Socioeconomic Disparities and Other Factors Affecting Time to Dispensing of Pediatric Hearing Aids.

INTRODUCTION: Pediatric hearing loss can significantly impact speech, language, social, and educational development. Providing access to speech and environmental sounds using amplification devices, such as hearing aids, can help improve developmental outcomes. However, timely rehabilitation and intervention may be delayed due to limited access to resources, further prolonging the adverse effects of childhood hearing loss. The aim of this study was to investigate socioeconomic barriers in time to dispensing hearing aids in a diverse pediatric patient population. METHODS: Data from an existing internal database from a tertiary pediatric hospital were analyzed from January 2020 through August 2022 for barriers associated with hearing aid (HA) dispensing delays. Demographic and clinical characteristics were obtained. Multivariate regression and survival analysis statistics were used to identify factors associated with delayed time to dispensing hearing aids. RESULTS: Of the 121 patients who had been appropriately diagnosed and fit, 108 (89.3%) had received hearings aids and 13 (10.7%) had not at the time of the study. Of those who had received HA, time to dispensing was not significantly impacted by sex, race, ethnicity, language, or income level. Insurance was found to be an influencing factor in time to receiving the HA. CONCLUSION: Factors such as insurance and hearing loss laterality contribute to delays in receiving hearing aids. Identifying these specific barriers and disparities in hearing rehabilitation services will prove vital in facilitating an expedited and equitable pathway to receiving hearing aids. LEVEL OF EVIDENCE: 3 Laryngoscope, 2024.

Barriers to auditory brainstem response testing under anesthesia.

OBJECTIVE: Auditory brainstem response (ABR) testing is the gold standard for diagnosis of hearing loss in children who cannot complete behavioral audiometry. Testing under general anesthesia is often recommended when natural sleep ABR and/or behavioral audiometry are unsuccessful. This study aims to determine which demographic and patient factors serve as barriers to receiving this diagnostic testing. METHODS: A retrospective chart review from an internal database of patients who underwent ABR testing under anesthesia from 2017 to 2023 was completed. Patient demographics, clinical diagnoses, dates of initial recommendation, and dates of testing were recorded. RESULTS: A total of 395 patients met inclusion criteria, with a median time from initial evaluation to successful ABR under anesthesia of 5.1 months (range 0.1-209 months). This time was significantly higher in patients with public insurance compared to private insurance and in patients with the following medical complexities: cardiac disease, developmental delay, neurologic disease, eye disease, and genetic syndromes not associated with hearing loss. The interval was significantly shorter in patients with abnormal ear anatomy. CONCLUSION: Patient factors, such as insurance type and certain medical diagnoses, may lead to delayed ABR testing under anesthesia and thus delayed diagnosis and management of hearing loss. This has implications for the timely care and treatment of children with hearing loss.

Evaluation of Cochlear Implantation in Children With Cochlear Nerve Absence or Deficiency.

OBJECTIVE: To identify associations between cochleovestibular anatomy findings and hearing outcomes found in children with imaging evidence of an absent or hypoplastic cochlear nerve treated with cochlear implantation (CI). STUDY DESIGN: retrospective review. SETTING: Cochlear implant program at tertiary care center. METHODS: A retrospective review was performed to identify children with imaging evidence of cochlear nerve absence or deficiency who underwent CI evaluation. High-resolution 3-dimensional T2-weighted magnetic resonance imaging in the oblique sagittal and axial planes were reviewed by a neuroradiologist to identify cochleovestibular anatomy. Hearing was assessed pre and postoperatively with Speech Perception Category scores. RESULTS: Seven CI recipients were identified (n = 10 ears) who had bilateral severe to profound sensorineural hearing loss with lack of auditory development with binaural hearing aid trial and imaging evidence of cochlear nerve aplasia/hypoplasia. All ears had 2 nerves in the cerebellopontine angle (100%, n = 10), half of the ears had evidence of 2 or less nerves in the internal auditory canal (IAC). All children showed large improvement in speech perception after CI. CONCLUSION: Our experience with CIs for children with absent or hypoplastic cochlear nerves demonstrates that CI can be a viable option in select patients who satisfy preoperative audiological criteria. Radiological identification of a hypoplastic or aplastic cochlear nerve does not preclude auditory innervation of the cochlea. CI recipients in this subgroup must be counseled on difficulty in predicting postimplantation language and speech outcomes, and cautioned about facial nerve stimulation.

Systematic Review of Slide Tracheoplasty Outcomes.

