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LIMBIC SYSTEM NBIO 401 Robinson
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Objectives: -1) Be able to describe the major inputs and outputs, function, and the consequences of lesions or electrical stimulation for each of the six components of the limbic system that we described (i.e., hypothalamus, amygdala, hippocampus, cingulate cortex, nucleus accumbens, and septal nuclei) -2) Be able to describe the basic interconnections of the limbic system, and what fibers are in the three main fiber tracks described in the lecture: a) the stria terminalis, b) the fornix, and c) the medial forebrain bundle. -3) Be able to describe the location of these tracks in the brain. -4) Be able to explain the three ways in which it hypothalamic activity can act to maintain homeostasis. -5) Be able to explain the different mechanisms through which the hypothalamus controls the anterior and posterior pituitary gland. -6) Know the two functions of cortical input to the limbic system that we discussed.
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Objectives: -1) Be able to describe the major inputs and outputs, function, and the consequences of lesions or electrical stimulation for each of the six components of the limbic system that we described (i.e., hypothalamus, amygdala, hippocampus, cingulate cortex, nucleus accumbens, and septal nuclei) -2) Be able to describe the basic interconnections of the limbic system, and what fibers are in the three main fiber tracks described in the lecture: a) the stria terminalis, b) the fornix, and c) the medial forebrain bundle. -3) Be able to describe the location of these tracks in the brain. -4) Be able to explain the three ways in which it hypothalamic activity can act to maintain homeostasis. -5) Be able to explain the different mechanisms through which the hypothalamus controls the anterior and posterior pituitary gland. -6) Know the two functions of cortical input to the limbic system that we discussed.
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Objectives: -1) Be able to describe the major inputs and outputs, function, and the consequences of lesions or electrical stimulation for each of the six components of the limbic system that we described (i.e., hypothalamus, amygdala, hippocampus, cingulate cortex, nucleus accumbens, and septal nuclei) -2) Be able to describe the basic interconnections of the limbic system, and what fibers are in the three main fiber tracks described in the lecture: a) the stria terminalis, b) the fornix, and c) the medial forebrain bundle. -3) Be able to describe the location of these tracks in the brain. -4) Be able to explain the three ways in which it hypothalamic activity can act to maintain homeostasis. -5) Be able to explain the different mechanisms through which the hypothalamus controls the anterior and posterior pituitary gland. -6) Know the two functions of cortical input to the limbic system that we discussed.
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Objectives: -1) Be able to describe the major inputs and outputs, function, and the consequences of lesions or electrical stimulation for each of the six components of the limbic system that we described (i.e., hypothalamus, amygdala, hippocampus, cingulate cortex, nucleus accumbens, and septal nuclei) -2) Be able to describe the basic interconnections of the limbic system, and what fibers are in the three main fiber tracks described in the lecture: a) the stria terminalis, b) the fornix, and c) the medial forebrain bundle. -3) Be able to describe the location of these tracks in the brain. -4) Be able to explain the three ways in which it hypothalamic activity can act to maintain homeostasis. -6) Be able to explain the different mechanisms through which the hypothalamus controls the anterior and posterior pituitary gland. -7) Know the two functions of cortical input to the limbic system that we discussed.
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Objectives: -1) Be able to describe the major inputs and outputs, function, and the consequences of lesions or electrical stimulation for each of the six components of the limbic system that we described (i.e., hypothalamus, amygdala, hippocampus, cingulate cortex, nucleus accumbens, and septal nuclei) -2) Be able to describe the basic interconnections of the limbic system, and what fibers are in the three main fiber tracks described in the lecture: a) the stria terminalis, b) the fornix, and c) the medial forebrain bundle. -3) Be able to describe the location of these tracks in the brain. -4) Be able to explain the three ways in which it hypothalamic activity can act to maintain homeostasis. -5) Be able to explain the different mechanisms through which the hypothalamus controls the anterior and posterior pituitary gland. -6) Know the two functions of cortical input to the limbic system that we discussed.
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Objectives: -1) Be able to describe the major inputs and outputs, function, and the consequences of lesions or electrical stimulation for each of the six components of the limbic system that we described (i.e., hypothalamus, amygdala, hippocampus, cingulate cortex, nucleus accumbens, and septal nuclei) -2) Be able to describe the basic interconnections of the limbic system, and what fibers are in the three main fiber tracks described in the lecture: a) the stria terminalis, b) the fornix, and c) the medial forebrain bundle. -3) Be able to describe the location of these tracks in the brain. -4) Be able to explain the three ways in which it hypothalamic activity can act to maintain homeostasis. -5) Be able to explain the different mechanisms through which the hypothalamus controls the anterior and posterior pituitary gland. -6) Know the two functions of cortical input to the limbic system that we discussed.
