagonists of EBM to participate in a placebo controlled trial. However valid this sensible approach might be, it should not prevent further research into efficacy. Even here, there is still persisting uncertainty about the risks and benefits of: canopy design, the provision of parachutes in passenger airliners, a reserve in military low-altitude combat drops and automatic opening devices.

Advances in technology and understanding of disease have surely transformed the management of many challenging conditions, and it may seem that all questions are answered and there is no scope for further research. Typical is the place of sphenopalatine artery ligation as standard practice in the control of refractory epistaxis. Systematic review of the literature, however, highlights many persisting uncertainties.Reference Ellinas, Jervis, Kenyon and Flood 2

Reviews of laryngomalacia generally open by reminding us that it is the commonest cause of congenital stridor; they go on to describe the characteristic appearance of the collapsing laryngeal inlet, and stress that the clinical course is relatively benign with spontaneous resolution the norm. The advent of supraglottoplasty, however ill-defined, led to many a case series or cohort study reporting success in the majority of the few patients deemed to require it, and a perception that this clinical problem is largely solved.

The term ‘laryngomalacia’ was probably first used by Jackson and Jackson in 1942Reference Jackson and Jackson 3 and does not appear in the Archives of The Journal of Laryngology & Otology until 1991.Reference Jani, Koltai, Ochi and Bailey 4 The condition was clearly recognised, however, in the late nineteenth century. Typical clinical findings were nicely described, for the first time in this journal, by Dan Mckenzie in 1919, as ‘those seen in congenital laryngeal stridor, in which it is the aryepiglottic folds and lateral walls of the larynx that are sucked inwards’.Reference Mckenzie 5

The progressive adoption of endoscopic surgery and especially aryepiglottoplasty has clearly transformed management. The earliest report in this journal (in 1991), of 12 procedures,Reference Jani, Koltai, Ochi and Bailey 4 was followed 10 years later by the same group's results in 100 consecutive patients.Reference Toynton, Saunders and Bailey 6 Indeed, many systematic reviews attest to efficacy, although based solely on case series, and they, universally, call for further research into gaps in knowledge.

The literature was systematically reviewed to establish an evidence base for our understanding of laryngomalacia and its management, and to identify where further work is needed. The topics addressed include: definition and classification; diagnostic criteria; the overlap with obstructive sleep apnoea (OSA); associated abnormalities and the role of medical therapy; staging of severity and indications for surgical intervention; the natural history of the condition; choice of surgical technique; surgical outcomes and efficacy; and complications of treatment.

Materials and methods

In the preparation of this systematic review, we have followed the guidelines of the Preferred Reporting Items for Systematic reviews and Meta-Analyses for Protocols (‘PRISMA-P’) 2015.Reference Shamseer, Moher, Clarke, Ghersi, Liberati and Petticrew 7

We assessed the quality of papers using the National Institute for Health and Care Excellence quality assessment tool, as it allows some analysis of case reports and series (lower level evidence). 8 We sought high-quality prospective clinical studies, reviews or laboratory work relevant to the diagnosis, classification, management and prognosis of laryngomalacia.

Medline, Embase and Cochrane Library databases were searched from inception up to March 2017. The following keywords or combinations thereof were used: ‘congenital laryngomalacia’, ‘supraglottoplasty’, ‘review’, ‘controlled trial’, ‘classification’ and ‘reflux’.

Abstracts, identified from a review of article titles, were evaluated for inclusion by two authors (CM and LMF) working independently, with consensus if opinions differed. Papers were chosen if the abstracts suggested systematic reviews or meta-analyses, prospective controlled studies, or original basic science findings from laboratory studies. Audits and larger case series or cohort studies, especially those offering any comparative study between groups or before and after intervention, provided a lower level of evidence. Papers suggesting algorithms and consensus views for treatment, case reports suggesting complications, and the earliest reports of the procedure were also included.

Abstracts were excluded if they suggested isolated case reports or small, uncontrolled series that presented no new insight. No language restrictions were applied.

Results

We selected and have made reference in the text to the following: 9 systematic reviews;Reference van der Heijden, Dikkers and Halmos 9 Reference Preciado and Zalzal 17 0 randomised controlled trials; 7 non-randomised controlled or comparative studies;Reference Sivan, Ben-Ari, Soferman and DeRowe 18 Reference Meier, Nguyen and White 24 33 case series or cohort studies;Reference Shah and Wetmore 25 Reference Eustaquio, Lee and Digoy 57 4 surveys, consensus documents or questionnaires;Reference Carter, Rahbar, Brigger, Chan, Cheng and Daniel 58 Reference Thottam, Simons, Choi, Maguire and Mehta 61 4 historical articles;Reference Jackson and Jackson 3 Reference Toynton, Saunders and Bailey 6 and 0 case reports.

Discussion

Definition and classification

The classical picture of congenital stridor, as due to a contracting laryngeal inlet on inspiration, is well recognised, but there may be different patterns of collapse, each with its own prognosis. There are a number of systems proposed for classification, suggesting this is still unsettled. Without an agreed, reliable classification, there are challenges to diagnosing, judging the severity and staging the disorder, and difficulties in evaluating outcomes and the effect size for surgical treatment.

Described variants from the typical stridor that develops shortly after birth include episodic, exercise-induced, adult and late-onset laryngomalacia and tracheomalacia. The contribution from neurological disorders and other co-morbidities must be recognised. There may even be a secondary form of laryngomalacia, in which a completely normal larynx only collapses because of excessive negative intra-thoracic pressure, in a child struggling against a supra-laryngeal obstruction. This might occur in bilateral choanal atresia, severe OSA or anterior nasal stenosis. Recognition and treatment of the primary disorder may then be fundamental.

The lack of agreed diagnostic criteria was noted two decades ago by Shah and Whetmore, who commented ‘While there is a vast literature on the subject, there is neither stratification nor correlation of clinical presentation, endoscopic appearance, treatment and outcome’.Reference Shah and Wetmore 25 They then devised a form to allow classification, but this was based on a validation exercise conducted on only 10 patients.

A decade later, another system was proposed (still based on a study population of only 10 children, however), dividing laryngomalacia into types 1–3.Reference Kay and Goldsmith 26 Type 1 showed a foreshortened or tight aryepiglottic fold, type 2 represented excessive redundant soft tissue in the supraglottis, and type 3 comprised all other causes, most notably neurological disease.