OBJECTIVE: To identify factors predicting success in slide tracheoplasty surgery at a regional children's hospital and compare with available published literature. MEASURES: Retrospective chart review comparing demographics (age, weight) and clinical (operative and hospital course, need for additional airway intervention) factors experienced with slide tracheoplasty. Findings were compared with a systematic review of published literature. RESULTS: Of the 16 tracheal stenosis patients in our cohort, 13 (81.3%) presented with an additional congenital or cardiovascular anomaly. When adjusted for cardiovascular anomalies, congenital tracheal stenosis patients had a mean age of 5.2 months (range 6 days-17 months), mean weight of 5.04 kg, and average ICU and hospital length of stay of 31.5 and 36.0 days, respectively. Tracheostomy was required for 4 patients and no early deaths were recorded. Of the 391 children in the grouped cohort, mean age and weight was older at 7.67 months and larger at 5.70 kg. Length of stay in both ICU and overall hospital course was 31.6 and 43.5 days, respectively. Mortality etiology for 44 patients was reported: 17 (38.6%) cardiac-related and 28 (63.6%) late mortalities. Our overall calculated mortality risk of 1.26 (P < .05) was lower than reported ratios of 2.0+. CONCLUSION: Despite the numerous institutional studies involving tracheal stenosis, mortality and surgical challenges remain high. Future studies with the inclusion of specific perioperative data can prove to further evaluate correlations between presentation characteristics and mortality.

Confirmatory Auditory Brainstem Responses Testing Results in Discordant Outcomes: Implications for Timely Care.

OBJECTIVES: The purpose of this study is to evaluate for discrepancies in diagnostic auditory brainstem responses (ABR) between Children's National Hospital (CNH), a pediatric medical center, and outside facilities (OSF) that referred patients to CNH for confirmatory evaluation. Such discrepancies impact early hearing detection and intervention (EHDI) timelines. METHODS: A retrospective chart review was conducted from an internal database of patients who underwent diagnostic ABR from 2017 to 2021. Only patients with ABR results from both CNH and OSF were analyzed. Demographic data, external and internal test results, and intervention data were obtained. Hearing loss (HL) severity was graded on a scale of 0 to 8, where 0 indicated normal hearing and 8 indicated profound. Each ear was analyzed separately. RESULTS: Forty-nine patients met the inclusion criteria, and each ear was evaluated separately. Median HL severity was 1.0 [0.0, 4.3] at CNH compared to 3.0 [1.8, 6] at OSF (p = 0.004). Forty-seven ears (48.0%) showed lower severity at CNH. Twenty-seven patients (55%) received hearing amplification devices. The median age at time of hearing intervention was 220 days. CONCLUSION: Our results showed statistical significance in the median severity of HL between CNH and OSF. A substantial proportion (70%) of children in our dataset who received amplification via cochlear implant or hearing aids were shown to have discrepancies in ABR findings from CNH and OSF. These findings have implications with regards to the appropriate usage of health care resources and maintaining EDHI timelines. LEVEL OF EVIDENCE: 4 (Retrospective Cohort Study) Laryngoscope, 133:3571-3574, 2023.

Tracheostomy in the extremely premature neonate - Long term outcomes in a multi-institutional study.

OBJECTIVES: To describe the long-term outcomes related to breathing, feeding, and neurocognitive development in extremely premature infants requiring tracheostomy. STUDY DESIGN: Pooled cross-sectional survey. SETTING: Multi-institutional academic children's hospitals. METHODS: Extremely premature infants who underwent tracheostomy between January 1, 2012, and December 31, 2019, at four academic hospitals were identified from an existing database. Information was gathered from responses to a questionnaire by caregivers regarding airway status, feeding, and neurodevelopment 2-9 years after tracheostomy. RESULTS: Data was available for 89/91 children (96.8%). The mean gestational age was 25.5 weeks (95% CI 25.2-25.7) and mean birth weight was 0.71 kg (95% CI 0.67-0.75). Mean post gestational age at tracheostomy was 22.8 weeks (95% CI 19.0-26.6). At time of the survey, 18 (20.2%) were deceased. 29 (40.8%) maintained a tracheostomy, 18 (25.4%) were on ventilatory support, and 5 (7%) required 24-h supplemental oxygen. Forty-six (64.8%) maintained a gastrostomy tube, 25 (35.2%) had oral dysphagia, and 24 (33.8%) required a modified diet. 51 (71.8%) had developmental delay, 45 (63.4%) were enrolled in school of whom 33 (73.3%) required special education services. CONCLUSIONS: Tracheostomy in extremely premature neonates is associated with long term morbidity in the pulmonary, feeding, and neurocognitive domains. At time of the survey, about half are decannulated, with a majority weaned off ventilatory support indicating improvement in lung function with age. Feeding dysfunction is persistent, and a significant number will have some degree of neurocognitive dysfunction at school age. This information may help caregivers regarding expectations and plans for resource management.

"Natural" decannulation in patients with Robin sequence and severe airway obstruction.

