|Year : 2019 | Volume
| Issue : 4 | Page : 304-312
Neurocognitive and behavioral abnormalities in Indian children with sleep-disordered breathing before and after adenotonsillectomy
Elias Mir1, Rohit Kumar2, Tejas M Suri3, Jagdish Chandra Suri2, VP Venkatachalam4, Manas Kamal Sen2, Shibdas Chakrabarti2
1 Department of Chest Medicine, SKIMS Medical College, Srinagar, Jammu and Kashmir, India
2 Department of Pulmonary, Critical Care and Sleep Medicine, Vardhman Mahavir Medical College and Safdarjung Hospital, New Delhi, India
3 Department of Pulmonary, Critical Care and Sleep Medicine, AlIMS, New Delhi, India
4 Department of Otorhinolaryngology, Vardhman Mahavir Medical College and Safdarjung Hospital, New Delhi, India
|Date of Web Publication||28-Jun-2019|
Dr. Jagdish Chandra Suri
Department of Pulmonary, Critical Care and Sleep Medicine, Vardhman Mahavir Medical College and Safdarjung Hospital, Ansari Nagar, New Delhi
Source of Support: None, Conflict of Interest: None
| Abstract|| |
Objectives: Children with untreated sleep-disordered breathing (SDB) have impaired intellectual ability and behavioral effects. Timely treatment of SDB by adenotonsillectomy (AT) may prevent this morbidity. This study was designed to assess the prevalence of neurocognitive and behavioral dysfunction in Indian children with SDB and to evaluate the impact of AT. Methods: Children recruited underwent diagnostic polysomnography (PSG), a detailed neurocognitive and behavioral assessment using a battery of validated instruments – the Malin's Intelligence Scale (MIS) for Indian children, Modified Wisconsin's Card Sorting Test, Parent Conners' Scale, and the Childhood Behavior Checklist (6–18). These children then underwent AT and subsequent reassessment at 3 and 6 months. Results: Neurocognitive impairment was common among the 33 enrolled children (mean age 9 [±2.97] years; 78.8% males). There was a significant correlation between the lowest O2saturation and the “categories completed” (r = -0.379; P = 0.029); and the lowest O2saturation and the “failure to maintain sets” (r = 0.386; P = 0.026) of the Modified Wisconsin's Card Sorting Test. Postsurgery, although apnea–hypopnea index (AHI) significantly decreased after surgery, 15 children still had SDB. Mean scores of most of the tested neurocognitive and behavioral domains showed improvement, although residual deficits were prevalent even after 6 months. Patients with a baseline AHI >5/h and those who had complete resolution of SDB (postoperative AHI <1/h) showed improvement in more subscales than patients with baseline AHI < 5/h and patients with incomplete resolution of SDB. Conclusion: The decreased neurocognitive performance related to SDB may be a result of hypoxemia, rather than the frequency of SDB events. Despite AT, residual disease is common and such patients may require further treatment.
Keywords: Adenotonsillectomy, behavioral assessment, neurocognitive assessment, oxygen desaturation, pediatric sleep-disordered breathing, polysomnography
|How to cite this article:|
Mir E, Kumar R, Suri TM, Suri JC, Venkatachalam V P, Sen MK, Chakrabarti S. Neurocognitive and behavioral abnormalities in Indian children with sleep-disordered breathing before and after adenotonsillectomy. Lung India 2019;36:304-12
|How to cite this URL:|
Mir E, Kumar R, Suri TM, Suri JC, Venkatachalam V P, Sen MK, Chakrabarti S. Neurocognitive and behavioral abnormalities in Indian children with sleep-disordered breathing before and after adenotonsillectomy. Lung India [serial online] 2019 [cited 2020 May 28];36:304-12. Available from: http://www.lungindia.com/text.asp?2019/36/4/304/261708
| Introduction|| |
Literature on sleep-disordered breathing (SDB) in children, a hitherto neglected disorder, has proliferated substantially over the last few decades. SDB is now considered to be one of the most prevalent pediatric disorders.,,,, It is known to have an adverse effect on the cardiovascular system, on the growth of children, and on their quality of life.,, Studies have also revealed involvement of one or more neurocognitive parameters. Children with untreated SDB have been shown to have impairment of intellectual ability and significant neurocognitive effects such as deficits in attention and executive function.,,,, Assessments of behavioral functions have shown increased morbidity in these children., Some studies have also suggested a correlation between the severity of SDB and neurocognitive impairment,,,, although this has not been shown in all the studies.,,
Early diagnosis of SDB and its prompt treatment are thought to prevent this morbidity in otherwise healthy children. Adenotonsillectomy (AT) has been the treatment of choice in affected children. Studies assessing neurocognitive and behavioral morbidity in such children have shown improvement in the verbal and performance intelligence and reduction in hyperactivity (HA), aggression/oppositional behavior, and somatic complaints. While most of the studies have shown a favorable effect of AT on neurocognitive dysfunctions,,,,,, others have also shown significant residual impairments., The CHAT study, a randomized controlled trial, had shown that compared to a strategy of watchful waiting, surgical treatment for the SDB in school-age children did not significantly improve attention or executive function at 7 months but did reduce symptoms and improve secondary outcomes of behavior, quality of life, and polysomnographic (PSG) findings, thus providing evidence of beneficial effects of early AT.
