OBJECTIVE: The purpose of this study was to evaluate the feasibility of sonography in identifying the anatomic structures of the upper airway and to describe their appearance on sonography. METHODS: We enrolled 24 healthy volunteers, placed them supine with their head extended and neck flexed (the "sniffing" position), and performed a systematic sonographic examination of their upper airway from the floor of the mouth to the suprasternal notch. RESULTS: We were able to visualize all relevant anatomic structures in all of the participants using either a linear or curved transducer oriented in 1 of 3 planes: sagittal, parasagittal, and transverse. Bony structures (eg, the mandible and hyoid) were brightly hyperechoic with an underlying hypoechoic acoustic shadow. Cartilaginous structures (eg, the epiglottis, thyroid cartilage, cricoid cartilage, and tracheal rings) were hypoechoic, and their intraluminal surface was outlined by a bright air-mucosa interface. The vocal cords were readily visualized through the thyroid cartilage. However, the posterior pharynx, posterior commissure, and posterior wall of the trachea could not be visualized because of artifacts created by an intraluminal air column. CONCLUSIONS: Sonography of the upper airway is capable of providing detailed anatomic information and has numerous potential clinical applications.
OBJECTIVE: The purpose of this study was to evaluate the feasibility of sonography in identifying the anatomic structures of the upper airway and to describe their appearance on sonography. METHODS: We enrolled 24 healthy volunteers, placed them supine with their head extended and neck flexed (the "sniffing" position), and performed a systematic sonographic examination of their upper airway from the floor of the mouth to the suprasternal notch. RESULTS: We were able to visualize all relevant anatomic structures in all of the participants using either a linear or curved transducer oriented in 1 of 3 planes: sagittal, parasagittal, and transverse. Bony structures (eg, the mandible and hyoid) were brightly hyperechoic with an underlying hypoechoic acoustic shadow. Cartilaginous structures (eg, the epiglottis, thyroid cartilage, cricoid cartilage, and tracheal rings) were hypoechoic, and their intraluminal surface was outlined by a bright air-mucosa interface. The vocal cords were readily visualized through the thyroid cartilage. However, the posterior pharynx, posterior commissure, and posterior wall of the trachea could not be visualized because of artifacts created by an intraluminal air column. CONCLUSIONS: Sonography of the upper airway is capable of providing detailed anatomic information and has numerous potential clinical applications.
Authors: Mohamad Iqhbal; Julina M Noor; Nur A Karim; Izzat Ismail; Halim Sanib; Mohd A Mokhtar; Safreeda S F Salim Journal: Sultan Qaboos Univ Med J Date: 2018-09-09
Authors: Amit Diwakar; Ryan J Adam; Andrew S Michalski; Monelle M Tamegnon; Anthony J Fischer; Jan L Launspach; Rebecca A Horan; Simon C Kao; Kathryn Chaloner; David K Meyerholz; David A Stoltz Journal: Laryngoscope Date: 2015-03-30 Impact factor: 3.325
Authors: André Luiz Nunes Gobatto; Bruno A M P Besen; Paulo F G M M Tierno; Pedro V Mendes; Filipe Cadamuro; Daniel Joelsons; Livia Melro; Maria J C Carmona; Gregorio Santori; Paolo Pelosi; Marcelo Park; Luiz M S Malbouisson Journal: Intensive Care Med Date: 2016-02-01 Impact factor: 17.440