OBJECTIVES: Airway management in infants with Robin sequence (RS) remains controversial, ranging from conservative to operative methods. In some centers, tracheostomy remains the mainstay for those infants with severe respiratory obstruction. The goals of this retrospective case cohort study were to determine the length of time to decannulation without further surgical intervention (ie, "natural" decannulation) in patients with severe RS who underwent tracheostomy and to investigate potential factors associated with successful decannulation. METHODS: We reviewed all infants with RS treated at a large tertiary center from 1994 to 2010. Patients who had undergone tracheostomy were identified. Baseline demographics, complications, deaths, and time to "natural" decannulation were recorded. Statistical analysis was performed with univariate analysis and Kaplan-Meier log-rank tests. RESULTS: Of 61 infants with RS with obstructive events, 25 infants (14 with isolated RS and 11 with syndromic RS) required tracheostomy. At a mean follow-up of 4 years, the rate of tracheostomy-specific complications was 52%; the tracheostomy-specific mortality rate was 12%. Overall, 13 of 25 infants (52%) were "naturally" decannulated, with a median time to decannulation of 97 months. Patients with syndromic RS had a significantly longer median time to decannulation than did those with isolated RS (more than 73 months versus 19 months, respectively; p = 0.019). In addition, patients with long-term tracheostomy dependence had significantly higher maximum carbon dioxide levels before tracheostomy than did patients who were successfully decannulated (82.4 versus 63.2 mEq/L, respectively; p = 0.02). CONCLUSIONS: Tracheostomy in infants with RS is associated with inordinately high rates of mortality, morbidity, and long-term tracheostomy dependence, particularly in patients with syndromic RS and in those with high maximum carbon dioxide levels before tracheostomy.

Deep Learning for Predictive Analysis of Pediatric Otolaryngology Personal Statements: A Pilot Study.

OBJECTIVE: The personal statement is often an underutilized aspect of pediatric otolaryngology fellowship applications. In this pilot study, we use deep learning language models to cluster personal statements and elucidate their relationship to applicant rank position and postfellowship research output. STUDY DESIGN: Retrospective cohort. SETTING: Single pediatric tertiary care center. METHODS: Data and personal statements from 115 applicants to our fellowship program were retrieved from San Francisco Match. BERT (Bidirectional Encoder Representations From Transformers) was used to generate document embeddings for clustering. Regression and machine learning models were used to assess the relationship of personal statements to number of postfellowship publications per year when controlling for publications, board scores, Alpha Omega Alpha status, gender, and residency. RESULTS: Document embeddings of personal statements were found to cluster into 4 distinct groups by K-means clustering: 2 focused on "training/research" and 2 on "personal/patient anecdotes." Training clusters 1 and 2 were associated with an applicant-organization fit by a single pediatric otolaryngology fellowship program on univariate but not multivariate analysis. Models utilizing document embeddings alone were able to equally predict applicant-organization fit (receiver operating characteristic areas under the curve, 0.763 and 0.750 vs 0.419; P values >.05) as compared with models utilizing applicant characteristics and personal statement clusters alone. All predictive models were poor predictors of postfellowship publications per year. CONCLUSION: We demonstrate ability for document embeddings to capture meaningful information in personal statements from pediatric otolaryngology fellowship applicants. A larger study can further differentiate personal statement clusters and assess the predictive potential of document embeddings.

Barriers to Pediatric Osseointegrated Bone-Conduction Hearing Devices.

OBJECTIVE: To identify social, demographic, and clinical barriers for implantation with Osseointegrated Bone Conduction Devices (OBCD) in pediatric candidates. STUDY DESIGN: Retrospective cohort study of 94 children who met standard OBCD implantation criteria. SETTING: Tertiary stand-alone children's hospital. MATERIALS AND METHODS: Retrospective chart review comparing demographic (age, race, state of residence, and insurance) and clinical (severity and etiology of hearing loss, medical comorbidities, and early intervention) factors impacting implantation. Members of the existing cohort were then contacted to obtain a better understanding of qualitative factors impacting surgical decision. RESULTS: Of the identified 94 surgical candidates, 47 (50%) underwent OBCD implantation. State of residence significantly impacted implantation rates, with children from the District of Columbia and Virginia being less likely to receive an implant than those from Maryland. Private insurance, race, and ethnicity did not impact rate of implantation (OR 2.8 [95% CI 0.78-10]; 1.34 [95% CI 0.44-3.68]; and 1.0 [95% CI 0.42-2.43], respectively). Children with anotia or microtia and children younger than 10 years old were less likely to have an implant (OR 10.6 (95% CI 1.74-65). Thirty-nine children participated in the qualitative portion. Themes that emerged as reasons to forgo implantation included a child's young age, planned reconstruction for microtia or atresia, and overall device functionality and usage. Thirtyseven children (39%) of the cohort declined surgery and currently wear a nonsurgical bone conduction aid regularly. CONCLUSION: Despite known benefits of implantation, only one-half of children who were candidates underwent OBCD. Unlike cochlear implantation, where insurance status is a major risk factor for implantation delay and underperformance, for OBCD, implantation barriers appear to be more multifactorial and include medical, demographic, and social factors.