Most studies, assessing neurocognitive and behavioral improvement following AT, are limited by methodological issues. Some early studies evaluated only limited domains of neurocognition and behavior and lacked objective assessment using validated instruments. Very few studies have used good-quality attended PSGs both before and after AT. Moreover, children in most of these studies have not been followed up for long periods after surgery. We also noticed a paucity of such studies from India. The present study was designed keeping in view the above lacunae and limitations in the available literature. We wanted to assess the prevalence of neurocognitive and behavioral dysfunction in Indian children with SDB and evaluate the impact of AT.
| Methods|| |
The present prospective observational study was conducted in the Department of Pulmonary, Critical Care, and Sleep Medicine in collaboration with the Department of Otorhinolaryngology, Vardhman Mahavir Medical College and Safdarjung Hospital (VMMC&SJH), New Delhi. We enrolled consecutive children from November 2013 to June 2015, referred to our sleep clinic for symptoms suggestive of SDB to using the following inclusion and exclusion criteria:
- Age <18 years
- Considered appropriate for AT by otorhinolaryngologists.
- Patient with a history of asthma or allergies
- Existing neurological disorders (epilepsy, cerebral palsy, etc.)
- Prior AT or other surgical procedure for SDB, e.g., mandibular advancement surgery
- Undergoing continuous positive airway pressure therapy for SDB
- Refusal for surgery
- Presence of bony deformities such as deviated nasal symptoms requiring specific therapy other than AT.
Approval of the Institutional Human Ethics Committee was obtained. Patients were enrolled only after taking informed, written consent from parents. All children and their caregivers underwent a detailed interview about their symptoms and socioeconomic and educational status, and this was recorded in a predesigned questionnaire. A detailed examination was done by a single otolaryngologist; the neck circumference, the tonsil size, the modified Mallampati grade, and the presence of retrognathia and high-arched palate were recorded.
As a baseline, all children underwent diagnostic PSG and detailed neurocognitive and behavioral assessment using a battery of validated instruments designed specifically for this age group. Children then underwent AT and were followed up 3 and 6 months after surgery in addition to regular checkups. The sleep assessment (which included the PSG) was repeated after 3–4 months of surgery. Neurocognitive and behavioral assessment was repeated using the same instruments 3 and 6 months after surgery. The sleep assessment and neurocognitive/behavioral assessment were done within a day or two of each other as per the convenience of the child and parents.
Pediatric Daytime Sleepiness Scale
The Pediatric Daytime Sleepiness Scale (PDSS) is an eight-item, self-reported Likert-type questionnaire that measures daytime sleepiness in school-age populations, with possible scores ranging from 0 to 32. Higher PDSS scores indicate greater daytime sleepiness.