Suggested classifications merely increased in complexity. In a study investigating the outcomes of carbon dioxide (CO2) laser surgery, laryngomalacia was instead subdivided according to the direction of the supraglottic collapse.Reference Lee, Chen, Yang and Chen 27 Type A represented posterolateral inversion, type B reflected complete collapse and type C represented anterior inversion. Unfortunately, most individuals showed mixed patterns and had to be classified as: group I (type A only), group II (type B or B + A) or group III (type C, C + A or C + B + A), resulting in an unwieldy tool.

In a retrospective case series, published in 2014, which reviewed the morphological types of laryngomalacia and influence on prognosis, the authors could still state ‘Further work is required in validating an existing classification scheme for laryngomalacia or developing a new, validated classification system which may be used for future outcomes research’.Reference Erickson, Cooper and El-Hakim 28

Based on a systematic review and a retrospective cohort study of 85 patients, the Groningen Classification System recognises only 3 typical dynamic (as opposed to anatomical, static) airway changes: type 1 – inward collapse of the arytenoid cartilages; type 2 – medial displacement of the aryepiglottic folds; and type 3 – postero-caudal displacement of the epiglottis against the posterior pharyngeal wall.Reference van der Heijden, Dikkers and Halmos 9

Diagnostic criteria

Endoscopy remains the method of choice for diagnosis and staging.

The initial assessment of stridor usually involves fibre-optic endoscopy on an awake patient, as reported in this journal in 2001,Reference Kayaykar and Gray 29 when a diagnosis could be made confidently in 80 per cent of 20 subjects, with only 4 requiring rigid endoscopy. A literature review reported many techniques attempting to ensure pacification, whilst reporting personal experience with a further modification.Reference Loizou, Haloob and Evgeniou 30

A blinded study asked 3 observers to compare and score videotapes from awake flexible endoscopy and endoscopy employing anaesthesia or sedation, in 42 children with congenital stridor.Reference Sivan, Ben-Ari, Soferman and DeRowe 18 The recordings were randomly mixed in with a sequence from normal infants and flexible endoscopy under sedation or anaesthesia. The latter showed 100 per cent sensitivity and specificity, compared with 93 per cent and 92 per cent respectively for awake examination. The awake technique missed three cases of laryngomalacia and misdiagnosed one normal individual as a sufferer. The conclusion was that this was best used for screening, for example to exclude the presence of a congenital supraglottic cyst, or for milder typical cases.Reference Sivan, Ben-Ari, Soferman and DeRowe 18 Flexible endoscopy is frequently combined with rigid bronchoscopy under general anaesthesia, especially seeking sites of multilevel obstruction in those most at risk (see below), but we could find no studies assessing the added benefit.

Airway fluoroscopy certainly did not contribute any added benefit to endoscopy, showing poor sensitivity and specificity, and poor predictive values.Reference Huntley and Carr 31

In a typically retrospective study of the airway findings of 130 patients with a laryngomalacia diagnosis, combined posterior and anterior supraglottic collapse was the most common finding (31 per cent).Reference Adil, Rager and Carr 32 Posterior collapse alone occurred in 25 per cent of patients, anterior collapse in 14 per cent and lateral collapse in 10 per cent. Twelve per cent of patients had all three sites of collapse. Forty-one per cent of patients had a secondary airway lesion, with tracheomalacia being the most common. Prematurity showed a statistically significant increased risk of reflux and multiple sites of collapse.Reference Adil, Rager and Carr 32

Obstructive sleep apnoea and laryngomalacia

The relationship of laryngomalacia to OSA has very recently attracted some studies with the highest level of evidence. In that rarity, a prospective cohort study of children with established OSA, polysomnography did not prove of value in determining the severity of laryngomalacia, did not correlate with the clinical impression and, alone, did not predict the need for surgery.Reference Weinstein, Lawlor, Wu and Rodriguez 33 Of 25 infants (mean age, 3.9 months), all presented with OSA as determined by polysomnography, but only 80 per cent underwent supraglottoplasty. The apnoea-hypopnea index did not correlate with a high laryngomalacia severity score, nor did it differ between those undergoing surgery and those managed conservatively.Reference Weinstein, Lawlor, Wu and Rodriguez 33

Site of obstruction identification is fundamental in surgical planning for OSA. A systematic review of a much older paediatric population extracted data from 24 articles (960 subjects) and found that most institutes employed drug-induced sleep endoscopy and cine magnetic resonance imaging.Reference Manickam, Shott, Boss, Cohen, Meinzen-Derr and Amin 10 It concluded that the evidence for relevance to outcomes was generally extremely limited, but that lingual tonsillectomy and supraglottoplasty were notable exceptions. UK practice would reserve sleep nasendoscopy for refractory OSA; a pre-operative cardiorespiratory sleep study or formal polysomnography are more routinely employed. A systematic review of polysomnography findings in patients with OSA and laryngomalacia identified only four studies meeting the inclusion criteria.Reference Farhood, Ong, Nguyen, Gillespie, Discolo and White 11 Meta-analysis showed improvement after supraglottoplasty, but there was a high level of some residual disease (88 per cent of 33 children). Four studies showed an improved apnoea-hypopnea index, with a drop of a mean of 12.5 points. Oxygen saturations improved from the nadir level by a mean of nearly 10 per cent.Reference Farhood, Ong, Nguyen, Gillespie, Discolo and White 11

Similar findings, inevitably perhaps, resulted from a simultaneous systematic review which had included 13 studies for analysis.Reference Camacho, Dunn, Torre, Sasaki, Gonzales and Liu 12 That study investigated 64 patients with sleep exclusive laryngomalacia and 74 patients with congenital laryngomalacia, to judge the efficacy of supraglottoplasty in correcting the apnoea-hypopnea index and lowest oxygen saturation scores. For the latter group, meta-analysis showed an apnoea-hypopnea index decrease from a mean of 20.4 to 4 events per hour after surgery, and improved lowest oxygen saturation from a mean of 74.5 to 88.4 per cent. Again, complete cure was a rarity (26.5 per cent).Reference Camacho, Dunn, Torre, Sasaki, Gonzales and Liu 12