Clinical Practice Guideline: Tympanostomy Tubes in Children (Update).

OBJECTIVE: Insertion of tympanostomy tubes is the most common ambulatory surgery performed on children in the United States. Tympanostomy tubes are most often inserted because of persistent middle ear fluid, frequent ear infections, or ear infections that persist after antibiotic therapy. All these conditions are encompassed by the term otitis media (middle ear inflammation). This guideline update provides evidence-based recommendations for patient selection and surgical indications for managing tympanostomy tubes in children. The guideline is intended for any clinician involved in managing children aged 6 months to 12 years with tympanostomy tubes or children being considered for tympanostomy tubes in any care setting as an intervention for otitis media of any type. The target audience includes specialists, primary care clinicians, and allied health professionals. PURPOSE: The purpose of this clinical practice guideline update is to reassess and update recommendations in the prior guideline from 2013 and to provide clinicians with trustworthy, evidence-based recommendations on patient selection and surgical indications for managing tympanostomy tubes in children. In planning the content of the updated guideline, the guideline update group (GUG) affirmed and included all the original key action statements (KASs), based on external review and GUG assessment of the original recommendations. The guideline update was supplemented with new research evidence and expanded profiles that addressed quality improvement and implementation issues. The group also discussed and prioritized the need for new recommendations based on gaps in the initial guideline or new evidence that would warrant and support KASs. The GUG further sought to bring greater coherence to the guideline recommendations by displaying relationships in a new flowchart to facilitate clinical decision making. Last, knowledge gaps were identified to guide future research. METHODS: In developing this update, the methods outlined in the American Academy of Otolaryngology-Head and Neck Surgery Foundation's "Clinical Practice Guideline Development Manual, Third Edition: A Quality-Driven Approach for Translating Evidence Into Action" were followed explicitly. The GUG was convened with representation from the disciplines of otolaryngology-head and neck surgery, otology, pediatrics, audiology, anesthesiology, family medicine, advanced practice nursing, speech-language pathology, and consumer advocacy. ACTION STATEMENTS: The GUG made strong recommendations for the following KASs: (14) clinicians should prescribe topical antibiotic ear drops only, without oral antibiotics, for children with uncomplicated acute tympanostomy tube otorrhea; (16) the surgeon or designee should examine the ears of a child within 3 months of tympanostomy tube insertion AND should educate families regarding the need for routine, periodic follow-up to examine the ears until the tubes extrude.The GUG made recommendations for the following KASs: (1) clinicians should not perform tympanostomy tube insertion in children with a single episode of otitis media with effusion (OME) of less than 3 months' duration, from the date of onset (if known) or from the date of diagnosis (if onset is unknown); (2) clinicians should obtain a hearing evaluation if OME persists for 3 months or longer OR prior to surgery when a child becomes a candidate for tympanostomy tube insertion; (3) clinicians should offer bilateral tympanostomy tube insertion to children with bilateral OME for 3 months or longer AND documented hearing difficulties; (5) clinicians should reevaluate, at 3- to 6-month intervals, children with chronic OME who do not receive tympanostomy tubes, until the effusion is no longer present, significant hearing loss is detected, or structural abnormalities of the tympanic membrane or middle ear are suspected; (6) clinicians should not perform tympanostomy tube insertion in children with recurrent acute otitis media who do not have middle ear effusion in either ear at the time of assessment for tube candidacy; (7) clinicians should offer bilateral tympanostomy tube insertion in children with recurrent acute otitis media who have unilateral or bilateral middle ear effusion at the time of assessment for tube candidacy; (8) clinicians should determine if a child with recurrent acute otitis media or with OME of any duration is at increased risk for speech, language, or learning problems from otitis media because of baseline sensory, physical, cognitive, or behavioral factors; (10) the clinician should not place long-term tubes as initial surgery for children who meet criteria for tube insertion unless there is a specific reason based on an anticipated need for prolonged middle ear ventilation beyond that of a short-term tube; (12) in the perioperative period, clinicians should educate caregivers of children with tympanostomy tubes regarding the expected duration of tube function, recommended follow-up schedule, and detection of complications; (13) clinicians should not routinely prescribe postoperative antibiotic ear drops after tympanostomy tube placement; (15) clinicians should not encourage routine, prophylactic water precautions (use of earplugs or headbands, avoidance of swimming or water sports) for children with tympanostomy tubes.The GUG offered the following KASs as options: (4) clinicians may perform tympanostomy tube insertion in children with unilateral or bilateral OME for 3 months or longer (chronic OME) AND symptoms that are likely attributable, all or in part, to OME that include, but are not limited to, balance (vestibular) problems, poor school performance, behavioral problems, ear discomfort, or reduced quality of life; (9) clinicians may perform tympanostomy tube insertion in at-risk children with unilateral or bilateral OME that is likely to persist as reflected by a type B (flat) tympanogram or a documented effusion for 3 months or longer; (11) clinicians may perform adenoidectomy as an adjunct to tympanostomy tube insertion for children with symptoms directly related to the adenoids (adenoid infection or nasal obstruction) OR in children aged 4 years or older to potentially reduce future incidence of recurrent otitis media or the need for repeat tube insertion.