Diagnostic PSG was done before AT and repeated 3–4 months after surgery using the Alice 6 Diagnostic Sleep System of the Philips Respironics at the Department of Pulmonary, Critical Care, and Sleep Medicine, VMMC&SJH. Each child underwent a fully attended in-laboratory whole-night level-I PSG performed for 7–8 h by a trained technologist. The time of sleep study and total recording time were guided by the previous week's sleep-wake diary. The following parameters were measured: three channels each for electroencephalography, electrooculography, electromyography with submental electrodes, and electrocardiography; airflow recording through nose and mouth using a thermistor and nasal pressure cannula; thoracic and abdominal efforts by piezoelectric bands; oxygen saturation using pulse oximetry; and snoring with neck microphone. There was continuous video monitoring during recording time.
The apnea-hypopnea index (AHI) and the oxygen desaturation index (ODI) were scored as per the Update of the 2007 AASM Manual for the Scoring of Sleep and Associated Events. Obstructive apnea was scored (using an oronasal thermal sensor) when there was a drop in the peak signal excursion by ≥90% of the pre-event baseline, lasting for at least two breaths during baseline breathing, and associated with respiratory effort throughout the entire period of absent airflow. A respiratory event was scored as a hypopnea if the peak signal excursions dropped by ≥30% of pre-event baseline using nasal pressure, lasting for at least two breaths, and associated with ≥3% desaturation from pre-event baseline, or the event was associated with an arousal.
Neurocognitive and behavioral assessment
Malin's Intelligence Scale for Indian children
It is an individual intelligence test scale for Indian children comprising 11 subtests divided into two groups; verbal (consisting of information, comprehension, arithmetic, similarities, vocabulary, and digit span) and performance (consisting of picture completion, block designing, object assembly, coding, and mazes). The points or raw scores for each test are totaled and converted into intelligence quotients (IQs). IQs of all subtests are averaged to generate a verbal IQ and a performance IQ. Total IQ is generated by averaging the verbal and performance IQs. Children were classified as normal (≥75) and abnormal (<75) in a subtest on the basis of a cutoff score.
Modified Wisconsin's Card Sorting Test
It is a test of executive function requiring use of working memory, planning, attention flexibility, and response inhibition to solve problems., Modified Wisconsin's Card Sorting Test (MWCST) consists of a total of 48 response cards and four key cards. Children are presented with response cards and told to match those with any of the key cards on the basis of color, form, or any other quality. The participant is told to match the cards but not how to match; however, he or she is told whether a particular match is right or wrong. Whatever method of matching the child chooses first becomes the first category. Subsequently, the child is told to change the rule of matching the cards after he/she correctly classifies six cards without telling the exact rule. If the child chooses a second and third rule correctly, these become the second and third category, respectively. The child then repeats matching cards as per the three categories again in the same order as earlier. The child is scored for categories completed, total errors, perseverative errors, nonperseverative errors, categorization efficiency, and failure to maintain sets. Children were classified as abnormal in parameters of categories completed and categorization efficiency on the basis of a cutoff score of 30 or less. A cutoff value of 65 (with values <65 classified as normal) was used to classify the parameters of total errors, perseverative errors, nonperseverative errors, and failure to maintain sets.
Parent Conners' Scale
We used “The Conners' 3–Parent” version – a validated instrument for assessing parent-reported behavioral dysfunction. It evaluates parent-reported inattention, HA, impulsivity, learning problems, executive functioning, aggression, and peer relations. It also evaluates for the presence and severity of symptoms of conduct disorder and oppositional defiance disorder according to the Diagnostic and Statistical Manual for the evaluation of Mental Disorders (DSM) IV. Parents respond to questions about their children which are scored on a Likert scale. The total score of a domain corresponds with a t-score provided. Children scoring 65 or greater in a particular domain were classified as abnormal and those scoring less classified as normal.
Childhood Behavior Checklist (6–18)
It is a component in the Achenbach System of Empirically Based Assessment. This questionnaire, containing 120 questions, measures emotional, behavioral, and social aspects of life. The total scores for each domain are calculated by adding the scores for all questions in that domain. These total scores are used to find t-scores for that individual domain. Children scoring 65 or greater in problem scores were classified as abnormal, and the rest were classified as normal. Children scoring less than 30 in any activity score were considered to be abnormal, except for total activity score where this cutoff was 37.