Remarkably, a third systematic review was published in the same year (2016), again to review changes in sleep parameters after supraglottoplasty, but also to determine prognostic factors for success.Reference Lee, Hsu, Lee, Lin and Kang 13 Now 11 studies met the inclusion criteria and again showed a statistically significant reduction of apnoea-hypopnea index of 8.9 events per hour and an increase in minimum oxygen saturations of 3.7 per cent. Cure (defined as an apnoea-hypopnea index of less than 1 event per hour) was only seen in 28 per cent. Supraglottoplasty, whether as a primary treatment (in the younger children) or secondary to other surgery, showed similar outcomes. Equally, the presence or absence of co-morbidities did not affect the chance of cure (25 per cent vs 21 per cent).Reference Lee, Hsu, Lee, Lin and Kang 13

Central sleep apnoea associated with laryngomalacia has attracted less investigation. A retrospective study of central sleep apnoea (defined as central apnoea index of 5 or more), conducted on 54 patients (mean age, 3.4 months), showed a prevalence of 46.3 per cent.Reference Tanphaichitr, Tanphaichitr, Apiwattanasawee, Brockbank, Rutter and Simakajornboon 34 It was suggested that the highest risk was in those with neurological disease, hypotonia or syndromes, prematurity, and age less than three months. However, none of the factors identified proved statistically significant, which might represent a type II error and small sample size.Reference Tanphaichitr, Tanphaichitr, Apiwattanasawee, Brockbank, Rutter and Simakajornboon 34

Other associated abnormalities

The prevalence of gastroesophageal reflux in association with laryngomalacia, its influence on outcomes and the value of medical management has attracted much debate, but less at a high level of evidence. Expert opinion, (level 5) as shown by the recent International Pediatric Otorhinolaryngology Group consensus document, concludes that ‘there is great variation in practice amongst the current group members’ in the management of associated reflux.Reference Carter, Rahbar, Brigger, Chan, Cheng and Daniel 58

A systematic review of eight articles did conclude that endoscopic findings suggestive of reflux (arytenoid and posterior glottic oedema, vocal fold oedema, and lingual tonsil hypertrophy) were more common in laryngomalacia and subglottic stenosis.Reference May, Shah, Lemonnier, Bhatti, Koscica and Coticchia 14 A systematic review investigating an association between laryngomalacia and reflux reviewed 27 studies, and performed a meta-analysis on 6.Reference Hartl and Chadha 15 The findings suggested a prevalence of 59 per cent based on dual probe pH monitoring, but this was not statistically significantly greater in laryngomalacia than in other respiratory diagnoses. The authors noted greater reflux, indeed a 10-fold increase, in the more severe cases of laryngomalacia. Response to anti-reflux therapy was based on weak and inconsistent evidence, and benefit was generally apparent only after six months of therapy, possibly just reflecting the natural history towards recovery. Any histological evidence was of only mild laryngeal inflammation. Although reporting a co-existence, the authors concluded that any causal association lacks an evidence base and called for a randomised controlled trial of anti-reflux therapy against placebo.Reference Hartl and Chadha 15

A survey of USA, Canadian and UK practice examined the management of reflux associated with severe laryngomalacia requiring surgery.Reference Ramprasad, Ryan, Farjat, Eapen and Raynor 59 Of 101 respondents, only 89 per cent would treat for reflux, 54 per cent with proton pump inhibitors only and 41 per cent just with H2 blockers. An empirical approach is suggested by the International Pediatric Otorhinolaryngology Group consensus, recommending anti-reflux therapy if the child has feeding and/or respiratory difficulty, but to ‘consider observation’ if respiratory symptoms are mild and the child shows good weight gain.Reference Carter, Rahbar, Brigger, Chan, Cheng and Daniel 58 Persistence of symptoms despite maximal reflux suppression requires the exclusion of an underlying neurological abnormality. The authors reported that H2 antagonists are better tolerated than proton pump inhibitors by infants, and that the latter lacks Food and Drug Administration approval for this indication. Some would favour a ‘step-down approach’, employing both approaches and dropping one at the earliest opportunity; others, the reverse.Reference Carter, Rahbar, Brigger, Chan, Cheng and Daniel 58

Swallowing dysfunction was studied in a large retrospective cohort analysis of 324 patients with laryngomalacia.Reference Simons, Greenberg, Mehta, Fabio, Maguire and Mandell 35 Gastroesophageal reflux was again noted in a high proportion, 69.8 per cent, but also dysphagia in 50.3 per cent and failure to thrive in 9.6 per cent. Nonetheless, there was no significant relationship between laryngomalacia severity and swallowing abnormalities, whether on symptoms, clinical swallowing evaluations by speech and language pathologists, modified barium swallow studies, or fibre-optic endoscopic evaluation of swallowing. Indeed, their experience of the rate of abnormal findings on such studies, irrespective of obvious clinical symptoms, led to a recommendation that all infants with laryngomalacia undergo dysphagia assessment.Reference Simons, Greenberg, Mehta, Fabio, Maguire and Mandell 35

The literature tends to concentrate on the influence of such recognised associations as reflux, neurological disease, syndromes and other airway abnormalities on prognosis and surgical success, rather than on their prevalence.

A study of 201 infants with varying laryngomalacia severity sought evidence of secondary airway lesions, and found 104, a higher number than expected.Reference Dickson, Richter, Meinzen-Derr, Rutter and Thompson 36 Subglottic stenosis was found in just over one-third of cases, with a similar rate for tracheomalacia. Secondary airway problems were more prevalent in severe laryngomalacia (79 per cent) than in mild laryngomalacia (28.8 per cent), and, in the mild to moderate cases, they significantly increased the need for surgery. Infants with secondary airway problems were far more likely to have reflux than those without (84.6 per cent vs 45.4 per cent; p < 0.0001).Reference Dickson, Richter, Meinzen-Derr, Rutter and Thompson 36

In the reverse process, a study of 139 children with congenital tracheoesophageal fistula and/or oesophageal atresia investigated the rate of associated airway disorders.Reference Hseu, Recko, Jennings and Nuss 37 Laryngomalacia was the least prevalent disorder (4.3 per cent), compared with subglottic stenosis (12.9 per cent), vocal fold paralysis (21.6 per cent) or laryngeal cleft (25.9 per cent). The commonest associated airway abnormality proved to be tracheomalacia (37.4 per cent).Reference Hseu, Recko, Jennings and Nuss 37

Edmondson et al. suggested that the vast majority of children reported in such cases series are Caucasian, and the results may not apply to a more ethnically diverse population, such as seen in the Bronx, New York.Reference Edmondson, Bent and Chan 38 Their small series of 78 children with laryngomalacia was dominated by Afro-American and Hispanic subjects, with only 4 Caucasians. Certainly, their experience contrasts with the literature, with 18 premature births and 21 low birth weights. Twenty-eight per cent of patients had a neurological abnormality and 30 per cent underwent surgery. Whether these findings truly relate to genetic rather than socioeconomic factors must be questioned.Reference Edmondson, Bent and Chan 38

Staging of severity and indications for surgery

In a condition that generally presents mild systemic upset, and where the natural tendency is towards spontaneous remission, indications for surgery are fundamental to evaluating outcomes. A low threshold for intervention will surely select many whose natural history was to recover, artificially boosting apparent success rates.

