• Animal cells and systems
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• 제2권1호
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• pp.71-80
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• 1998

Glutamate dehydrogenase (GDH) is one of the main enzymes involved in the formation and metabolism of the neurotransmitter glutamate. In the present study, we investigated the distribution of the GDH-immunoreactive cells in the rat brain using monoclonal antibodies against bovine brain GDH isoprotein. GDH-immunoreactive cell were distributed in the basal ganglia, thalamus and the nuclei belong to substantia innominata, and its connecting area, subthalamic nucleus, zona incerta, and substantia niqra. We could see GDH-immunoreactive cells in the hippocampus, septal nuclei associated with the limbic system, the anterior thalamic nuclei connecting between the hypothalamus and limbic system, and its associated structures, amygdaloid nuclear complex, the dorsal raphe and median raphe nuclei and the reticular formation of the midbrain. The GDH-immunoreactive cells were shown in the pyramidal neurons of the cerebral cortex, the Purkinie cells of the cerebella cortex, their associated structures, ventral thalamic nuclei and the reticular thalamic nuclei that seem to function as neural conduction in the thalamus.

• 감성과학
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• 제12권4호
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• pp.443-450
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• 2009

본 연구에서는 공간 과제 수행 시 21%의 산소 농도와 30%의 고농도 산소 공급이 변연계의 활성화에 어떠한 변화를 유발하는지 관찰하였다. 총 8명의 오른손잡이 남자 대학생을 본 연구의 실험 참여자로 선정하였다. 공간 과제를 수행하는 동안 3T MRI 를 이용하여 뇌기능 영상을 획득하였다. 실험은 21%의 일반 공기 중의 산소 농도와 30%의 고농도 산소를 각각 공급하면서 공간 인지 과제를 수행하는 두 개의 회기로 구성된다. 변연계를 대상이랑(cingulate gyrus), 시상(thalamus), 변연엽(limbic lobe), 시상하부(hypothalamus), 해마(hippocampus), 해마방회(parahippocampa gyrus), 편도(amygdala), 유두체(mammilary body)의 8 개의 영역으로 분리하여 뇌 활성화 영역을 비교하였다. 공간 과제 수행 시 두 가지 산소 농도에 따른 변연계의 활성화 영역은 거의 동일하였다. 그러나 21%의 산소 농도에 비해 30%의 고농도 산소 공급 시 대상이랑(cingulate gyrus)과 시상(thalamus) 영역에서 활성화가 증가하였다. 즉, 30%의 고농도 산소 공급 시 공간 인지 수행 능력의 증가는 공간 인지 처리와 관련이 있는 대뇌 피질 뿐만 아니라 시상(thalamus)과 대상이랑(cingulate gyrus) 같은 피질하 영역에서의 신경 활성화의 증가와도 관련이 있는 것으로 판단된다.

• Journal of Yeungnam Medical Science
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• 제16권1호
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• pp.25-33
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• 1999

세계적으로 그 처방률이 높은 약물들 중 하나인 benzodiazepine계 약물은, 강력한 불안해소작용, 항경련작용, 최면작용 및 근이완작용을 가지고 있다. Benzodiazepine계 약물의 약리작용기전과 관련하여 불안장애의 병인에서 각종 신경전달계의 역할은 밝혀지고 있다. Benzodiazepine 약물은 편도체와 같은 변연계, 우측 시상하부 및 raphe nuclei에서 GALA성 신경전달을 조절함으로써 불안해소 작용을 나타내는 것으로 보고되었으며, 공포와 스트레스로 인해 유발되는 행동에 있어서 편도체의 역할은 이미 여러 보고를 통해 시사된 바 있다. 본 종설에서는 GABA성 신경전달 조절작용이 있다고 보고된 내인성 benzodiazepine 수용체 배위자의 불안 및 스트레스 반응의 인지 조절작용 및 기억 형성과정 조절작용 등에 관한 연구결과들을 종합하여 본 결과 내인성 benzodiazepine 수용체 배위자들이 불쾌한 학습과정에 동반되는 스트레스와 불안의 정도에 영향을 미침으로써 기억 형성과정을 조절한다는 생각을 뒷받침해 주었다. 또한 각종 행동 검사후 나타나는 뇌조직의 benzodiazepine 유사 물질의 부위별(편도체, 해마, 중격) 농도 감소는 행동 검사에 수반되는 스트레스 및 불안 정도에 비례하므로, 이러한 물질의 감소는 스트레스 및 불안에 대한 변연계의 일반적인 반응으로 생각된다. 부가적으로 이러한 결과는 변연계의 $GABA_A$/benzodiazepine 수용체 복합체는 생체의 스트레스 및 불안반응의 생리, 생화학적 면에서 중추적인 역할을 한다는 생각을 할 수 있게 하는 결과라 할 수 있다.

