Hirano Yoji, Oribe Naoya, Kanba Shigenobu, Onitsuka Toshiaki, Nestor Paul G, Spencer Kevin M
Neural Dynamics Laboratory, Research Service, Veterans Affairs Boston Healthcare System, Boston, Massachusetts2Department of Psychiatry, Harvard Medical School, Boston, Massachusetts3Department of Neuropsychiatry, Graduate School of Medical Sciences, Kyus.
Department of Neuropsychiatry, Graduate School of Medical Sciences, Kyushu University, Fukuoka, Japan.
JAMA Psychiatry. 2015 Aug;72(8):813-21. doi: 10.1001/jamapsychiatry.2014.2642.
A major goal of translational neuroscience is to identify neural circuit abnormalities in neuropsychiatric disorders that can be studied in animal models to facilitate the development of new treatments. Oscillations in the gamma band (30-100 Hz) of the electroencephalogram have received considerable interest as the basic mechanisms underlying these oscillations are understood, and gamma abnormalities have been found in schizophrenia (SZ). Animal models of SZ based on hypofunction of the N-methyl-d-aspartate receptor (NMDAR) demonstrate increased spontaneous broadband gamma power, but this phenomenon has not been identified clearly in patients with SZ.
To examine spontaneous gamma power and its relationship to evoked gamma oscillations in the auditory cortex of patients with SZ.
DESIGN, SETTING, AND PARTICIPANTS: We performed a cross-sectional study including 24 patients with chronic SZ and 24 matched healthy control participants at the Veterans Affairs Boston Healthcare System from January 1, 2009, through December 31, 2012. Electroencephalograms were obtained during auditory steady-state stimulation at multiple frequencies (20, 30, and 40 Hz) and during a resting state in 18 participants in each group.
Electroencephalographic activity in the auditory cortex was estimated using dipole source localization. Auditory steady-state response (ASSR) measures included the phase-locking factor and evoked power. Spontaneous gamma power was measured as induced (non-phase-locked) gamma power in the ASSR data and as total gamma power in the resting-state data.
The ASSR phase-locking factor was reduced significantly in patients with SZ compared with controls for the 40-Hz stimulation (mean [SD], 0.075 [0.028] vs 0.113 [0.065]; F1,46 = 6.79 [P = .012]) but not the 20- or the 30-Hz stimulation (0.042 [0.038] vs 0.043 [0.034]; F1,46 = 0.006 [P = .938] and 0.084 [0.040] vs 0.098 [0.050]; F1,46 = 1.605 [P = .212], respectively), repeating previous findings. The mean [SD] broadband-induced (30-100 Hz) gamma power was increased in patients with SZ compared with controls during steady-state stimulation (6.579 [3.783] vs 3.984 [1.843]; F1,46 = 9.128 [P = .004]; d = 0.87) but not during rest (0.006 [0.003] vs 0.005 [0.002]; F1,34 = 1.067 [P = .309]; d = 0.35). Induced gamma power in the left hemisphere of the patients with SZ during the 40-Hz stimulation was positively correlated with auditory hallucination symptoms (tangential, ρ = 0.587 [P = .031]; radial, ρ = 0.593 [P = .024]) and negatively correlated with the ASSR phase-locking factor (baseline: ρ = -0.572 [P = .024]; ASSR: ρ = -0.568 [P = .032]).
Spontaneous gamma activity is increased during auditory steady-state stimulation in SZ, reflecting a disruption in the normal balance of excitation and inhibition. This phenomenon interacts with evoked oscillations, possibly contributing to the gamma ASSR deficit found in SZ. The similarity of increased spontaneous gamma power in SZ to the findings of increased spontaneous gamma power in animal models of NMDAR hypofunction suggests that spontaneous gamma power could serve as a biomarker for the integrity of NMDARs on parvalbumin-expressing inhibitory interneurons in humans and in animal models of neuropsychiatric disorders.
转化神经科学的一个主要目标是确定神经精神疾病中的神经回路异常,这些异常可在动物模型中进行研究,以促进新疗法的开发。脑电图γ波段(30 - 100赫兹)的振荡受到了广泛关注,因为其潜在的基本机制已为人所知,并且在精神分裂症(SZ)中发现了γ异常。基于N - 甲基 - D - 天冬氨酸受体(NMDAR)功能减退的SZ动物模型显示出自发性宽带γ功率增加,但在SZ患者中尚未明确鉴定出这种现象。
研究SZ患者听觉皮层的自发性γ功率及其与诱发γ振荡的关系。
设计、设置和参与者:我们进行了一项横断面研究,纳入了2009年1月1日至2012年12月31日在波士顿退伍军人事务医疗保健系统的24例慢性SZ患者和24名匹配的健康对照参与者。每组18名参与者在多个频率(20、30和40赫兹)的听觉稳态刺激期间以及静息状态下记录脑电图。
使用偶极子源定位估计听觉皮层的脑电图活动。听觉稳态反应(ASSR)测量指标包括锁相因子和诱发功率。自发性γ功率在ASSR数据中测量为诱发(非锁相)γ功率,在静息状态数据中测量为总γ功率。
与对照组相比,SZ患者在40赫兹刺激时ASSR锁相因子显著降低(均值[标准差],0.075[0.028]对0.113[0.065];F1,46 = 6.79[P = 0.012]),但在20赫兹或30赫兹刺激时未降低(0.042[0.038]对0.043[0.034];F1,46 = 0.006[P = 0.938]以及0.084[0.040]对0.098[0.050];F1,46 = 1.605[P = 0.212]),重复了先前的发现。与对照组相比,SZ患者在稳态刺激期间宽带诱发(30 - 100赫兹)γ功率均值[标准差]增加(6.579[3.783]对3.984[1.843];F1,46 = 9.128[P = 0.004];d = 0.87),但在静息时未增加(0.006[0.003]对0.005[0.002];F1,34 = 1.067[P = 0.309];d = 0.35)。在40赫兹刺激期间,SZ患者左半球的诱发γ功率与幻听症状呈正相关(切线方向,ρ = 0.587[P = 0.031];径向方向,ρ = 0.593[P = 0.024]),与ASSR锁相因子呈负相关(基线:ρ = -0.572[P = 0.024];ASSR:ρ = -0.568[P = 0.0