A particularly interesting consensus document surprisingly largely overlooks this decision.Reference Carter, Rahbar, Brigger, Chan, Cheng and Daniel 58 The authors repeatedly note ‘variation in practice’ amongst the membership throughout the text. Of 21 questions tabled for consensus, no fewer than 12 are qualified by the word ‘consider’.Reference Carter, Rahbar, Brigger, Chan, Cheng and Daniel 58

Indications for surgery are subjective and rarely documented, centring on the worsening of an ill-defined variety of airway symptoms (especially cyanosis and apnoeic episodes), feeding difficulties and failure to thrive.Reference Ramprasad, Ryan, Farjat, Eapen and Raynor 59

Natural history of condition

There is little doubt that the vast majority of laryngomalacia cases settle spontaneously by 12–18 months of age, and are probably cared for by paediatricians and so never referred to surgeons, as is reflected in the ENT literature.

Typical of such reports is a retrospective study of 120 consecutive patients with laryngomalacia, over a 4-year period.Reference Wright and Goudy 39 In that study, 115 cases resolved without surgery, at a mean age of 7.6 months, and only 5 patients required supraglottoplasty.

A recent systematic review addressing the natural history in otherwise healthy infants could only identify 3 papers (411 patients), all retrospective, which met the study inclusion criteria.Reference Isaac, Zhang, Soon, Campbell and El-Hakim 16 Eighty-nine per cent of cases ‘resolved’ (i.e. were free of stridor) over a period ranging from 4 to 42 months. The authors suggested that, with such a low level of evidence, ‘Prospective longitudinal trials are required to better understand the natural history’.

Clearly, few studies compare the natural history or best medical management with surgical outcomes. Largely using growth and thriving as outcome measures, rather than the airway, a case–control comparison of 51 infants with moderate to severe congenital laryngomalacia compared supraglottoplasty, in 17 cases, with medical management (acid suppression therapy, speech and swallowing therapy, and/or high-calorie formula), in 34 matched controls.Reference Faria and Behar 19 The absence of randomisation of course does suggest the risk of selection bias; however, no difference in growth was actually observed between the two groups. The conclusion could only be that ‘Medical management and close observation … may be a viable alternative to supraglottoplasty in appropriately selected infants’.Reference Faria and Behar 19

A similar retrospective study, of 89 patients, compared outcomes of supraglottoplasty with those of a wait-and-see policy, and considered the influence of co-morbidities.Reference van der Heijden, Dikkers and Halmos 20 Unsurprisingly, surgery was associated with a statistically significant faster resolution of symptoms than conservative management (5 weeks vs 29 weeks; p = 0.026), and synchronous airway lesions further prolonged symptoms. The authors found supraglottoplasty to be safe and effective in severe laryngomalacia, but did concede that ‘the indication for surgery is not firmly established yet’.Reference van der Heijden, Dikkers and Halmos 20

The effect of laryngomalacia on quality of life has been studied prospectively in a study using a questionnaire survey of 26 families of infants aged less than 1 year.Reference Kilpatrick, Boyette, Hartzell, Norton, Boswell and Bower 60 It compared responses for the 11 infants managed medically and the 15 infants who underwent supraglottoplasty, both before and after treatment. Both groups showed a statistically significant improvement over the presenting findings after a three-month interval. Unsurprisingly, those destined to undergo surgery showed higher scores at presentation, but ultimately there was no difference in quality of life scores between the surgically and conservatively managed infants.Reference Kilpatrick, Boyette, Hartzell, Norton, Boswell and Bower 60 A similar, but larger study (72 patients) showed that parents’ perception of their child's health was particularly influenced by the degree of aspiration and penetration.Reference Thottam, Simons, Choi, Maguire and Mehta 61

Surgical techniques

There is a notable lack of detailed description of the surgical measures involved in what is termed ‘supraglottoplasty’ in most publications. Operative abnormalities to be addressed in such surgery include shortened aryepiglottic folds, a retro-positioned epiglottis, and excess and prolapsing arytenoid mucosa. The solution is generally some combination of division of the aryepiglottic folds, ablation of excess mucosa and anterior suspension of the epiglottis.Reference Garritano and Carr 40

A recent review of a 14-year experience of 79 patients undergoing laser supraglottoplasty showed limited success for those with postero-caudal displacement of the epiglottis, and for those with synchronous airway lesions, associated co-morbidities and prematurity.Reference Reinhard, Gorostidi, Leishman, Monnier and Sandu 41 A study comparing such rigid endoscopic methods in 27 patients, with a flexible potassium titanyl phosphate laser delivery system in a subsequent 30, suggested similar benefits, but obvious advantages for convenience and cost-effectiveness.Reference Soong, Shiao, Jeng, Lee, Tsao and Yang 21

Concerns about potential hazards of supraglottoplasty, especially stenosis, have led some to consider staged surgery, operating on one side and then the second if needed. An early UK study retrospectively compared the results of bilateral and unilateral supraglottoplasty in 106 paediatric patients with severe laryngomalacia.Reference Reddy and Matt 22 Although selection bias seems inevitable in the absence of randomisation, it is notable that they reported a success rate of 95.7 per cent and a reduced risk of stenosis in the 47 patients who underwent unilateral surgery. Only seven patients in this group (14.9 per cent) required a second contralateral procedure, and the authors concluded that this ‘seems to be a reasonable option’.Reference Reddy and Matt 22

More recently, a much smaller study (n = 15 infants) compared outcomes for unilateral (73 per cent resolution) or staged surgery (100 per cent response), with historical controls taken from the literature.Reference Walner, Neumann, Hamming and Miller 23 This study found that a second procedure was needed in 40 per cent of patients, but concluded that ‘Staged supraglottoplasty appears to be an effective, low-risk method to treat severe laryngomalacia’.