• Applied Microscopy
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• 제18권1호
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• pp.35-48
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• 1988

To investigate the connections between the major limbic structures and the nucleus accumbens septi or the nucleus fundus striati, stereotaxic surgeries were performed. One group of the rats were electrically lesioned in the mamillary body, and the other group were extirpated their hippocampal formation. Careful study of both nuclei following each surgery showed the following results. 1. Nerve terminals of mamillo-accumbens tract were synapsed to the dendrite of nucleus accumbens cell, whereas the neuronal type of accumbens-mamillary tract was aspiny cell. 2. Nerve terminals of mamillo-fundus tract were synapsed to the spines of fundus striati cells. Fundus-mamillary tract cells were not confirmed. 3. Nerve terminals of hippocampo-accumbens terminals were synapsed to the dendrites and spines of nucleus accumbens cells, whereas the neuronal type of accumbens-hippocampal tract was spiny one. 4. Nerve terminals of hippocampo-fundus tract were synapsed to the spines of fundus striati cells, whereas the neuronal types of fundus-hippocampal tract was aspiny one. 5. From the results, it was concluded that both of the nucleus accumbens septi and the fundus striati have connections with the mamillary body and the hippocampus. But nucleus accumbens septi has apparently more intimate relationship with major limbic structures.

• The Korean Journal of Physiology and Pharmacology
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• 제7권6호
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• pp.307-310
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• 2003

Kainic acid (KA) is a structural analogue of glutamate that interacts with specific presynaptic and postsynaptic receptors to potentiate the release and excitatory actions of glutamate. Systemic or intracerebroventricular (i.c.v.) administration of KA to experimental animals elicits multifocal seizures with a predominantly limbic localization, and results in neuronal death of cornu ammonia 1 (CA1), reactive gliosis and biochemical changes in the hippocampus and other limbic structures. Several lines of evidence suggest that reactive oxygen species (ROS) play a pivotal role in the pathogenesis of excitotoxic death by KA. Curcumin has been known to possess anti-oxidative and anti-inflammatory activities. In this study, the effects of curcumin on KA induced hippocampal cell death, reactive gliosis and biochemical changes in reactive glia were investigated by immunohistochemical methods. Our data demonstrated that curcumin attenuated KA-induced astroglial and microglial activation although it did not protect KA-induced hippocampal cell death.

• 수면정신생리
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• 제5권2호
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• pp.119-133
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• 1998

Attentional processes facilitate cognitive and behavioral performance in several ways. Attention serves to reduce the amount of information to receive. Attention enables humans to direct themselves to appropriate aspects of external environmental events and internal operations. Attention facilitates the selection of salient information and the allocation of cognitive processing appropriate to that information. Attention is not a unitary process that can be localized to a single neuroanatomical region. Before the cortical registration of sensory information, activation of important subcortical structures occurs, which is called as an orienting response. Once sensory information reaches the sensory cortex, a large number of perceptual processes occur, which provide various levels of perceptual resolution of the critical features of the stimuli. After this preattentional processing, information is integrated within higher cortical(heteromodal) systems in inferior parietal and temporal lobes. At this stage, the processing characteristics can be modified, and the biases of the system have a direct impact on attentional selection. Information flow has been traced through sensory analysis to a processing stage that enables the new information to be focused and modified in relation to preexisting biases. The limbic and paralimbic system play significant roles in modulating attentional response. It is labeled with affective salience and is integrated according to ongoing pressures from the motivational drive system of the hypothalamus. The salience of information greatly influences the allocation of attention. The frontal lobe operate response selection system with a reciprocal interaction with both the attention system of the parietal lobe and the limbic system. In this attentional process, the search with the spatial field is organized and a sequence of attentional responses is generated. Affective, motivational and appectitive impulses from limbic system and hypothalamus trigger response intention, preparation, planning, initiation and control of frontal lobe on this process. The reticular system, which produces ascending activation, catalyzes the overall system and increases attentional capacity. Also additional energetic pressures are created by the hypothalamus. As psychophysiological measurement, skin conductance, pupil diameter, muscle tension, heart rate, alpha wave of EEG can be used. Event related potentials also provide physiological evidence of attention during information process. NI component appears to be an electrophysiological index of selective attention. P3 response is developed during the attention related to stimulus discrimination, evaluation and response.