Executive Summary of Clinical Practice Guideline on Tympanostomy Tubes in Children (Update).

OBJECTIVE: This executive summary of the guideline update provides evidence-based recommendations for patient selection and surgical indications for managing tympanostomy tubes in children. The summary and guideline are intended for any clinician involved in managing children aged 6 months to 12 years with tympanostomy tubes or children being considered for tympanostomy tubes in any care setting as an intervention for otitis media of any type. The target audience includes specialists, primary care clinicians, and allied health professionals. PURPOSE: The purpose of this executive summary is to provide a succinct overview for clinicians of the key action statements (recommendations), summary tables, and patient decision aids from the update of the American Academy of Otolaryngology-Head and Neck Surgery Foundation's "Clinical Practice Guideline: Tympanostomy Tubes in Children (Update)." The new guideline updates recommendations in the prior guideline from 2013 and provides clinicians with trustworthy, evidence-based recommendations on patient selection and surgical indications for managing tympanostomy tubes in children. This summary is not intended to substitute for the full guideline, and clinicians are encouraged to read the full guideline before implementing the recommended actions. METHODS: The guideline on which this summary is based was developed using methods outlined in the American Academy of Otolaryngology-Head and Neck Surgery Foundation's "Clinical Practice Guideline Development Manual, Third Edition: A Quality-Driven Approach for Translating Evidence Into Action," which were followed explicitly. The guideline update group represented the disciplines of otolaryngology-head and neck surgery, otology, pediatrics, audiology, anesthesiology, family medicine, advanced practice nursing, speech-language pathology, and consumer advocacy. ACTION STATEMENTS: Strong recommendations were made for the following key action statements: (14) Clinicians should prescribe topical antibiotic ear drops only, without oral antibiotics, for children with uncomplicated acute tympanostomy tube otorrhea. (16) The surgeon or designee should examine the ears of a child within 3 months of tympanostomy tube insertion AND should educate families regarding the need for routine, periodic follow-up to examine the ears until the tubes extrude.Recommendations were made for the following key action statements: (1) Clinicians should not perform tympanostomy tube insertion in children with a single episode of otitis media with effusion (OME) of less than 3 months' duration, from the date of onset (if known) or from the date of diagnosis (if onset is unknown). (2) Clinicians should obtain a hearing evaluation if OME persists for 3 months or longer OR prior to surgery when a child becomes a candidate for tympanostomy tube insertion. (3) Clinicians should offer bilateral tympanostomy tube insertion to children with bilateral OME for 3 months or longer AND documented hearing difficulties. (5) Clinicians should reevaluate, at 3- to 6-month intervals, children with chronic OME who do not receive tympanostomy tubes, until the effusion is no longer present, significant hearing loss is detected, or structural abnormalities of the tympanic membrane or middle ear are suspected. (6) Clinicians should not perform tympanostomy tube insertion in children with recurrent acute otitis media (AOM) who do not have middle ear effusion (MEE) in either ear at the time of assessment for tube candidacy. (7) Clinicians should offer bilateral tympanostomy tube insertion in children with recurrent AOM who have unilateral or bilateral MEE at the time of assessment for tube candidacy. (8) Clinicians should determine if a child with recurrent AOM or with OME of any duration is at increased risk for speech, language, or learning problems from otitis media because of baseline sensory, physical, cognitive, or behavioral factors. (10) The clinician should not place long-term tubes as initial surgery for children who meet criteria for tube insertion unless there is a specific reason based on an anticipated need for prolonged middle ear ventilation beyond that of a short-term tube. (12) In the perioperative period, clinicians should educate caregivers of children with tympanostomy tubes regarding the expected duration of tube function, recommended follow-up schedule, and detection of complications. (13) Clinicians should not routinely prescribe postoperative antibiotic ear drops after tympanostomy tube placement. (15) Clinicians should not encourage routine, prophylactic water precautions (use of earplugs or headbands, avoidance of swimming or water sports) for children with tympanostomy tubes.Options were offered from the following key action statements: (4) Clinicians may perform tympanostomy tube insertion in children with unilateral or bilateral OME for 3 months or longer (chronic OME) AND symptoms that are likely attributable, all or in part, to OME that include, but are not limited to, balance (vestibular) problems, poor school performance, behavioral problems, ear discomfort, or reduced quality of life. (9) Clinicians may perform tympanostomy tube insertion in at-risk children with unilateral or bilateral OME that is likely to persist as reflected by a type B (flat) tympanogram or a documented effusion for 3 months or longer. (11) Clinicians may perform adenoidectomy as an adjunct to tympanostomy tube insertion for children with symptoms directly related to the adenoids (adenoid infection or nasal obstruction) OR in children aged 4 years or older to potentially reduce future incidence of recurrent otitis media or the need for repeat tube insertion.