Most descriptions of operative modifications, or procedures with new surgical tools, lack any comparative trials, involve retrospective studies and present small series. Typical is a study of microdebrider-assisted supraglottoplasty, the largest series to describe this, but comprising only 28 patients.Reference Groblewski, Shah and Zalzal 42 Coblation® is recorded as used by a small minority,Reference Ramprasad, Ryan, Farjat, Eapen and Raynor 59 but without any reports of outcome.

Post-operative care

A retrospective chart review of 65 patients with severe laryngomalacia undergoing supraglottoplasty suggested a very favourable course immediately post-operatively.Reference Fordham, Potter and White 43 Only three patients required more than a single overnight stay, and all returned from the operating theatre extubated. In over three-quarters of patients, normal oral intake was possible within 4 hours of surgery.Reference Fordham, Potter and White 43

An international survey of practice showed marked variation; however, there was almost universal consensus on steroid use intra-operatively, but only 23 per cent administered antibiotics.Reference Ramprasad, Ryan, Farjat, Eapen and Raynor 59 The level of post-operative care was significantly (p = 0.009) associated with familiarity with procedure. Those performing the highest numbers of procedures annually were least likely to continue intubation and admit to intensive care.Reference Ramprasad, Ryan, Farjat, Eapen and Raynor 59 A retrospective study of 223 patients undergoing supraglottoplasty showed that 25 (11.2 per cent) required intensive care, with intubation, ventilation, racemic adrenaline or high levels of oxygen therapy.Reference Albergotti, Sturm, Stapleton, Simons, Mehta and Chi 44 Predictors for this need, generally identified within 4 hours of surgery, were surgical duration longer than 30 minutes, non-Caucasian race and pre-operative gastroesophageal reflux, all proving highly statistically significant.Reference Albergotti, Sturm, Stapleton, Simons, Mehta and Chi 44

Surgical outcomes and efficacy

The generally favourable results of supraglottoplasty dominate the literature on laryngomalacia. An often-cited systematic review of surgery outcomes in practice concentrated more on causes of failure, but was compromised by the paucity of high-level evidence.Reference Preciado and Zalzal 17 Only 8 studies met even the generous inclusion criteria and all were level 4 case–control series. There were no prospective controlled trials to evaluate. Surgical failure, specified by the review as the need for tracheostomy, gastrostomy or revision surgery, was increased by the presence of co-morbidities (particularly ill-defined in the articles studied). Compared with isolated laryngomalacia, those with co-morbidities showed a risk ratio of 7.14 for surgical failure and of 4.33 for post-operative aspiration (the latter calculation based on data from only three studies). There were insufficient data to correlate outcomes with: age at surgery, technique employed or even laryngomalacia severity. Understandably, the review concluded that ‘Randomized, prospective studies with well-defined protocols appear to be necessary to further stratify the risk of failure by the specific medical comorbidity and/or surgical technique used’.Reference Preciado and Zalzal 17

Subsequent retrospective studies continued to review personal experience and prove contradictory. One of the larger studies (comprising 148 patients undergoing supraglottoplasty, but only 115 with available case notes to analyse) showed a significant association between a delayed post-operative diagnosis of neurological disorder and surgical failure (p < 0.001).Reference Douglas, Shafi, Higgins, Blackmore, Wynne and Kubba 45

An earlier study obtained data from 74 of 95 children undergoing supraglottoplasty.Reference Day, Discolo, Meier, Wolf, Halstead and White 46 Reporting a 16 per cent failure rate, the authors found that, after analysing neurological disorder, age at surgery, cardiac disease, other airway problems, syndromes and so on, only prematurity (less than 34 weeks gestation) proved an independent risk factor (odds ratio = 4.85).Reference Day, Discolo, Meier, Wolf, Halstead and White 46 Concentrating just on infants and children (over 1 year of age) with either a syndromal or neurological co-morbidity, a study of 54 patients (23 syndromal and 31 neurological) reported an overall success rate of 67 per cent for supraglottoplasty.Reference Durvasula, Lawson, Bower and Richter 47 For infants, the two groups showed similar outcomes (67 per cent and 69 per cent) for supraglottoplasty, which was largely driven by acute airway obstruction. For those aged over one year, where such surgery was instead driven by OSA, the neurological group did better (50 per cent vs 78 per cent).Reference Durvasula, Lawson, Bower and Richter 47 The same authors, analysing 325 patients under 1 year of age and free of co-morbidities, could then evaluate the influence of prematurity on surgical results.Reference Durvasula, Lawson, Bower and Richter 48 In that study, 136 term and 40 pre-term infants showed no difference in success rates (92.7 per cent and 90 per cent). Prematurity was associated with a higher rate of secondary airway lesions, and dysphagia was significantly worse both pre- and post-operation in those of gestational age of less than 32 weeks.Reference Durvasula, Lawson, Bower and Richter 48

A relatively small but unique study of patients with Down syndrome (n = 18) and laryngomalacia investigated the results of supraglottoplasty performed at a mean age of 7.7 months.Reference Cockerill, Frisch, Rein and Orvidas 49 Nearly half of the patients did require subsequent further surgery such as adenotonsillectomy. Of this small group, two patients subsequently required tracheostomy, two required nasogastric feeding and two required revision supraglottoplasty, illustrating the greater challenge involved.Reference Cockerill, Frisch, Rein and Orvidas 49

Few studies consider objective measures of benefit, instead concentrating on predictors of compromised surgical results. A case–control study compared a series of growth curve measurements of body weight for: 15 patients with laryngomalacia who were merely observed, 71 patients with laryngomalacia who received medical treatment and 29 who underwent surgery.Reference Meier, Nguyen and White 24 Clearly the groups were highly selected, and the surgical group showed significantly lower scores at presentation, but with significant improvement by three months post-surgery. After 12 months, all groups showed values close to the mean.Reference Meier, Nguyen and White 24 An analysis of patient records studied catch-up growth in just those undergoing supraglottoplasty.Reference Czechowicz and Chang 50 Seventy-six patients had height, weight and body mass index measurements pre- and up to nine months post-surgery. Most gain was seen in the first six months and, unsurprisingly, was greatest in those who were youngest and smallest at the start.Reference Czechowicz and Chang 50

It is likely that the commonest surgical approach to laryngomalacia, in the UK, is still the cold steel division of the aryepiglottic folds. As we have seen, there are no studies providing high-level evidence to suggest that any other technique is superior in isolated laryngomalacia, without co-morbidities.

