1.Diagnosis and treatment of sleep disordered breathing: an update.
Journal of Clinical Otorhinolaryngology Head and Neck Surgery 2015;29(6):483-485
The sleep breathing disorders (SDB) include obstructive sleep apnea (OSA), central sleep apnea disorders, sleep related hypoventilation disorders, and sleep related hypoxemia disorder in international classification of sleep diseases 3rd edition (ICSD-3). Latest diagnosis criteria are introduced. Treatments, which target to Individual contributors, should be applied. Thus identification of the phenotype in patients with OSA is important. The methods of evaluation patients' arousal thresholds, loop gain as well as neuromyopathy in clinical setting are reported. Several new treatment strategies are developed and applied for OSA. Long term follow up and more data are needed for evaluation the outcomes of hypoglossal nerve stimulation, bariatric surgery as well as medicine as treatments for OSA.
Humans
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Sleep Apnea Syndromes
;
diagnosis
;
therapy
;
Sleep Apnea, Central
;
Sleep Apnea, Obstructive
2.Skeletal Surgery in Obstructive Sleep Apnea.
Hanyang Medical Reviews 2013;33(4):233-238
Skeletal surgery for obstructive sleep apnea (OSA) aims to provide more space for the soft tissue in the oropharynx to prevent airway collapse during sleep. Conventional surgical techniques include genioglossus advancement (GA), hyoid myotomy/suspension (HMS), and maxillomandibular advancement (MMA). GA and HMS are usually performed with soft tissue surgery and/or other skeletal surgery in a combined manner. These combined procedures seem to have a higher success rate. MMA employs a different conceptual approach, so called whole upper airway reconstruction, because MMA can widen the entire upper airway with one procedure. Various modifications of skeletal surgery have been reported. Surgical techniques, efficacy and complications of skeletal surgery with my opinions and comments are introduced in this review. Furthermore, limitations and considerations in skeletal surgery that sleep surgeons have to realize and overcome will be discussed in this review.
Mandibular Advancement
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Oropharynx
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Sleep Apnea Syndromes
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Sleep Apnea, Obstructive*
3.Surgical Treatment of Adult Obstructive Sleep Apnea.
Journal of Rhinology 2009;16(1):12-19
Obstructive sleep apnea (OSA) is well known disease which induces cardiovascular, cerebrovascular, and metabolic sequelae. Positive airway pressure (PAP) is considered as standard and primary therapy of choice in OSA. However, compliance continues to be a problem for many patients despite advances in PAP for obstructive sleep apnea. Sleep apnea surgery is a viable option for patients who are intolerant of positive pressure therapy and should be one column in treatment of this disease. This review will present the current state in sleep apnea surgery, including concept of surgery, formulation of surgical planning through a lot of factors which should be considered, as well as introduction of various surgical techniques which have been used world widely, and perioperative cares.
Adult
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Compliance
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Humans
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Sleep Apnea Syndromes
;
Sleep Apnea, Obstructive
4.Comparison between Group I in Which Non-Supine Apnea-Hypopnea Index> or =5 and Group II in Which Non-Supine Apnea-Hypopnea Index<5 in Patients with Positional Sleep Apnea.
Won Il PARK ; Hye Won JUNG ; Joon Bum JOO ; Ju Eun CHO ; Jong Yang KIM
Sleep Medicine and Psychophysiology 2013;20(1):31-34
OBJECTIVES: The aim of this study was to evaluate the differences in patients with positional dependent sleep apnea according to their non-supine apnea-hypopnea index (AHI, > or =5 vs. <5). METHODS: 92 patients with positional sleep apnea were evaluated. The patients were divided into two groups : group I was non-supine AHI having > or =5 ; group II was non-supine AHI having less than 5. Statistical analysis was performed to find the difference between two groups. RESULTS: In 92 patients, the number of group I patients was 11 (12%) and the number of group II patients was 81 (88%). In the severe AHI group, percentage of group I was dominated (70%) and showing a significant difference compared with the mild and moderate AHI groups (p<.05). In the severe body mass index (BMI) group, percentage of group I was dominated (54.5%) and showing a significant difference compared with of the mild and moderate BMI groups (p<.05). The percentage of group I was significantly higher than group II (p<.05) in the AHI, supine AHI, non-supine AHI and snore time. CONCLUSIONS: In patients with positional sleep apnea, severe OSA and high BMI are more common in patients with non-supine AHI> or =5 than non-supine AHI<5.
Body Mass Index
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Humans
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Sleep Apnea Syndromes
;
Sleep Apnea, Obstructive
6.Reversed Hand Movement during Sleep in Patients with Obstructive Sleep Apnea.