Barriers to Decannulation After Double-Stage Laryngotracheal Reconstruction.

OBJECTIVES/HYPOTHESIS: To identify any potential barriers for decannulation in children undergoing double-staged laryngotracheal reconstruction (dsLTR) beyond the severity of disease itself. STUDY DESIGN: Case series with chart review. METHODS: We performed a retrospective chart review from 2008 to 2018 of 41 children who had undergone dsLTR as primary treatment for laryngotracheal stenosis at a stand-alone tertiary children's hospital. We examined the effect of demographic, medical, and surgical factors on successful decannulation and time to decannulation after dsLTR. RESULTS: Of the 41 children meeting inclusion criteria who underwent dsLTR, 34 (82%) were decannulated. Age, gender, race, insurance status, medical comorbidity, and multilevel stenosis did not predict overall decannulation. Insurance status did not impact time to decannulation (P = .13, Log-rank). Factors that increased length of time to decannulation were the use of anterior and posterior cartilage grafts (P = .001, Log-rank), history of pulmonary disease (P = .05, Log rank), history of cardiac disease (P = .017, Log-rank), and race/ethnicity (P = .001 Log-rank). CONCLUSION: In a cohort with a similar decannulation rates to previous dsLTR cohorts, we identified no demographic or medical factors that influenced overall decannulation. We did observe that pulmonary comorbidity, cardiac comorbidity, and race/ethnicity lengthens time to decannulation. LEVEL OF EVIDENCE: 4 Laryngoscope, 131:2141-2147, 2021.

Sistrunk vs modified Sistrunk procedures: Does procedure type matter?

BACKGROUND: Thyroglossal Duct Cyst (TDC) is the most common congenital neck mass in children and is surgically managed with a Sistrunk procedure. Some surgeons perform a modified Sistrunk (mSis), involving the dissection of the fistula beyond the hyoid bone without coring out the foramen cecum at the base of the tongue. We aim to evaluate surgical outcomes of children undergoing Sistrunk (Sis) or modified Sistrunk (mSis) procedures for TDC at an academic pediatric institution. MATERIALS AND METHODS: We conducted a retrospective chart review of the Children's National Medical Center database from 2004 to 2014. Basic demographic information, preoperative characteristics, postoperative complications, and recurrence were extracted for children diagnosed with TDC. We estimated descriptive statistics using Kruskal-Wallis tests and Pearson's chi-square for continuous and categorical values. RESULTS: 157 patients that underwent TDC excision were identified. Sistrunk (Sis) was performed in 52 cases (33%) and modified Sistrunk (mSis) performed in 105 (67%) cases. 84 (54%) were female and the mean age at surgery was 5.4 years (SD=4.5). Overall recurrence was detected in 8 cases (5.1%) and did not differ significantly by procedure type [2 (4%) in Sis and 6 (6%) in mSis, p = 0.616]. Post-operative complications did not differ significantly between Sis and mSis procedure: swelling [6 (12%) and 18 (17%), p = 0.481]; seroma [5 (10%) and 10 (10%), p = 1.00]; surgical site infection [3 (6%) and 8 (8%), p = 0.752]; or post-excision incision and drainage [3 (6%) and 9 (9%), p = 0.752] (respectively). CONCLUSIONS: Our findings reveal no statistical difference in recurrence rates between Sis and mSis with no risk factors for recurrence identified. Furthermore, there was no difference in post-operative complications between the groups. Both surgical procedures were associated with few complications and low recurrence.

Lower respiratory tract infections in early life are associated with obstructive sleep apnea diagnosis during childhood in a large birth cohort.