Complications of surgery

Complications of supraglottoplasty are few, but include reports of new onset or worsening of aspiration and stenosis. Any review of safety must include the lowest levels of evidence, even isolated case reports. However, a systematic review of surgical outcomes, based on three studies satisfying the inclusion criteria, confirmed an increased risk of post-operative aspiration for those patients with associated co-morbidities (risk ratio = 4.33) when compared to those without.Reference Preciado and Zalzal 17 A lack of data prevented evaluation of the significance of age at surgery or technique used.

In a retrospective review of 468 patients, most aged 28 days to 2 years, 10 per cent experienced aspiration after supraglottoplasty, an association not found to be statistically significant.Reference Anderson de Moreno, Burgin and Matt 51 The risk of aspiration was positively correlated with: an age of less than 18 months, revision surgery, any underlying neuromuscular abnormality and the need for post-operative gastrostomy (presumably only to be expected, as required by aspiration rather than promoting it).Reference Anderson de Moreno, Burgin and Matt 51 Analysis excluding the patients with neurological co-morbidities reduced the aspiration risk to 5.8 per cent.

Most such reports will represent a surgical failure to correct swallowing difficulties, rather than causing or worsening them, as few studies objectively exclude swallowing disorders prior to surgery. The same authors, in a much larger study (2360 children's records), wisely then excluded from analysis those experiencing obvious aspiration before surgery, and found that post-operative risk increased with degree of prematurity (5.9 per cent, odds ratio = 2.3).Reference Anderson de Moreno and Matt 52

A retrospective review reported on a 5-year experience of 50 infants (mean age of 4.5 months) with severe laryngomalacia who required cold steel supraglottoplasty and maximal reflux suppression.Reference Richter, Wootten, Rutter and Thompson 53 None of the infants developed aspiration de novo, as shown on fibre-optic endoscopic evaluation of swallowing and laryngopharyngeal stimulation testing. Pre-operatively, laryngeal penetration was seen in 88 per cent, and aspiration beyond the vocal folds was observed in 72 per cent. Post-operatively, these conditions resolved in 81.8 per cent and 86.1 per cent respectively. Failure was universally associated with co-morbidities such as congenital heart disease, syndromes or neurological abnormality.Reference Richter, Wootten, Rutter and Thompson 53

An unexpectedly higher rate of aspiration, but a tendency to resolve by a mean of 6 months, was noted in a study reviewing bilateral CO2 laser supraglottoplasty in 52 infants.Reference Schroeder, Thakkar, Poznanovic and Holinger 54 All infants underwent a post-operative swallowing evaluation and videofluoroscopy. Initial aspiration rates of 20 out of 52 (37 per cent) post-operatively contrasted with 9 out of 52 prior to surgery. Of the latter group, eight patients continued to aspirate after surgery and seven required gastrostomy (all with neurological co-morbidities).Reference Schroeder, Thakkar, Poznanovic and Holinger 54 The same research group retrospectively compared 39 patients undergoing either CO2 laser (n = 21) or cold steel supraglottoplasty (n = 18).Reference Rastatter, Schroeder, Hoff and Holinger 55 The rates of new onset aspiration were 56.3 per cent and 30.8 per cent respectively, but this difference did not achieve statistical significance, and the problem was temporary and easily controlled.

A similar retrospective study did exclude all those with pre-operative swallowing difficulties, to investigate 24 children undergoing supraglottoplasty using a variety of techniques.Reference Chun, Wittkopf, Sulman and Arvedson 56 Unfortunately, only 17 children underwent post-operative swallowing evaluation, but 6 out of 17 did now show swallowing dysfunction. All responded to dietary modification, positioning and anti-reflux management, and showed significant recovery by four weeks.Reference Chun, Wittkopf, Sulman and Arvedson 56 The very limited numbers did not allow any analysis of the relative risks of the various techniques.

A similar favourable long-term outcome was reported in a review of 75 infants following bilateral supraglottoplasty, of whom 48 had no co-morbidities.Reference Eustaquio, Lee and Digoy 57 Of the latter, 46 out of 48 infants had unchanged or improved oral intake. The two infants experiencing a worsening showed a return to normal oral intake by two months. Of the less fortunate infants, with co-morbidities, 22 per cent required dietary modification, nasogastric tube feeding or gastrostomy.Reference Eustaquio, Lee and Digoy 57

Conclusion

The evidence for the efficacy and safety of supraglottoplasty in the management of severe laryngomalacia is sound, if based on limited quality data. High-quality research data prevent many treatment issues from being addressed. The role of reflux and the place of maximal suppression therapy need high-level evidence from well-designed prospective clinical trials. An accepted classification or grading of severity system for laryngomalacia is essential to determine the need for and choice of surgery, and to compare results. Indications for surgery should be clearly stated in cohort studies and case series. Future studies must specify precisely what surgery was performed when describing ‘supraglottoplasty’. Outcomes should provide objective data and be compared with the natural tendency for resolution. The influence of co-morbidities, and of more racially, ethnically and/or socioeconomically diverse study populations, should be clarified.