Hong Jun JEON ; Jee Hyun HA ; Seung Ho RYU ; Jaehak YU ; Doo Heum PARK
Psychiatry Investigation 2018;15(9):884-890
OBJECTIVE: Previous findings suggest that hand movement laterality is reversed during sleep. The present study aimed to verify this phenomenon and evaluate whether the extent of reversal is correlated with the severity of sleep apnea. METHODS: A total of 184 participants (mean age: 44.5±13.0 years; 81.5% males) wore actigraphs on both hands during sleep, and nocturnal polysomnography was simultaneously performed. RESULTS: Actigraphic indices of hand movement were significantly higher for the left hand than those for the right hand (p < 0.001), including total activity score, mean activity score, mean score in active periods and fragmentation index. Additionally, calculated differences between the fragmentation index for the left versus right hands were significantly correlated with the apnea-hypopnea index (AHI, r=0.149, p=0.032). The AHI was not significantly correlated with differences in hand movement between both hands movement assessed by total activity score (r=0.004, p=0.957), mean activity score (r=0.011, p=0.876), mean score in active periods (r=-0.080, p=0.255). CONCLUSION: More severe symptoms of obstructive sleep apnea was associated with larger degree of hand movement reversal at night. This result support the theory that homeostatic deactivation occurs in the dominant hemisphere during sleep.
Hand*
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Humans
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Polysomnography
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Sleep Apnea Syndromes
;
Sleep Apnea, Obstructive*
7.The Differences of anthropometric and polysomnographic characteristics between the positional and non-positional obstructive sleep apnea syndrome.
Hye Jung PARK ; Kyeong Cheol SHIN ; Choong Kee LEE ; Jin Hong CHUNG ; Kwan Ho LEE
Tuberculosis and Respiratory Diseases 2000;48(6):956-963
BACKGROUNDS: Obstructive sleep apnea syndrome(OSA) can divided into two groups, positional (PP) and non-positional(NPP) obstructive sleep apnea syndrome, according to the body position while sleeping. In this study, we evaluated the differences of anthropometirc data and polysomnographic recordings between the two types of sleep apnea syndrome. MATERIALS: Fifty patients with OSA were divided two groups by Cartwright's criteria. The supine respiratory disturbance index (RDI) was at least two times higher than the lateral RDI in the PP group, and the supine RDI was less than twice the lateral RDI in the NPP group. This patients underwent standardized polysomnographic recordings. The anthropometirc data and polysomnographic data were analyzed, statistically. RESULTS: Of all 50 patients, 30% were found to be positional OSA. BMI was significantly higher in the PP group(p<0.05). Total sleep time was significantly longer in the PP group (350.6±46.0min, p<0.05). Sleep efficiency was high in the PP group(89.6± 6.4%, 85.6±9.9%, p<0.05). Deep sleep was significantly higher and light sleep was lower in the PP group than in the NPP group but no difference was observed in REM sleep between the two groups. Apnea index(AI) and RDI were significantly lower(17.0±10.6, 28.5±13.3, p<0.05) and mean arterial oxygen saturation was higher in the PP group(92.7 ±1.8%, p<0.05) than in the NPP group. CONCLUSION: Body position during sleep has a profound effect on the frequency and severity of breathing abnormalities in OSA patients. A polysomnographic evaluation for suspected OSA patients must include monitoring of the body position. Breathing function in OSA patients can be improved by controlling their obesity and through postural therapy.
Apnea
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Humans
;
Obesity
;
Oxygen
;
Polysomnography
;
Respiration
;
Sleep Apnea Syndromes
;
Sleep Apnea, Obstructive*
;
Sleep, REM
8.Influences of nonobstructive apneas on hemodynamic changes in anesthetized dogs.
Jin Woo KIM ; Sang Haak LEE ; Young Mee CHOI ; Soon Seog KWON ; Young Kyoon KIM ; Kwan Hyoung KIM ; Jeong Sup SONG ; Sung Hak PARK ; Hwa Sik MOON
Korean Journal of Medicine 2001;60(1):61-69
BACKGROUND: The cardiovascular dysfunction frequently accompanies sleep apnea syndrome, but the exact pathophysiology of cardiovascular dysfunction still remains uncertain. Moreover, most studies are concerned with obstructive sleep apnea syndrome and the studies of central sleep apnea syndrome are rare. METHODS: We studied with sixteen dogs which were anesthetized with intravenous pancuronium bromide. We created nonobstructive breath hold (apnea) in anesthetized dogs by means of alternating fixed duration (30s) of apnea and mechanical ventilation (breathing). After five or seven repetitions of this apnea-breathing cycle, we measured arterial oxygen pressure, arterial carbon dioxide pressure, heart rate, cardiac output, mean femoral artery pressure and mean pulmonary artery pressure separately before apnea (baseline), 25s after apnea (apneic period), 10s (early phase of postapneic period) and 25s (late phase of postapneic period) after resumption of breathing. We analysed the impact of oxygen trial on the hemodynamic changes by comparing measures of the eight 30% oxygen breathing dogs with the other eight room air breathing dogs. RESULTS: Heart rate decreased significantly at apneic period compared to baseline (p<0.05), and increased significantly at early and late phase of postapneic period compared to apneic period (p<0.05). After oxygen trial, this change of heart rate showed significant difference (p<0.05). Cardiac output only tended to decrease during late phase of postapneic period by comparison with baseline and apneic period. Mean femoral artery pressure of apneic period increased more than that of baseline (p<0.05), and persisted until late phase of postapneic period (p<0.05). When oxygen was supplied, this change of increase disappeared, but did not show statistical significance. Mean pulmonary artery pressure did not change according to apnea-breathing cycle and oxygen trial. CONCLUSION: In anesthetized dogs with periodic nonobstructive apnea, the changes of heart rate, cardiac output, mean femoral artery pressure were noted and the change of heart rate was closely related with hypoxia. Through this study, indirectly, we were able to understand partially the changes of cardiovascular function in patients with central sleep apnea syndrome.