The data were analyzed as per appropriate statistical tools to compare variables we used the t-test for continuous variables with a normal distribution and Mann–Whitney U-test for continuous variables not normally distributed. Binomial data before and after surgery were compared using the McNemar test of equality of paired proportions. The correlation coefficient between the neurocognitive and behavior scores and the sleep parameters was calculated. All P values are two-tailed, with statistical significance determined at α = 0.05.
| Results|| |
Thirty-three children were enrolled (mean age 9 ± 2.97 years, 78.8% males, mean body mass index of 17.24 [±2.83] kg/m2). One child (3.0%) had retrognathia and 4 (12.1%) had a high-arched palate (12.12%) [Table 1]. Baseline PSG, neurocognitive, and behavioral assessment was done. Fifteen children (45.5%) had an AHI of <5/h while 18 (54.5%) had an AHI of ≥5/h. All patients underwent AT within a week of the baseline assessment. One child did not come for follow-up after AT, and his postoperative assessment was not available. After surgery, 17 patients had complete resolution of SDB while 15 patients still had an AHI of >1/h. Another patient dropped out after the postoperative PSG; postoperative neurocognitive assessment was available for only 31 patients [Figure 1].
Snoring, reported in 84.8% of the children, was the most common symptom seen at baseline. Witnessed choking at night (57.6%), difficulty in morning awakening (48.5%), nocturnal drooling of saliva (33.3%), and nocturnal enuresis (33.3%) were also common. Most symptoms were ameliorated within 3 months of surgery. Difficulty in morning awakening and nocturnal drooling of saliva persisted in at least half of the subjects even after 6 months of treatment [Table 2].
Sleep parameters: Before and after surgery
All PSG parameters (AHI and ODI) showed significant decrease after surgery. However, significant residual abnormalities remained in most children. The success of AT was 53.1%; out of 32 children, 15 still had SDB (defined as AHI ≥1/h) while two patients (6.3%) had a postoperative AHI of >5/h [Supplementary Table S1 [Additional file 1]].
Baseline neurocognitive assessment and its correlation with sleep parameters
In the Malin's Intelligence Scale (MIS), 48.5% of children scored less than normal in object assembly, a measure of performance intelligence. Information (33.3%) and vocabulary (27.3%), which are domains of verbal IQ, were also common areas of impairment. In the MWCST, 36.4% of children failed to maintain sets and 21.2% made perseverative errors [Table 3].
|Table 3: Correlation of the baseline neurocognitive assessment with the sleep parameters|
Click here to view
In the Parent Conners' scale, almost half of the children were in clinical range for inattention (45.5%), HA (45.5%), aggression (45.5%), and learning problems (42.4%). About one-third had problems related to conduct (33.33%) and oppositional defiance (24.2%) when scored on the basis of DSM IV criteria. In the Childhood Behavior Checklist (CBCL/6–18), almost half (51.60%) of the subjects showed abnormal activity score. High frequencies of attention-deficit/hyperactivity (AD/HA) problems (39.4%), affective problems (18.2%), conduct problems (12.1%), and oppositional defiance disorder (9.1%) were also seen in many children [Table 3].
The children with a higher PDSS (excessive daytime sleepiness) made more perseverative errors during assessment using the MWCST (r = 0.459; P = 0.007). Furthermore, with increasing frequency of oxygen desaturation (increase in ODI), decrement was observed in comprehension scores of MIS (r = −0.409; P = 0.018). The lowest O2 saturation during sleep showed negative correlation with categories completed (r = −0.379; P = 0.029) and positive correlation with failure to maintain sets (r = 0.386; P = 0.026) [Table 3].
Neurocognitive assessment: Before and after surgery
In the MIS, statistically significant improvement was seen in all scores at 3 months and further improvement at the 6 month assessment [Figure 2]. In the MWCST, statistically significant drop in mean values of almost all MWCST parameters was seen; improvement was evident at 6 months [Figure 3]. In the Parent Conners' Scale, decrease in mean scores of inattention, HA, and learning problems was seen [Figure 4]. The mean scores of conduct disorder and oppositional defiance disorder when assessed using DSM IV criteria also decreased after surgery. Attention-deficit hyperactivity disorder (ADHD) index, a combined score of problems related to inattention and HA, decreased substantially with significant improvement within 3 months of surgery. In the CBCL, significant improvement occurred in mean scores of affective problems, AD/HA problems, and conduct problems after 6 months of surgery [Figure 5]. Although improvements in these domains are statistically significant, the clinical relevance may be questionable. In spite of improvement in scores, children who were impaired initially continued to remain in abnormal range even after 6 months of treatment.
