精神分裂症中的抑制缺陷不一定是γ-氨基丁酸能缺陷。
Inhibitory deficit in schizophrenia is not necessarily a GABAergic deficit.
作者信息
Lara Diogo R
机构信息
Departamento de Ciências Fisiológicas, Faculdade de Ciências Biológicas, PUCRS, Porto Alegre, Brazil.
出版信息
Cell Mol Neurobiol. 2002 Jun;22(3):239-47. doi: 10.1023/a:1020759615977.
Abstract
- Current evidence strongly supports the idea of an inhibitory deficit as a central pathophysiological mechanism in schizophrenia. This deficit has been well documented in sensory gating and paired-pulse studies and may be related to decreases in inhibitory interneurons found in schizophrenic patients. 2. The GABAergic system has been repeatedly postulated to mediate this deficit, but the findings are controversial, at least in some areas, and mostly negative regarding treatment with drugs enhancing GABAergic activity. Therefore, the scope of mediators of this inhibitory deficit should be widened and the neuromodulator adenosine is proposed as a candidate to be further studied. 3. A state of adenosinergic hypoactivity in schizophrenia is compatible not only with the inhibitory deficit but also with symptoms, clinical response to antipsychotics, impaired sensory gating, deteriorating course, increased smoking, and sleep alterations reported in schizophrenia. 4. It is concluded that although the GABAergic system should be further studied, especially in sensory gating model in humans, emphasis on other inhibitory mechanisms may prove useful and provide more effective treatment.
摘要
- 当前证据有力支持抑制功能缺陷是精神分裂症核心病理生理机制这一观点。这种缺陷在感觉门控和双脉冲研究中已有充分记录,可能与精神分裂症患者中抑制性中间神经元减少有关。2. 人们多次推测GABA能系统介导这种缺陷,但研究结果存在争议,至少在某些方面如此,而且关于增强GABA能活性药物治疗的研究大多呈阴性。因此,应拓宽这种抑制功能缺陷的介导因子范围,并提出神经调质腺苷作为有待进一步研究的候选因子。3. 精神分裂症中腺苷能活性低下的状态不仅与抑制功能缺陷相符,还与精神分裂症中报告的症状、对抗精神病药物的临床反应、感觉门控受损、病情恶化、吸烟增加及睡眠改变相符。4. 得出的结论是,虽然应进一步研究GABA能系统,尤其是在人类感觉门控模型中,但重视其他抑制机制可能会证明有用,并提供更有效的治疗方法。
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3
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4
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