STUDY OBJECTIVES: Several birth cohorts have defined the pivotal role of early lower respiratory tract infections (LRTI) in the inception of pediatric respiratory conditions. However, the association between early LRTI and the development of obstructive sleep apnea (OSA) in children has not been established. METHODS: To investigate whether early LRTIs increase the risk of pediatric OSA, we analyzed clinical data in children followed during the first 5 years in the Boston Birth Cohort (n = 3114). Kaplan-Meier survival estimates and Cox proportional hazards models adjusted by pertinent covariates were used to evaluate the risk of OSA by the age of 5 years between children with LRTI during the first 2 years of life in comparison to those without LRTI during this period. RESULTS: Early life LRTI increased the risk of pediatric OSA independently of other pertinent covariates and risk factors (hazard ratio, 1.53; 95% CI, 1.15 to 2.05). Importantly, the association between LRTI and pediatric OSA was limited to LRTIs occurring during the first 2 years of life. Complementarily to this finding, we observed that children who had severe respiratory syncytial virus bronchiolitis during infancy had two times higher odds of OSA at 5 years in comparison with children without this exposure (odds ratio, 2.09; 95% CI, 1.12 to 3.88). CONCLUSIONS: Children with severe LRTIs in early life have significantly increased risk of developing OSA during the first 5 years of life. Our results offer a new paradigm for investigating novel mechanisms and interventions targeting the early pathogenesis of OSA in the pediatric population.

Tracheostomy on infants born in the periviable period: Outcomes at discharge from the neonatal intensive care unit (NICU).

OBJECTIVES: Advances in neonatal intensive care have allowed successful resuscitation of children born at the border of viability. However, there has been little change in the incidence of bronchopulmonary dysplasia (BPD) and anatomical upper airway obstruction which may require a tracheostomy in that group. The benefits of the procedure are accompanied by sequelae that impact outcomes. Information about these issues can assist caregivers in making decisions and planning care after discharge from the neonatal intensive care unit (NICU). The objectives of this study were to describe the clinical characteristics of neonates born in the periviable period (≤25 weeks gestation) requiring tracheotomy and to highlight their hospital course, complications and status upon NICU discharge. METHODS: Retrospective analysis at four tertiary care academic children's hospitals. Medical records of neonates born ≤25 weeks gestation who required tracheotomy between January 1, 2012 and December 31, 2018 were reviewed. Demographics, medical comorbidities, and tracheostomy related complications were studied. Feeding, ventilation, and neurodevelopmental outcomes at time of transfer from NICU were evaluated. RESULTS: Fifty-two patients were included. The mean gestational age was 24.3 (95% confidence interval, 24.1 to 24.5) weeks. The mean birth weight was 635 (95% CI: 603 to 667) grams and 50 (96.2%) children had BPD. At time of discharge from the NICU, 47 (90.4%) required mechanical ventilation, four (7.7%) required supplemental oxygen and one (1.9%) was weaned to room air. Forty-two (80.8%) were discharged with a gastrostomy tube, seven (28%) with a nasogastric tube, and three (5.8%) were on oral feeds. Two (3.8%) suffered hypoxic ischemic encephalopathy, 27 (51.9%) had neurodevelopmental delay, seven (13.5%) were diagnosed with another anomaly, and 16 (30.8%) were considered normal. Complications related to the procedure were observed in 28 (53.8%) neonates. Granulation tissue was seen in 17 (32.7%), wound break down or cellulitis in three (5.8%), one (1.9%) with tracheostomy plugging, three (5.8%) with dislodgement of the tracheostomy tube and four (7.7%) developed tracheitis. CONCLUSIONS: Tracheostomy in infants born in the periviable period is primarily performed for BPD and portends extended ventilatory dependence. It is associated with non-oral alimentation at the time of discharge from the NICU and developmental delay. Mortality directly related to the procedure is rare. Minor complications are common but do not require surgical intervention. These data may aid in counseling caregivers about the procedure in this vulnerable population.

Defining the patterns of PAP adherence in pediatric obstructive sleep apnea: a clustering analysis using real-world data.

STUDY OBJECTIVES: The implementation of positive airway pressure (PAP) therapy to treat obstructive sleep apnea in children is a complex process. PAP therapy data are highly heterogeneous in pediatrics, and the clinical management cannot be generalized. We hypothesize that pediatric PAP users can be subgrouped via clustering analysis to guide tailored interventions. METHODS: PAP therapy data for 250 children with obstructive sleep apnea were retrospectively examined using unsupervised hierarchical cluster analysis based on (1) PAP tolerance (average hours on days used) and (2) consistency of PAP use (percentage of days used). Clinical features in each cluster were defined, and a tree decision analysis was generated for clinical implementation. RESULTS: We were able to subclassify all 250 children (median age = 11.5 years) into five clusters: A (13.6%), B (29.6%), C (17.6%), D (16.4%), and E (22.8%). The clusters showed significant differences in PAP use patterns (Kruskal-Wallis P value < 1e-16). The most consistent PAP use patterns were seen in clusters A, B, and C. Major differences across clusters included the prevalence of obesity, PAP setting, developmental delay, and adenotonsillectomy. We also identified important differences in mask acceptance, OSA severity, and individual responses to PAP therapy based on objective apnea-hypopnea reductions in PAP downloads. CONCLUSIONS: A simple method to subset PAP use patterns in children can be implemented by analyzing cloud-based PAP therapy data. This novel approach may contribute to optimization of PAP therapy in children of all ages based on real-world evidence at the individual level.