|Figure 2: Mean scores of Malin's intelligence scale in children before and after surgery|
Click here to view
|Figure 3: Modified Wisconsin Card Sorting Test scores, before and after surgery|
Click here to view
|Figure 5: Mean scores of Childhood Behavior Checklist in children before and after surgery|
Click here to view
The study population was categorized based on severity of pre-operative AHI (AHI <5/h and AHI ≥5/h). The improvement over 6 months in various scales in each group was compared [Supplementary Table S2 [Additional file 2]]. Most domains of various scales improved in both groups. Statistically significant improvement was seen amongst those with a higher AHI, in the perseverative errors and failure to maintain sets (in the MWSCT); inattention and HA domains (in the Parent Conners' scale); and in school score and AD/HA problems (in the CBCL/6–18 scores), while there was no significant improvement in these domains in the group with AHI <5/h. Statistically significant improvement was also seen in mild SDB group in oppositional defiance disorder scale (in the Parent Conners' scale) and activity score (in the CBCL/6–18 scores); however, such an improvement was lacking in the group with severe SDB. However, when we compared the improvement in various subscales in the two groups, the difference was not statistically significant.
The improvement after 6 months was compared between patients in whom SDB was completely cured and those with residual SDB [Supplementary Table S3 [Additional file 3]]. Here also, most domains of various scales improved in both groups. Statistically significant improvement was seen in whom SDB was cured in the similarities, coding, and mazes subscales (in the MIS); categories completed and total errors (in the MWSCT); inattention and HA domains and the oppositional defiance disorder scale and ADHD index (in the Parent Conners' scale); and in the activity and total score (in the CBCL/6–18 scores); however, there was no significant improvement in these domains in those with persisting SDB. When improvement between groups was compared, the mazes subscale in the MIS showed significant improvement in patients in whom SDB was completely cured (P = 0.028).
| Discussion|| |
This is one of the few prospective studies to have used attended PSG, both for diagnosing SDB before AT and for evaluating residual disease after surgery, along with extensive and objective assessment of neurocognitive and behavioral functions in affected children using validated instruments. We observed that neurocognitive impairment was common in these children, and though there was significant improvement after AT, residual abnormalities persisted in patients.
Most studies in children with SDB have reported lower intelligence scores than normal controls. Although we did not have a control group, a significant proportion of children showed a clinically abnormal score. Studies conducted so far have not found a strong association between severity of SDB (assessed using AHI) and baseline neurocognitive impairment in children with SDB.,,, We observed that children with excessive daytime sleepiness made more perseverative errors. The present study also found a negative correlation between comprehension scores (a domain of verbal intelligence) and ODI and between the lowest oxygen saturation and the categories completed in the MWCST – these correlations are scientifically plausible given the expected effect of sleep disruption due to oxygen desaturation on the neurocognitive development in these children. This could reflect that probably oxygen desaturation rather than apneas may be the important mediators of neurocognitive deficits in these patients; similar results have been reported in adult SDB patients. In studies done in chronic obstructive pulmonary disease, patient's oxygen saturation has been found to be related to increased risk of cognitive impairment and the regular use of supplemental oxygen therapy decreased the risk for cognitive impairment in them. It is possible that in children with SDB also, the goal of therapy should be to abolish oxygen desaturation.
AT in our study group led to a sharp decrease in almost all PSG abnormalities. This is similar to the earlier studies., However, complete cure of SDB defined as AHI ≤1 h was seen in 53.1% of the subjects. This is also commensurate with previous studies.,, A multicenter retrospective study has reported complete resolution of the SDB in about a quarter of the children undergoing AT. This suggests that though AT improves SDB, it completely resolve SDB only in a minority of children.
Significant improvement in mean scores was seen in most of the tested neurocognitive and behavioral domains. The first postoperative assessment at 3 months showed gradual improvement. Further improvement was seen at the 6 months assessment. The change in mean scores of MWCST was significant only at 6 months and not 3 months after surgery in most parameters. This indicates that improvement after surgery in these domains is gradual and may take some time before becoming evident clinically.