References

1 Smith, GC, Pell, JP. Parachute use to prevent death and major trauma related to gravitational challenge: systematic review of randomised controlled trials. BMJ 2003;327:1459–61Google Scholar
2 Ellinas, A, Jervis, P, Kenyon, G, Flood, LM. Endoscopic sphenopalatine artery ligation for acute idiopathic epistaxis. Do anatomical variation and a limited evidence base raise questions regarding its place in management? J Laryngol Otol 2017;131:290–7Google Scholar
3 Jackson, C, Jackson, CL. Diseases and Injuries of the Larynx. New York: Macmillan, 1942;63–9Google Scholar
4 Jani, P, Koltai, P, Ochi, JW, Bailey, CM. Surgical treatment of laryngomalacia. J Laryngol Otol 1991;105:1040–5Google Scholar
5 Mckenzie, D. Arytaenoid stridor. J Laryngol Otol 1919;34:449–??CrossRefGoogle Scholar
6 Toynton, SC, Saunders, MW, Bailey, CM. Aryepiglottoplasty for laryngomalacia: 100 consecutive cases. J Laryngol Otol 2001;115:35–8Google Scholar
7 Shamseer, L, Moher, D, Clarke, M, Ghersi, D, Liberati, A, Petticrew, M et al. Preferred reporting items for systematic review and meta-analysis protocols (PRISMA-P) 2015: elaboration and explanation. BMJ 2015;349:g7647 CrossRefGoogle Scholar
8 National Institute for Health and Care Excellence. Assessing the quality of the evidence. In: https://www.nice.org.uk/process/pmg4/chapter/reviewing-the-scientific-evidence#assessing-the-quality-of-the-evidence [20 September 2017]Google Scholar
9 van der Heijden, M, Dikkers, FG, Halmos, GB. The Groningen laryngomalacia classification system--based on systematic review and dynamic airway changes. Pediatr Pulmonol 2015;50:1368–73Google Scholar
10 Manickam, PV, Shott, SR, Boss, EF, Cohen, AP, Meinzen-Derr, JK, Amin, RS et al. Systematic review of site of obstruction identification and non-CPAP treatment options for children with persistent pediatric obstructive sleep apnea. Laryngoscope 2016;126:491500 Google Scholar
11 Farhood, Z, Ong, AA, Nguyen, SA, Gillespie, MB, Discolo, CM, White, DR. Objective outcomes of supraglottoplasty for children with laryngomalacia and obstructive sleep apnea: a meta-analysis. JAMA Otolaryngol Head Neck Surg 2016;142:665–71Google Scholar
12 Camacho, M, Dunn, B, Torre, C, Sasaki, J, Gonzales, R, Liu, SY et al. Supraglottoplasty for laryngomalacia with obstructive sleep apnea: a systematic review and meta-analysis. Laryngoscope 2016;126:1246–55Google Scholar
13 Lee, CF, Hsu, WC, Lee, CH, Lin, MT, Kang, KT. Treatment outcomes of supraglottoplasty for pediatric obstructive sleep apnea: a meta-analysis. Int J Pediatr Otorhinolaryngol 2016;87:1827 Google Scholar
14 May, JG, Shah, P, Lemonnier, L, Bhatti, G, Koscica, J, Coticchia, AM. Systematic review of endoscopic airway findings in children with gastroesophageal reflux disease. Ann Otol Rhinol Laryngol 2011;120:116–22Google Scholar
15 Hartl, TT, Chadha, NK. A systematic review of laryngomalacia and acid reflux. Otolaryngol Head Neck Surg 2012;147:619–26Google Scholar
16 Isaac, A, Zhang, H, Soon, SR, Campbell, S, El-Hakim, H. A systematic review of the evidence on spontaneous resolution of laryngomalacia and its symptoms. Int J Pediatr Otorhinolaryngol 2016;83:7883 Google Scholar
17 Preciado, D, Zalzal, G. A systematic review of supraglottoplasty outcomes. Arch Otolaryngol Head Neck Surg 2012;138:718–21Google Scholar
18 Sivan, Y, Ben-Ari, J, Soferman, R, DeRowe, A. Diagnosis of laryngomalacia by fiberoptic endoscopy: awake compared with anesthesia-aided technique. J Chest 2006;130:1412–18Google Scholar
19 Faria, J, Behar, P. Medical and surgical management of congenital laryngomalacia: a case-control study. Otolaryngol Head Neck Surg 2014;151:845–51Google Scholar
20 van der Heijden, M, Dikkers, FG, Halmos, GB. Treatment outcome of supraglottoplasty vs. wait-and-see policy in patients with laryngomalacia. Eur Arch Otorhinolaryngol 2016;273:1507–13Google Scholar
21 Soong, WJ, Shiao, AS, Jeng, MJ, Lee, YS, Tsao, PC, Yang, CF et al. Comparison between rigid and flexible laser supraglottoplasty in the treatment of severe laryngomalacia in infants. Int J Pediatr Otorhinolaryngol 2011;75:824–9Google Scholar
22 Reddy, DK, Matt, BH. Unilateral vs. bilateral supraglottoplasty for severe laryngomalacia in children. Arch Otolaryngol Head Neck Surg 2001;127:694–9Google Scholar
23 Walner, DL, Neumann, DB, Hamming, KK, Miller, RP. Supraglottoplasty in infants: a staged approach. Ann Otol Rhinol Laryngol 2015;124:803–7CrossRefGoogle ScholarPubMed
24 Meier, JD, Nguyen, SA, White, DR. Improved growth curve measurements after supraglottoplasty. Laryngoscope 2011;121:1574–7Google Scholar
25 Shah, UK, Wetmore, RF. Laryngomalacia: a proposed classification form. Int J Pediatr Otorhinolaryngol 1998;46:21–6Google Scholar
26 Kay, DJ, Goldsmith, AJ. Laryngomalacia: a classification system and surgical treatment strategy. Ear Nose Throat J 2006;85:328–31, 336Google Scholar
27 Lee, KS, Chen, BN, Yang, CC, Chen, YC. CO2 laser supraglottoplasty for severe laryngomalacia: a study of symptomatic improvement. Int J Pediatr Otorhinolaryngol 2007;71:889–95Google Scholar
28 Erickson, B, Cooper, T, El-Hakim, H. Factors associated with the morphological type of laryngomalacia and prognostic value for surgical outcomes. JAMA Otolaryngol Head Neck Surg 2014;140:927–33Google Scholar
29 Kayaykar, R, Gray, RF. Per oral awake flexible fibre-optic laryngoscopy in the investigation of children with stridor without respiratory distress. J Laryngol Otol 2001;115:894–6Google Scholar
30 Loizou, P, Haloob, N, Evgeniou, E. Per-oral flexible laryngoscopy in awake neonates and infants: the ‘pacifier’ technique. J Laryngol Otol 2014;128:169–70Google Scholar