• 감성과학
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• 제2권1호
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• pp.1-25
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• 1999

The differentiation of emotions by means of psychophysiological measures has been only moderately successful so far. A major reason for this dilemma may be the lack of appropriate neurophysiological modeling for the various autonomic nervous system based measures being used in emotion research. The aim of the present article is to provide such a neurophysiological background for electrodermal activity which has been frequently used as an indicator of emotional processes. First, the literature is reviewd with respect to the usability of electrodermal measures as an indicators of emotion. second, the neurophysilogical sources of electrodermal phenomena in general are described. Electrodermal activity has different origins in the central nervous system, a limbic-hypothalamic source that dominates during negative emotions as opposed to a premotor and basal ganglia source being predominantly active during positive emotions. Panksepp's model of four basic emotive systems is adopted for demonstrating subcortical structures and pathways possibly involved in the elicitation of both kinds of electrodermal activity in comparison with cardiovascular in dicators of emotional processes.

• Advances in Traditional Medicine
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• 제4권2호
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• pp.65-69
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• 2004

Acupuncture as a therapeutic intervention has been widely used for treatment for many functional disorders, such as substances abuse and mental dysfunction. In general, acupuncture is known to be simple, economic; painless, non-traumatic, and without untoward reaction, being able to inhibit the abstinence syndrome. Although a number of studies on acupuncture have been reported, a few studies described acupuncture effect on drug addiction. Evidences suggest that substances abuses including nicotine, cocaine and alcohol are in part related to its effects on dopamine neurons in the reward pathways of the brain. The effects of acupuncture on drug addiction may be mediated through the neuronal cells within the limbic structures, which are known to be involved in rewarding properties of drug abuse. This essay reviews clinical and experimental evidences for its effectiveness on the drug addiction, and discusses a plausible explanation for the mechanism of acupuncture on substances abuse.

• Investigative Magnetic Resonance Imaging
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• 제19권1호
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• pp.1-9
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• 2015

Purpose: Several morphometric studies have been performed to investigate brain abnormalities in congenitally deaf people. But no report exists concerning structural brain abnormalities in congenitally deaf adolescents. We evaluated the regional volume changes in gray matter (GM) using voxel-based morphometry (VBM) in congenitally deaf adolescents. Materials and Methods: A VBM8 methodology was applied to the T1-weighted magnetic resonance imaging (MRI) scans of eight congenitally deaf adolescents (mean age, 15.6 years) and nine adolescents with normal hearing. All MRI scans were normalized to a template and then segmented, modulated, and smoothed. Smoothed GM data were tested statistically using analysis of covariance (controlled for age, gender, and intracranial cavity volume). Results: The mean values of age, gender, total volumes of GM, and total intracranial volume did not differ between the two groups. In the auditory centers, the left anterior Heschl's gyrus and both inferior colliculi showed decreased regional GM volume in the congenitally deaf adolescents. The GM volumes of the lingual gyri, nuclei accumbens, and left posterior thalamic reticular nucleus in the midbrain were also decreased. Conclusions: The results of the present study suggest that early deprivation of auditory stimulation in congenitally deaf adolescents might have caused significant underdevelopment of the auditory cortex (left Heschl's gyrus), subcortical auditory structures (inferior colliculi), auditory gain controllers (nucleus accumbens and thalamic reticular nucleus), and multisensory integration areas (inferior colliculi and lingual gyri). These defects might be related to the absence of general auditory perception, the auditory gating system of thalamocortical transmission, and failure in the maturation of the auditory-to-limbic connection and the auditorysomatosensory-visual interconnection.

• 한국초등과학교육학회지:초등과학교육
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• 제24권1호
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• pp.86-101
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• 2005

In this study, a brain-basrd model for science teaching and learning was developed based on the natural processes which human acquire knowledge about a natural object or on event, the major domains of science educational objectives of the national curriculum, and the human brain's organizational patterns and functions. In the model, each educational objective domain is related to the brain regions as follows: The affective domain is related to the limbic system, especially amygdala of human brain which is involved in emotions, the psychomotor domain is related to the occipital lobes of human brain which perform visual processing, temporal lobes which perform functions of language generating and understandng, and parietal lobes which receive and process sensory information and execute motor activities of body, and the cognitive domain is related to the frontal and prefrontal lobes which are involved in think-ing, planning, judging, and problem solving. The model is a kind of procedural model which proceed fiom affective domain to psychomotor domain, and to cognitive domain of science educational objective system, and emphasize the order of each step and authentic assessment at each step. The model has both properties of circularity and network of activities. At classrooms, the model can be used as various forms according to subjects and student characteristics. STS themes can be appropriately covered by the model.