Despite improvement, residual neurocognitive deficits persisted in children even 6 months after surgery. This is in agreement with previous studies which have shown improvement in some aspects as well as residual disabilities.,,, We observed that aggression (assessed using the Parent Conners' scale) and oppositional defiance (assessed using the CBCL/6–18) persisted after the surgery. The persistence of neurocognitive problems in these children could be due to the incomplete resolution of SDB or to other nonsleep-related factors. It is also conceivable that 6 months duration may not be enough for resolution of neurocognitive problems even in children in whom SDB is cured by AT. Another possible reason could be that the cognitive and behavioral impairment may be irreversible.
Previous studies have reported that baseline PSG assessment and its subsequent amelioration did not predict the improvement in neurocognitive and behavioral morbidity., However, we saw that patients with a baseline AHI >5/h and those who have complete resolution of the SDB (postoperative AHI <1/h) had shown improvement in more subscales than patients with baseline AHI <5/h and patients who had incomplete resolution of the SDB. However, when we compared the degree of improvement, only the maze subscale (a measure of performance IQ in the MIS) showed significant improvement in the patients in whom the SDB was completely cured. The lack of significant difference in the improvement in the various subscales of neurobehavioral morbidity could be attributed to the small sample size.
As AT may not lead to complete cure of PSG abnormalities and neurocognitive impairment, the use of repeat PSG after surgery may be warranted to evaluate for residual disease and plan further treatment in these patients.,
The strength of this study is the use of high-quality attended diagnostic overnight PSGs both before and after surgery and application of objective, well-validated instruments for neurocognitive and behavioral assessment in these children. Furthermore, after surgery, reassessment was done at 3 and 6 months interval to look for short- and intermediate-term improvement. The shortcomings in this study are a fairly small number of patients. It can be argued that the improvement in the score could be due to a learning effect; by the inclusion of a control group in further studies, this can be negated. A longer follow-up period may be required to assess the long-term impact of residual SDB. In addition, the use of other adjunctive techniques in addition to AT (e.g., lingual tonsillectomy), with the aim of completely ameliorating sleep fragmentation and nocturnal hypoxia, needs to be assessed.
| Conclusion|| |
We conclude that children suffering from SDB have impaired neurocognitive and behavioral functions. The decrements in neurocognitive performance related to SDB appear to be predominantly a result of hypoxemia, rather than the frequency of SDB events. AT significantly reduced the apneas, and there was substantial improvement in neurocognitive and behavioral parameters; a greater resolution being observed patients with AHI >5/h and in those with complete resolution of the SDB. However, despite treatment, residual disease is common and such patients may require further treatment.
Financial support and sponsorship
Conflicts of interest
There are no conflicts of interest.
| References|| |
Suri JC, Sen M, Adhikari T. Epidemiology of sleep disorders in school children of Delhi: A questionnaire based study. Indian J Sleep Med 2008;3:42-50.
Lumeng JC, Chervin RD. Epidemiology of pediatric obstructive sleep apnea. Proc Am Thorac Soc 2008;5:242-52.
Nixon GM, Brouillette RT. Sleep 8: Paediatric obstructive sleep apnoea. Thorax 2005;60:511-6.
Sinha D, Guilleminault C. Sleep disordered breathing in children. Indian J Med Res 2010;131:311-20.
] [Full text]
Suri JC, Sen MK, Venkatachalam VP, Bhool S, Sharma R, Elias M, et al.
Outcome of adenotonsillectomy for children with sleep apnea. Sleep Med 2015;16:1181-6.
Rosen CL, Palermo TM, Larkin EK, Redline S. Health-related quality of life and sleep-disordered breathing in children. Sleep 2002;25:657-66.
Amin RS, Carroll JL, Jeffries JL, Grone C, Bean JA, Chini B, et al.
Twenty-four-hour ambulatory blood pressure in children with sleep-disordered breathing. Am J Respir Crit Care Med 2004;169:950-6.
Nieminen P, Löppönen T, Tolonen U, Lanning P, Knip M, Löppönen H, et al.