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1)Hypothalamus 2)Amygdala 3)Hippocampus 4)Cingulate cortex 5)Nucleus accumbens 6)Septal nuclei
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1)Hypothalamus 2)Amygdala 3)Hippocampus 4)Cingulate cortex 5)Nucleus accumbens 6)Septal nuclei
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HYPOTHALAMUS
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Hypothalamus Inputs: -1) amygdala (via stria terminalis & direct) -2) hippocampus (via fornix) -3)septal nuclei (via medial forebrain bundle) -4) brainstem & spinal cord (via medial forebrain bundle)
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Hypothalamus Outputs: -1) amygdala (via stria terminalis) -2) hippocampus (via fornix) -3) septal nuclei (via medial forebrain bundle) -4) brainstem & spinal cord sympathetic and parasympathetic preganglionic neurons -5) pituitary (neural & humoral) -6) anterior thalamus (to prefrontal, orbital, & cingulate cortex)
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Hypothalamus Outputs: -1) amygdala (via stria terminalis) -2) hippocampus (via fornix) -3) septal nuclei (via medial forebrain bundle) -4) brainstem & spinal cord sympathetic and parasympathetic preganglionic neurons -5) pituitary (neural & humoral) -6) anterior thalamus (to prefrontal, orbital, & cingulate cortex)
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BA Autonomic Nervous System Sympathetic (fight or flight) Parasympathetic (rest & digest)
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The hypothalamus maintains homeostasis 3 ways: 1) changing the body via ANS 2) changing the body via pituitary gland 3) changing motivation for behavior
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The hypothalamus maintains homeostasis 3 ways: 1) changing the body via ANS 2) changing the body via pituitary gland 3) changing motivation for behavior
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The hypothalamus maintains homeostasis 3 ways: 1) changing the body via ANS 2) changing the body via pituitary gland 3) changing motivation for behavior
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INFUNDIBULUM (stalk of pituitary) OPTIC CHIASM
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INFUNDIBULUM (stalk of pituitary) OPTIC CHIASM
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INFUNDIBULUM (stalk of pituitary) OPTIC CHIASM
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INFUNDIBULUM (stalk of pituitary) OPTIC CHIASM
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The hypothalamus maintains homeostasis 3 ways: 1) action on body via ANS 2) action on body via pituitary gland 3) motivating behavioral solutions
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Hypothalamus Outputs: -1) amygdala (via stria terminalis) -2) hippocampus (via fornix) -3) septal nuclei (via medial forebrain bundle) -4) brainstem & spinal cord sympathetic and parasympathetic preganglionic neurons -5) pituitary (neural & humoral) -6) anterior thalamus (to prefrontal, orbital, & cingulate cortex)
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The hypothalamus maintains homeostasis 3 ways: 1) action on body via ANS 2) action on body via pituitary gland 3) motivating behavioral solutions
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The hypothalamus maintains homeostasis 3 ways: 1) action on body via ANS 2) action on body via pituitary gland 3) motivating behavioral solutions The hypothalamus also prepares the body for responses using stimuli that are not directly inside the body.
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The hypothalamus maintains homeostasis 3 ways: 1) action on body via ANS 2) action on body via pituitary gland 3) motivating behavioral solutions The hypothalamus also prepares the body for responses using stimuli that are not directly inside the body. Finally, the hypothalamus relays info about the body to the limbic system.
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The hypothalamus maintains homeostasis 3 ways: 1) action on body via ANS 2) action on body via pituitary gland 3) motivating behavioral solutions The hypothalamus also prepares the body for responses using stimuli that are not directly inside the body. Finally, the hypothalamus relays info about the body to the limbic system. The James-Lange theory.
