Brennick Michael J, Pickup Stephen, Dougherty Lawrence, Cater Jacqueline R, Kuna Samuel T
Center for Sleep and Respiratory Neurobiology, University of Pennsylvania, 991 Maloney Building, 3600 Spruce Street, Philadelphia, PA 19104, USA.
J Physiol. 2004 Dec 1;561(Pt 2):597-610. doi: 10.1113/jphysiol.2004.073502. Epub 2004 Oct 7.
To better understand pharyngeal airway mechanics as it relates to the pathogenesis and treatment of obstructive sleep apnoea, we have developed a novel application of magnetic resonance imaging (MRI) with non-invasive tissue tagging to measure pharyngeal wall tissue motion during active dilatation of the airway. Eleven anaesthetized Sprague-Dawley rats were surgically prepared with platinum electrodes for bilateral stimulation of the medial branch of the hypoglossus nerve that supplies motor output to the protrudor and intrinsic tongue muscles. Images of the pharyngeal airway were acquired before and during stimulation using a gated multislice, spoiled gradient recalled (SPGR) imaging protocol in a 4.7 T magnet. The tag pulses, applied before stimulation, created a grid pattern of magnetically imbedded dark lines that revealed tissue motion in images acquired during stimulation. Stimulation significantly increased cross-sectional area, and anteroposterior and lateral dimensions in the oropharyngeal and velopharyngeal airways when results were averaged across the rostral, mid- and caudal pharynx (P < 0.001). Customized software for tissue motion-tracking and finite element-analysis showed that changes in airway size were associated with ventral displacement of tissues in the ventral pharyngeal wall in the rostral, mid- and caudal pharyngeal regions (P < 0.0032) and ventral displacement of the lateral walls in the mid- and caudal regions (P < 0.0001). In addition, principal maximum stretch was significantly increased in the lateral walls (P < 0.023) in a ventral-lateral direction in the mid- and caudal pharyngeal regions and principal maximum compression (perpendicular to stretch) was significantly increased in the ventral walls in all regions (P < 0.0001). Stimulation did not cause lateral displacement of the lateral pharyngeal walls at any level. The results reveal that the increase in pharyngeal airway size resulting from stimulation of the medial branch of the hypoglossal nerve is predominantly due to ventral displacement of the ventral and lateral pharyngeal walls.
为了更好地理解与阻塞性睡眠呼吸暂停的发病机制和治疗相关的咽气道力学,我们开发了一种磁共振成像(MRI)的新应用,通过无创组织标记来测量气道主动扩张期间咽壁组织的运动。对11只麻醉的Sprague-Dawley大鼠进行手术,植入铂电极以双侧刺激舌下神经内侧支,该神经为舌突出肌和舌内肌提供运动输出。在4.7T磁体中,使用门控多层扰相梯度回波(SPGR)成像协议在刺激前和刺激期间采集咽气道图像。在刺激前施加标记脉冲,产生了磁性嵌入暗线的网格图案,揭示了刺激期间采集的图像中的组织运动。当对咽前部、中部和尾部的结果进行平均时,刺激显著增加了口咽和腭咽气道的横截面积、前后径和左右径(P<0.001)。用于组织运动跟踪和有限元分析的定制软件显示,气道大小的变化与咽前部、中部和尾部区域腹侧咽壁组织的腹侧移位有关(P<0.0032),以及中部和尾部区域侧壁的腹侧移位有关(P<0.0001)。此外,在中部和尾部咽区域,侧壁在腹侧-外侧方向的主最大拉伸显著增加(P<0.023),并且在所有区域腹侧壁的主最大压缩(垂直于拉伸)显著增加(P<0.0001)。刺激在任何水平都不会导致咽侧壁的侧向移位。结果表明,刺激舌下神经内侧支导致的咽气道大小增加主要是由于腹侧和外侧咽壁的腹侧移位。