Growth and biochemical markers of growth in children with snoring and obstructive sleep apnea. Pediatrics 2002;109:e55.
Rosen CL, Storfer-Isser A, Taylor HG, Kirchner HL, Emancipator JL, Redline S, et al.
Increased behavioral morbidity in school-aged children with sleep-disordered breathing. Pediatrics 2004;114:1640-8.
Kohler MJ, Lushington K, Kennedy JD. Neurocognitive performance and behavior before and after treatment for sleep-disordered breathing in children. Nat Sci Sleep 2010;2:159-85.
Kohler MJ, Lushington K, van den Heuvel CJ, Martin J, Pamula Y, Kennedy D, et al.
Adenotonsillectomy and neurocognitive deficits in children with sleep disordered breathing. PLoS One 2009;4:e7343.
Giordani B, Hodges EK, Guire KE, Ruzicka DL, Dillon JE, Weatherly RA, et al.
Neuropsychological and behavioral functioning in children with and without obstructive sleep apnea referred for tonsillectomy. J Int Neuropsychol Soc 2008;14:571-81.
Gottlieb DJ, Chase C, Vezina RM, Heeren TC, Corwin MJ, Auerbach SH, et al.
Sleep-disordered breathing symptoms are associated with poorer cognitive function in 5-year-old children. J Pediatr 2004;145:458-64.
O'Brien LM, Mervis CB, Holbrook CR, Bruner JL, Smith NH, McNally N, et al.
Neurobehavioral correlates of sleep-disordered breathing in children. J Sleep Res 2004;13:165-72.
Chervin RD, Ruzicka DL, Giordani BJ, Weatherly RA, Dillon JE, Hodges EK, et al.
Sleep-disordered breathing, behavior, and cognition in children before and after adenotonsillectomy. Pediatrics 2006;117:e769-78.
Goldstein NA, Fatima M, Campbell TF, Rosenfeld RM. Child behavior and quality of life before and after tonsillectomy and adenoidectomy. Arch Otolaryngol Head Neck Surg 2002;128:770-5.
Wei JL, Mayo MS, Smith HJ, Reese M, Weatherly RA. Improved behavior and sleep after adenotonsillectomy in children with sleep-disordered breathing. Arch Otolaryngol Head Neck Surg 2007;133:974-9.
Hunter SJ, Gozal D, Smith DL, Philby MF, Kaylegian J, Kheirandish-Gozal L, et al.
Effect of sleep-disordered breathing severity on cognitive performance measures in a large community cohort of young school-aged children. Am J Respir Crit Care Med 2016;194:739-47.
Zhao Q, Sherrill DL, Goodwin JL, Quan SF. Association between sleep disordered breathing and behavior in school-aged children: The tucson children's assessment of sleep apnea study. Open Epidemiol J 2008;1:1-9.
Esposito M, Antinolfi L, Gallai B, Parisi L, Roccella M, Marotta R, et al.
Executive dysfunction in children affected by obstructive sleep apnea syndrome: An observational study. Neuropsychiatr Dis Treat 2013;9:1087-94.
Friedman BC, Hendeles-Amitai A, Kozminsky E, Leiberman A, Friger M, Tarasiuk A, et al.
Adenotonsillectomy improves neurocognitive function in children with obstructive sleep apnea syndrome. Sleep 2003;26:999-1005.
Calhoun SL, Mayes SD, Vgontzas AN, Tsaoussoglou M, Shifflett LJ, Bixler EO, et al.
No relationship between neurocognitive functioning and mild sleep disordered breathing in a community sample of children. J Clin Sleep Med 2009;5:228-34.
Marcus CL, Brooks LJ, Draper KA, Gozal D, Halbower AC, Jones J, et al.
Diagnosis and management of childhood obstructive sleep apnea syndrome. Pediatrics 2012;130:e714-55.
Gozal D. Sleep-disordered breathing and school performance in children. Pediatrics 1998;102:616-20.
Harvey JM, O'Callaghan MJ, Wales PD, Harris MA, Masters IB. Six-month follow-up of children with obstructive sleep apnoea. J Paediatr Child Health 1999;35:136-9.
