Freiberger J J, Derrick B J, Natoli M J, Akushevich I, Schinazi E A, Parker C, Stolp B W, Bennett P B, Vann R D, Dunworth S A S, Moon R E
Duke Center for Hyperbaric Medicine and Environmental Physiology and Department of Anesthesiology, Duke University Medical Center, Durham, North Carolina
Duke Center for Hyperbaric Medicine and Environmental Physiology and Department of Anesthesiology, Duke University Medical Center, Durham, North Carolina.
J Appl Physiol (1985). 2016 Oct 1;121(4):953-964. doi: 10.1152/japplphysiol.00534.2016. Epub 2016 Sep 15.
Diving narcosis results from the complex interaction of gases, activities, and environmental conditions. We hypothesized that these interactions could be separated into their component parts. Where previous studies have tested single cognitive tasks sequentially, we varied inspired partial pressures of CO, N, and O in immersed, exercising subjects while assessing multitasking performance with the Multi-Attribute Task Battery II (MATB-II) flight simulator. Cognitive performance was tested under 20 conditions of gas partial pressure and exercise in 42 male subjects meeting U.S. Navy age and fitness profiles. Inspired nitrogen (N) and oxygen (O) partial pressures were 0, 4.5, and 5.6 ATA and 0.21, 1.0, and 1.22 ATA, respectively, at rest and during 100-W immersed exercise with and without 0.075-ATA CO Linear regression modeled the association of gas partial pressure with task performance while controlling for exercise, hypercapnic ventilatory response, dive training, video game frequency, and age. Subjects served as their own controls. Impairment of memory, attention, and planning, but not motor tasks, was associated with N partial pressures >4.5 ATA. Sea level O at 0.925 ATA partially rescued motor and memory reaction time impaired by 0.075-ATA CO; however, at hyperbaric pressures an unexpectedly strong interaction between CO, N, and exercise caused incapacitating narcosis with amnesia, which was augmented by O Perception of narcosis was not correlated with actual scores. The relative contributions of factors associated with diving narcosis will be useful to predict the effects of gas mixtures and exercise conditions on the cognitive performance of divers. The O effects are consistent with O narcosis or enhanced O toxicity.
潜水麻醉是气体、活动和环境条件复杂相互作用的结果。我们假设这些相互作用可以分解为其组成部分。以往的研究依次测试单个认知任务,而我们在浸没且进行运动的受试者中改变吸入的一氧化碳(CO)、氮气(N)和氧气(O)的分压,同时使用多属性任务电池II(MATB-II)飞行模拟器评估多任务表现。在42名符合美国海军年龄和体能标准的男性受试者中,在20种气体分压和运动条件下测试认知表现。在休息时以及在100瓦浸没运动期间,无论有无0.075ATA的CO,吸入的氮气(N)和氧气(O)分压分别为0、4.5和5.6ATA以及0.21、1.0和1.22ATA。线性回归在控制运动、高碳酸血症通气反应、潜水训练、电子游戏频率和年龄的同时,模拟了气体分压与任务表现之间的关联。受试者自身作为对照。记忆、注意力和计划能力受损,但运动任务不受影响,与N分压>4.5ATA有关。0.925ATA的海平面O部分挽救了因0.075ATA的CO而受损的运动和记忆反应时间;然而,在高压下,CO、N和运动之间意外地出现了强烈相互作用,导致伴有失忆的致残性麻醉,O会加剧这种情况。麻醉的感知与实际分数无关。与潜水麻醉相关因素的相对贡献将有助于预测气体混合物和运动条件对潜水员认知表现的影响。O的作用与O麻醉或增强的O毒性一致。