Animals
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Anoxia
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Apnea*
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Arterial Pressure
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Carbon Dioxide
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Cardiac Output
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Dogs*
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Femoral Artery
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Heart Rate
;
Hemodynamics*
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Humans
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Oxygen
;
Pancuronium
;
Pulmonary Artery
;
Respiration
;
Respiration, Artificial
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Sleep Apnea Syndromes
;
Sleep Apnea, Central
;
Sleep Apnea, Obstructive
9.The Nasal Airflow Pressure Monitoring and the Measurement of Airway Pressure Changes in Obstructive Sleep Apnea Syndrome and Upper Airway Resistance Syndrome.
Sleep Medicine and Psychophysiology 2000;7(1):27-33
OBJECTIVES: The sensitivity and accuracy of thermistor airflow signal has been debated. The purposes of this study were to compare apnea-hypopnea index(AHI) detected from a conventional thermistor signal and a nasal pressure transducer of airflow(NPT), to evaluate the value of NPT for the diagnosis of upper airway resistance syndrome (UARS), and to measure airway pressure fluctuations which produced respiratory arousals in UARS by naso-oro-esophageal manometer catheter. The subjects were 30 patients with obstructive sleep apnea syndrome [mild(5
Airway Resistance*
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Apnea
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Arousal
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Catheters
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Diagnosis
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Humans
;
Sleep Apnea Syndromes
;
Sleep Apnea, Obstructive*
;
Transducers, Pressure
10.Relationship Between Snoring Intensity and Severity of Obstructive Sleep Apnea.
Jeong Whun KIM ; Chul Hee LEE ; Chae Seo RHEE ; Ji Hun MO
Clinical and Experimental Otorhinolaryngology 2015;8(4):376-380
OBJECTIVES: The aim of this study was to determine the relationship between the intensity of snoring and severity of sleep apnea using Watch-PAT (peripheral arterial tone) 100. METHODS: A total of 404 patients (338 males and 66 females) who underwent home-based portable sleep study using Watch-PAT 100 for obstructive sleep apnea (OSA) from January 2009 through December 2011 were included in this study. Subjects were divided into 4 groups; no OSA (PAT apnea hypopnea index [pAHI]<5/hour), mild OSA (5< or =pAHI<15/hour), moderate OSA (15< or =pAHI<30/hour), or severe OSA groups (pAHI> or =30/hour). Mean snoring intensity and percent sleep time with snoring intensity greater than 40, 50, and 60 dB were measured by Watch-PAT 100. Correlations of these parameters with apnea hypopnea index (AHI), respiratory disturbance index (RDI), and oxygen desaturation index were assessed. RESULTS: The mean age and body mass index were 46.5+/-14.8 years and 24.7+/-3.4 kg/m2, respectively. Mean AHI and RDI were 16.5+/-15.3/hour and 20.8+/-14.3/hour, respectively. The mean snoring intensity in the no, mild, moderate, and severe OSA groups was 44.0+/-2.7, 45.4+/-6.0, 47.7+/-5.0, and 50.5+/-5.6 dB, respectively (P<0.001). There was a positive correlation between snoring intensity and pAHI or PAT RDI (pRDI) (r=0.391 and r=0.385, respectively, both P<0.001). There was also a positive correlation between percent sleep time with the snoring intensity greater than 50 dB and pAHI or pRDI (r=0.423 and r=0.411, respectively, both P<0.001). CONCLUSION: This study revealed that the intensity of snoring increased with the severity of sleep apnea, which suggests that the loudness of snoring might be an indicator of the severity of OSA.
Apnea
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Body Mass Index
;
Humans
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Male
;
Oxygen
;
Sleep Apnea Syndromes
;
Sleep Apnea, Obstructive*
;
Snoring*