Stradling JR, Thomas G, Warley AR, Williams P, Freeland A. Effect of adenotonsillectomy on nocturnal hypoxaemia, sleep disturbance, and symptoms in snoring children. Lancet 1990;335:249-53.
Guilleminault C, Winkle R, Korobkin R, Simmons B. Children and nocturnal snoring: Evaluation of the effects of sleep related respiratory resistive load and daytime functioning. Eur J Pediatr 1982;139:165-71.
Constantin E, Kermack A, Nixon GM, Tidmarsh L, Ducharme FM, Brouillette RT, et al.
Adenotonsillectomy improves sleep, breathing, and quality of life but not behavior. J Pediatr 2007;150:540-6, 546.e1.
Biggs SN, Walter LM, Jackman AR, Nisbet LC, Weichard AJ, Hollis SL, et al.
Long-term cognitive and behavioral outcomes following resolution of sleep disordered breathing in preschool children. PLoS One 2015;10:e0139142.
Marcus CL, Moore RH, Rosen CL, Giordani B, Garetz SL, Taylor HG, et al.
Arandomized trial of adenotonsillectomy for childhood sleep apnea. N
Engl J Med 2013;368:2366-76.
Drake C, Nickel C, Burduvali E, Roth T, Jefferson C, Pietro B, et al.
The pediatric daytime sleepiness scale (PDSS): Sleep habits and school outcomes in middle-school children. Sleep 2003;26:455-8.
Berry RB, Budhiraja R, Gottlieb DJ, Gozal D, Iber C, Kapur VK, et al.
Rules for scoring respiratory events in sleep: Update of the 2007 AASM manual for the scoring of sleep and associated events. Deliberations of the sleep apnea definitions task force of the American Academy of Sleep Medicine. J Clin Sleep Med 2012;8:597-619.
Malin AJ. Malin's intelligence scale for children. Indian J Ment Retard 1971;4:15-25.
Nelson HE. A modified card sorting test sensitive to frontal lobe defects. Cortex 1976;12:313-24.
Cianchetti C, Corona S, Foscoliano M, Contu D, Sannio-Fancello G. Modified wisconsin card sorting test (MCST, MWCST): Normative data in children 4-13 years old, according to classical and new types of scoring. Clin Neuropsychol 2007;21:456-78.
Quan SF, Chan CS, Dement WC, Gevins A, Goodwin JL, Gottlieb DJ, et al.
The association between obstructive sleep apnea and neurocognitive performance – The apnea positive pressure long-term efficacy study (APPLES). Sleep 2011;34:303-314B.
Thakur N, Blanc PD, Julian LJ, Yelin EH, Katz PP, Sidney S, et al.
COPD and cognitive impairment: The role of hypoxemia and oxygen therapy. Int J Chron Obstruct Pulmon Dis 2010;5:263-9.
Friedman M, Wilson M, Lin HC, Chang HW. Updated systematic review of tonsillectomy and adenoidectomy for treatment of pediatric obstructive sleep apnea/hypopnea syndrome. Otolaryngol Head Neck Surg 2009;140:800-8.
Brietzke SE, Gallagher D. The effectiveness of tonsillectomy and adenoidectomy in the treatment of pediatric obstructive sleep apnea/hypopnea syndrome: A meta-analysis. Otolaryngol Head Neck Surg 2006;134:979-84.
Bhattacharjee R, Kheirandish-Gozal L, Spruyt K, Mitchell RB, Promchiarak J, Simakajornboon N, et al.
Adenotonsillectomy outcomes in treatment of obstructive sleep apnea in children: A multicenter retrospective study. Am J Respir Crit Care Med 2010;182:676-83.
Dillon JE, Blunden S, Ruzicka DL, Guire KE, Champine D, Weatherly RA, et al.
DSM-IV diagnoses and obstructive sleep apnea in children before and 1 year after adenotonsillectomy. J Am Acad Child Adolesc Psychiatry 2007;46:1425-36.
Pomerantz J. Management of persistent obstructive sleep apnea after adenotonsillectomy. Pediatr Ann 2016;45:e180-3.
[Figure 1], [Figure 2], [Figure 3], [Figure 4], [Figure 5]
[Table 1], [Table 2], [Table 3]