Original articleMorphologic response to changes in neuromuscular patterns experimentally induced by altered modes of respiration☆
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2023, Snoring and Obstructive Sleep Apnea in ChildrenBilateral intermittent nasal obstruction in adolescent rats leads to the growth defects of mandibular condyle
2019, Archives of Oral BiologyCitation Excerpt :MB was developed in monkeys by obstruction of the nasal passages with silicon nose plugs. All experimental animals gradually acquired a facial appearance and dental occlusion different from those of the control animals (Harvold, Vargervik, & Chierici, 1973; Harvold, Tomer, Vargervik, & Chierici, 1981; Vargervik, Miller, Chierici, Harvold, & Tomer, 1984). Yamada also reported a similar result on nasal obstruction in young Macaca fuscata monkeys before and during pubertal growth.
From oral facial dysfunction to dysmorphism and the onset of pediatric OSA
2018, Sleep Medicine ReviewsLong-Face Dentofacial Deformities: Occlusion and Facial Esthetic Surgical Outcomes
2018, Journal of Oral and Maxillofacial SurgeryHistorical review on obstructive sleep apnea in children
2017, Medecine du SommeilBimaxillary expansion therapy for pediatric sleep-disordered breathing
2017, Sleep MedicineCitation Excerpt :The three external factors that are firmly established to affect the upper airway space are the nasal cavity, and the retropalatal and the retroglossal upper airway space. Obstructions that affect the mode of breathing can affect the width, length, and height of the maxillomandibular complex with a subsequent impact on the nasal cavity, and retropalatal and retroglossal upper airway space, as shown in both children and experimental animals [4–8]. Craniofacial alterations of a narrowed maxilla, altered tongue position, and narrowed dentition have been described in numerous studies [9–13].
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This study was supported by grant DE 05558 from the National Institute of Dental Research.