Ramirez Sanja, Allen Travis, Villagracia Lindsay, Chae Yooree, Ramirez Jan M, Rubens Daniel D
Center for Integrative Brain Research, Seattle Children's Research Institute, 1900 Ninth Avenue, Seattle, WA 98101, United States.
Department of Anesthesia, Seattle Children's Hospital, 4800 Sandpoint Way NE, Seattle, WA 98105, United States; Center for Integrative Brain Research, Seattle Children's Research Institute, 1900 Ninth Avenue, Seattle, WA 98101, United States; Department of Anesthesia, University of Washington, Seattle, WA, United States.
Neuroscience. 2016 Nov 19;337:9-16. doi: 10.1016/j.neuroscience.2016.08.054. Epub 2016 Sep 12.
Infants that succumb to Sudden Infant Death Syndrome (SIDS) have been identified with inner ear dysfunction (IED) at birth and on autopsy. We previously investigated whether IED could play a mechanistic role in SIDS. We discovered that animals with IED displayed significant suppression of movement arousal to a hypoxic-hypercarbic gas mixture under light anesthesia. In the current study we investigated the role of each gas in triggering movements and the response to hypercarbia during natural sleep without anesthesia. Seventeen-day-old CD-1 mice received intra-tympanic gentamicin (IT-Gent) injections to precipitate IED. The movement response to hypercarbia, hypoxia and hypoxia-hypercarbia was compared to controls under light anesthesia. Hypercarbia did not stimulate vigorous movements in any animals under either sleep condition. Hypoxia triggered vigorous movements in controls (p<0.05) and a decreased response in IT-Gent animals under light anesthesia. This contrasted with combined hypoxia-hypercarbia, in which IT-Gent animals displaced significantly suppressed movements compared to controls (p<0.05). Our findings portray that a degree of intact inner ear function is necessary for instigating the movement response. Additionally, hypoxia is the trigger for the movement response while carbon dioxide (CO) suppresses it. The finding that carbon dioxide did not stimulate movement during natural sleep is an important finding. This contrasts with other studies that have identified hypercarbia as an arousal stimulus with EEG. Further studies are warranted to evaluate the precise role of the inner ear in the movement response and potential association with SIDS. The early detection of IED in SIDS predisposed cases could be invaluable.
死于婴儿猝死综合征(SIDS)的婴儿在出生时及尸检时被发现存在内耳功能障碍(IED)。我们之前研究了IED是否在SIDS中发挥机制性作用。我们发现,患有IED的动物在轻度麻醉下对低氧 - 高碳酸气体混合物的运动觉醒表现出显著抑制。在当前研究中,我们研究了每种气体在自然睡眠且无麻醉状态下触发运动以及对高碳酸血症反应中的作用。17日龄的CD - 1小鼠接受鼓室内庆大霉素(IT - Gent)注射以诱发IED。在轻度麻醉下,将对高碳酸血症、低氧和低氧 - 高碳酸血症的运动反应与对照组进行比较。在任何一种睡眠状态下,高碳酸血症均未刺激任何动物产生剧烈运动。低氧在对照组中触发了剧烈运动(p<0.05),而在轻度麻醉下IT - Gent处理的动物中反应减弱。这与低氧 - 高碳酸血症联合情况形成对比,其中与对照组相比,IT - Gent处理的动物明显表现出运动抑制(p<0.05)。我们的研究结果表明,一定程度的内耳功能完整性对于引发运动反应是必要的。此外,低氧是运动反应的触发因素,而二氧化碳(CO)则抑制该反应。二氧化碳在自然睡眠期间未刺激运动这一发现是一项重要发现。这与其他将高碳酸血症确定为脑电图觉醒刺激的研究形成对比。有必要进行进一步研究以评估内耳在运动反应中的精确作用以及与SIDS的潜在关联。在SIDS易患病例中早期检测IED可能具有重要价值。
