Evans Karleyton C, Banzett Robert B, Adams Lewis, McKay Leanne, Frackowiak Richard S J, Corfield Douglas R
Physiology Program, Harvard School of Public Health, Boston, Massachusetts 02115, USA.
J Neurophysiol. 2002 Sep;88(3):1500-11. doi: 10.1152/jn.2002.88.3.1500.
Air hunger (uncomfortable urge to breathe) is a component of dyspnea (shortness of breath). Three human H(2)(15)O positron emission tomography (PET) studies have identified activation of phylogenetically ancient structures in limbic and paralimbic regions during dyspnea. Other studies have shown activation of these structures during other sensations that alert the organism to urgent homeostatic imbalance: pain, thirst, and hunger for food. We employed blood oxygen level dependent (BOLD) functional magnetic resonance imaging (fMRI) to examine activation during air hunger. fMRI conferred several advantages over PET: enhanced signal-to-noise, greater spatial resolution, and lack of ionizing radiation, enabling a greater number of trials in each subject. Six healthy men and women were mechanically ventilated at 12-14 breaths/min. The primary experiment was conducted at mean end-tidal PCO(2) of 41 Torr. Moderate to severe air hunger was evoked during 42-s epochs of lower tidal volume (mean = 0.75 L). Subjects described the sensation as "like breath-hold," "urge to breathe," and "starved for air." In the baseline condition, air hunger was consistently relieved by epochs of higher tidal volume (mean = 1.47 L). A control experiment in the same subjects under a background of mild hypocapnia (mean end-tidal PCO(2) = 33 Torr) employed similar tidal volumes but did not evoke air hunger, controlling for stimulus variables not related to dyspnea. During each experiment, we maintained constant end-tidal PCO(2) and PO(2) to avoid systematic changes in global cerebral blood flow. Whole-brain images were acquired every 5 s (T2*, 56 slices, voxel resolution 3 x 3 x 3 mm). Activations associated with air hunger were determined using voxel-based interaction analysis of covariance that compared data between primary and control experiments (SPM99). We detected activations not seen in the earlier PET study using a similar air hunger stimulus (Banzett et al. 2000). Limbic and paralimbic loci activated in the present study were within anterior insula (seen in all 3 published studies of dyspnea), anterior cingulate, operculum, cerebellum, amygdala, thalamus, and basal ganglia. Elements of frontoparietal attentional networks were also identified. The consistency of anterior insular activation across subjects in this study and across published studies suggests that the insula is essential to dyspnea perception, although present data suggest that the insula acts in concert with a larger neural network.
空气饥饿感(呼吸的不适感)是呼吸困难(呼吸急促)的一个组成部分。三项人体H₂¹⁵O正电子发射断层扫描(PET)研究已确定,在呼吸困难期间,边缘和边缘旁区域中系统发生上古老的结构会被激活。其他研究表明,在其他使机体警觉到紧急内稳态失衡的感觉(疼痛、口渴和饥饿)期间,这些结构也会被激活。我们采用血氧水平依赖(BOLD)功能磁共振成像(fMRI)来检查空气饥饿感期间的激活情况。与PET相比,fMRI具有几个优势:更高的信噪比、更高的空间分辨率以及无电离辐射,从而能够在每个受试者身上进行更多次试验。六名健康男性和女性以每分钟12 - 14次呼吸的频率进行机械通气。主要实验在平均呼气末二氧化碳分压(PCO₂)为41托的条件下进行。在较低潮气量(平均 = 0.75升)的42秒时段内诱发中度至重度空气饥饿感。受试者将这种感觉描述为“像屏气”“呼吸冲动”和“渴望空气”。在基线状态下,较高潮气量(平均 = 1.47升)的时段能持续缓解空气饥饿感。在同一受试者中,在轻度低碳酸血症背景下(平均呼气末PCO₂ = 33托)进行的对照实验采用了类似的潮气量,但未诱发空气饥饿感,从而控制了与呼吸困难无关的刺激变量。在每个实验过程中,我们保持呼气末PCO₂和PO₂恒定,以避免全脑血流量出现系统性变化。每5秒采集一次全脑图像(T2*,56层,体素分辨率3×3×3毫米)。使用基于体素的协方差交互分析来确定与空气饥饿感相关的激活情况,该分析比较了主要实验和对照实验之间的数据(SPM99)。我们检测到了在早期PET研究中使用类似空气饥饿感刺激时未发现的激活情况(Banzett等人,2000年)。本研究中激活的边缘和边缘旁位点位于前岛叶(在所有三项已发表的呼吸困难研究中均可见)、前扣带回、脑岛盖、小脑、杏仁核、丘脑和基底神经节。还识别出了额顶叶注意力网络的组成部分。本研究中各受试者之间以及已发表研究中前岛叶激活的一致性表明,岛叶对于呼吸困难的感知至关重要,但现有数据表明岛叶与一个更大的神经网络协同作用。