31 Huntley, C, Carr, MM. Evaluation of the effectiveness of airway fluoroscopy in diagnosing patients with laryngomalacia. Laryngoscope 2010;120:1430–4Google Scholar
32 Adil, E, Rager, T, Carr, M. Location of airway obstruction in term and preterm infants with laryngomalacia. Am J Otolaryngol 2012;33:437–40Google Scholar
33 Weinstein, JE, Lawlor, CM, Wu, EL, Rodriguez, KH. Utility of polysomnography in determination of laryngomalacia severity. Int J Pediatr Otorhinolaryngol 2017;93:145–9CrossRefGoogle ScholarPubMed
34 Tanphaichitr, A, Tanphaichitr, P, Apiwattanasawee, P, Brockbank, J, Rutter, MJ, Simakajornboon, N. Prevalence and risk factors for central sleep apnea in infants with laryngomalacia. Otolaryngol Head Neck Surg 2014;150:677–83Google Scholar
35 Simons, JP, Greenberg, LL, Mehta, DK, Fabio, A, Maguire, RC, Mandell, DL. Laryngomalacia and swallowing function in children. Laryngoscope 2016;126:478–84CrossRefGoogle ScholarPubMed
36 Dickson, JM, Richter, GT, Meinzen-Derr, J, Rutter, MJ, Thompson, DM. Secondary airway lesions in infants with laryngomalacia. Ann Otol Rhinol Laryngol 2009;118:3743 Google Scholar
37 Hseu, A, Recko, T, Jennings, R, Nuss, R. Upper airway anomalies in congenital tracheoesophageal fistula and esophageal atresia patients. Ann Otol Rhinol Laryngol 2015;124:808–13Google Scholar
38 Edmondson, NE, Bent, JP 3rd, Chan, C. Laryngomalacia: the role of gender and ethnicity. Int J Pediatr Otorhinolaryngol 2011;75:1562–4CrossRefGoogle ScholarPubMed
39 Wright, CT, Goudy, SL. Congenital laryngomalacia: symptom duration and need for surgical intervention. Ann Otol Rhinol Laryngol 2012;121:5760 Google Scholar
40 Garritano, FG, Carr, MM. Characteristics of patients undergoing supraglottoplasty for laryngomalacia. Int J Pediatr Otorhinolaryngol 2014;78:1095–100Google Scholar
41 Reinhard, A, Gorostidi, F, Leishman, C, Monnier, P, Sandu, K. Laser supraglottoplasty for laryngomalacia; a 14 year experience of a tertiary referral center. Eur Arch Otorhinolaryngol 2017;274:367–74Google Scholar
42 Groblewski, JC, Shah, RK, Zalzal, GH. Microdebrider-assisted supraglottoplasty for laryngomalacia. Ann Otol Rhinol Laryngol 2009;118:592–7Google Scholar
43 Fordham, MT, Potter, SM, White, DR. Postoperative management following supraglottoplasty for severe laryngomalacia. Laryngoscope 2013;123:3206–10Google Scholar
44 Albergotti, WG, Sturm, JJ, Stapleton, AS, Simons, JP, Mehta, DK, Chi, DH. Predictors of intensive care unit stay after pediatric supraglottoplasty. JAMA Otolaryngol Head Neck Surg 2015;141:704–9Google Scholar
45 Douglas, CM, Shafi, A, Higgins, G, Blackmore, K, Wynne, DM, Kubba, H et al. Risk factors for failure of supraglottoplasty. Int J Pediatr Otorhinolaryngol 2014;78:1485–8Google Scholar
46 Day, KE, Discolo, CM, Meier, JD, Wolf, BJ, Halstead, LA, White, DR. Risk factors for supraglottoplasty failure. Otolaryngol Head Neck Surg 2012;146:298301 Google Scholar
47 Durvasula, VS, Lawson, BR, Bower, CM, Richter, GT. Supraglottoplasty outcomes in neurologically affected and syndromic children. JAMA Otolaryngol Head Neck Surg 2014;140:704–11Google Scholar
48 Durvasula, VS, Lawson, BR, Bower, CM, Richter, GT. Supraglottoplasty in premature infants with laryngomalacia: does gestation age at birth influence outcomes? Otolaryngol Head Neck Surg 2014;150:292–9Google Scholar
49 Cockerill, CC, Frisch, CD, Rein, SE, Orvidas, LJ. Supraglottoplasty outcomes in children with Down syndrome. Int J Pediatr Otorhinolaryngol 2016;87:8790 Google Scholar
50 Czechowicz, JA, Chang, KW. Catch-up growth in infants with laryngomalacia after supraglottoplasty. Int J Pediatr Otorhinolaryngol 2015;79:1333–6Google Scholar
51 Anderson de Moreno, LC, Burgin, SJ, Matt, BH. The incidence of postoperative aspiration among children undergoing supraglottoplasty for laryngomalacia. Ear Nose Throat J 2015;94:320–8Google Scholar
52 Anderson de Moreno, LC, Matt, BH. The effects of prematurity on incidence of aspiration following supraglottoplasty for laryngomalacia. Laryngoscope 2014;124:777–80Google Scholar
53 Richter, GT, Wootten, CT, Rutter, MJ, Thompson, DM. Impact of supraglottoplasty on aspiration in severe laryngomalacia. Ann Otol Rhinol Laryngol 2009;118:259–66Google Scholar
54 Schroeder, JW Jr, Thakkar, KH, Poznanovic, SA, Holinger, LD. Aspiration following CO(2) laser-assisted supraglottoplasty. Int J Pediatr Otorhinolaryngol 2008;72:985–90Google Scholar
55 Rastatter, JC, Schroeder, JW, Hoff, SR, Holinger, LD. Aspiration before and after supraglottoplasty regardless of technique. Int J Otolaryngol 2010;2010:912814 Google Scholar
56 Chun, RH, Wittkopf, M, Sulman, C, Arvedson, J. Transient swallowing dysfunction in typically developing children following supraglottoplasty for laryngomalacia. Int J Pediatr Otorhinolaryngol 2014;78:1883–5Google Scholar
57 Eustaquio, M, Lee, EN, Digoy, GP. Feeding outcomes in infants after supraglottoplasty. Otolaryngol Head Neck Surg 2011;145:818–22Google Scholar
58 Carter, J, Rahbar, R, Brigger, M, Chan, K, Cheng, A, Daniel, SJ et al. International Pediatric ORL Group (IPOG) laryngomalacia consensus recommendations. Int J Pediatr Otorhinolaryngol 2016;86:256–61Google Scholar
59 Ramprasad, VH, Ryan, MA, Farjat, AE, Eapen, RJ, Raynor, EM. Practice patterns in supraglottoplasty and perioperative care. Int J Pediatr Otorhinolaryngol 2016;86:118–23CrossRefGoogle ScholarPubMed
60 Kilpatrick, LA, Boyette, JR, Hartzell, LD, Norton, JA, Boswell, JB, Bower, CM et al. Prospective quality of life assessment in congenital laryngomalacia. Int J Pediatr Otorhinolaryngol 2014;78:583–7Google Scholar
61 Thottam, PJ, Simons, JP, Choi, S, Maguire, R, Mehta, DK. Clinical relevance of quality of life in laryngomalacia. Laryngoscope 2016;126:1232–5Google Scholar