Tracheostomy in the Extremely Premature Neonate: A Multi-Institutional Study.

OBJECTIVE: (1) To describe characteristics associated with tracheostomy placement and (2) to describe associated in-hospital morbidity in extremely premature infants. STUDY DESIGN: Pooled retrospective analysis of charts. SETTING: Academic children's hospitals. SUBJECTS AND METHODS: The patient records of premature infants (23-28 weeks gestational age) who underwent tracheostomy between January 1, 2012, and December 31, 2017, were reviewed from 4 academic children's hospitals. Demographics, procedural morbidity, feeding, respiratory, and neurodevelopmental outcomes at the time of transfer from the neonatal intensive care unit (NICU) were obtained. The contribution of baseline characteristics to mortality, neurodevelopmental, and feeding outcomes was also assessed. RESULTS: The charts of 119 infants were included. The mean gestational age was 25.5 (95% confidence interval, 25.2-25.7) weeks. The mean birth weight was 712 (671-752) g. Approximately 50% was African American. The principal comorbidity was chronic lung disease (92.4%). Overall, 60.5% of the infants had at least 1 complication. At the time of transfer, most remained mechanically ventilated (94%) and dependent on a feeding tube (90%). Necrotizing enterocolitis increased the risk of feeding impairment (P = .002) and death (P = .03). CONCLUSIONS: Tracheostomy in the extremely premature neonate is primarily performed for chronic lung disease. Complications occur frequently, with skin breakdown being the most common. Placement of a tracheostomy does not seem to mitigate the systemic morbidity associated with extreme prematurity.

Management of pediatric orbital cellulitis in patients with radiographic findings of subperiosteal abscess.

OBJECTIVE: Controversies remain regarding the management of orbital cellulitis (OC). The objective of this study was to examine the outcomes of patients admitted to our institution for orbital cellulitis during a 7-year period. STUDY DESIGN: Case series with chart review. SETTING: Tertiary referral pediatric hospital. SUBJECTS AND METHODS: Charts of 465 consecutive OC admissions were reviewed for presentation, imaging, medical and surgical treatment, and outcome. RESULTS: Of these patients, 189 were treated in the emergency room and 276 were admitted. CT scan was performed on 240 patients. Subperiosteal abscess (SPA) was noted in 68 patients. Of these, 47 were treated medically and 21 had surgery. Surgical patients were older (8.3 vs 6.2 years, P = 0.039), had larger abscesses (>10 mm, P < 0.001), required a longer admission (10.2 vs 6.6 days, P < 0.001), and had higher temperatures on admission (38.0 degrees C vs 37.3 degrees C, P = 0.03). CONCLUSION: The majority of small SPAs as diagnosed on CT scans in younger children can be successfully treated medically. Surgery, however, should be considered for a worsening clinical examination. Our findings confirm those of previous reports on this clinical entity.

Utility of bronchoscopy for recurrent croup.

OBJECTIVES: We performed a retrospective review to determine the utility of bronchoscopy in patients with recurrent croup (RC). METHODS: Bronchoscopy was performed on 30 patients with a diagnosis of RC (age, 14 months to 13.9 years) over a 2-year period. RESULTS: One third of the patients (33.3%) were found to have airway disorders, including subglottic stenosis (7), subglottic edema (2), and a subglottic cyst (1). Patients with RC who were less than 3 years of age were more likely to have an airway abnormality found on endoscopy (9 of 14 or 64.2%) than were those older than 3 years (1 of 16 or 6.2%; chi2 p < 0.001). There was no statistically significant difference in abnormal findings 1) in patients with RC who had a history of prematurity or prior intubations (chi2, p = 0.17 and p = 0.052, respectively); 2) between infectious and spasmodic croup (chi2, p = 0.794); or 3) by number of croup episodes (chi2, p = 0.300). Two patients required surgical intervention (laryngotracheal reconstruction and marsupialization of a subglottic cyst). CONCLUSIONS: Of 30 patients who underwent bronchoscopy for RC, 33% had airway disorders--mostly children less than 3 years old. We suggest a higher index of suspicion for finding airway disorders in children less than 3 years old with RC and having a lower threshold for performing diagnostic bronchoscopy in this population.

Special Populations in Implantable Auditory Devices: Pediatric.

"Hearing loss in the pediatric population can have significant social and developmental implications. Early auditory rehabilitation by at least 6 months of age is imperative. Although traditional hearing aids are often a first-line treatment option, there is a wide array of implantable auditory devices available. This article describes the indications for such devices as they pertain to the pediatric population, including osseointegrated bone-conduction devices, middle ear implants, cochlear implants, and auditory brainstem implants."