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1)Hypothalamus 2)Amygdala 3)Hippocampus 4)Cingulate cortex 5)Nucleus accumbens 6)Septal nuclei
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Amygdala Inputs: -1) cortex (orbital, cingulate, entorhinal, & temporal) -2) hypothalamus (via stria terminalis & directly) -3) hippocampus -4) brainstem -5) septal nuclei -6) thalamus
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Amygdala Outputs: -1) cortex (orbital, cingulate, entorhinal, & temporal via thalamus) -2) hypothalamus (via stria terminalis & directly) -3) hippocampus -4) septal nuclei -5) thalamus
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Amygdala Functions: -1) connection between cortex & hypothalamus -2) probably mediates feeling of emotions (electrical stimulation elicits fear & can elicit same behaviors as stimulating hypothalamus but w/ more natural onset and offset) -3) lesions cause docile animals without fear
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Amygdala Functions: -1) connection between cortex & hypothalamus -2) probably mediates feeling of emotions (electrical stimulation elicits fear & can elicit same behaviors as stimulating hypothalamus but w/ more natural onset and offset) -3) lesions cause docile animals without fear
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Amygdala Functions: -1) connection between cortex & hypothalamus -2) probably mediates feeling of emotions (electrical stimulation elicits fear & can elicit same behaviors as stimulating hypothalamus but w/ more natural onset and offset) -3) lesions cause docile animals without fear
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1)Hypothalamus 2)Amygdala 3)Hippocampus 4)Cingulate cortex 5)Nucleus accumbens 6)Septal nuclei
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Hippocampus Inputs: -1) entorhinal cortex (receives input from cingulate, orbital, & prefrontal cortex) -2) amygdala -3) hypothalamus (via fornix)
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entorhinal cortex
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Prefrontal
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Hippocampus Inputs: -1) entorhinal cortex (receives input from cingulate, orbital, & prefrontal cortex) -2) amygdala -3) hypothalamus (via fornix)
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Prefrontal
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Hippocampus Inputs: -1) entorhinal cortex (receives input from cingulate, orbital, & prefrontal cortex) -2) amygdala -3) hypothalamus (via fornix)
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Prefrontal
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Hippocampus Outputs: -1) entorhinal cortex (receives input from cingulate, orbital, & prefrontal cortex) -2) anterior thalamus (to prefrontal, orbital, & cingulate cortex) -3) amygdala -4) hypothalamus (via fornix)
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Prefrontal
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Hippocampus Outputs: -1) entorhinal cortex (receives input from cingulate, orbital, & prefrontal cortex) -2) anterior thalamus (to prefrontal, orbital, & cingulate cortex) -3) amygdala -4) hypothalamus (via fornix)
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Prefrontal
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Hippocampus Outputs: -1) entorhinal cortex (receives input from cingulate, orbital, & prefrontal cortex) -2) anterior thalamus (to prefrontal, orbital, & cingulate cortex) -3) amygdala -4) hypothalamus (via fornix)
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Prefrontal
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Hippocampus Outputs: -1) entorhinal cortex (receives input from cingulate, orbital, & prefrontal cortex) -2) anterior thalamus (to prefrontal, orbital, & cingulate cortex) -3) amygdala (via fornix) -4) hypothalamus (via fornix)
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Prefrontal
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Hippocampus Functions: -1) mediates formation of new declarative memories -2) bilateral lesions impairs a patient’s ability to form new memories -3) lesions do not impair other memories, such as motor adaptation or learning motor tasks like a finger maze or doing a jigsaw puzzle.
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1)Hypothalamus 2)Amygdala 3)Hippocampus 4)Cingulate cortex 5)Nucleus accumbens 6)Septal nuclei
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Cingulate cortex Inputs: -1) VP (somatosensory) thalamus (pain) -2) anterior thalamus (also to orbital cortex)
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VP thalamus spinothalamic tract
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cingulate cortex VP thalamus spinothalamic tract
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cingulate cortex VP thalamus spinothalamic tract
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Cingulate cortex Inputs: -1) VP (somatosensory) thalamus (pain) -2) anterior thalamus (also to orbital cortex)
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Prefrontal
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Cingulate cortex Outputs: -1) entorhinal cortex -2) amygdala
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Prefrontal
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Cingulate cortex Outputs: -1) entorhinal cortex -2) amygdala
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Prefrontal
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Cingulate cortex Functions: -mediates emotional response to pain
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1)Hypothalamus 2)Amygdala 3)Hippocampus 4)Cingulate cortex 5)Nucleus accumbens 6)Septal nuclei
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Nucleus accumbens Inputs: -amygdala
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Prefrontal nucleus accumbens
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Prefrontal nucleus accumbens
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Prefrontal nucleus accumbens
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Nucleus accumbens Outputs: -basal ganglia
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Nucleus Accumbens Functions: -referred to as emotional component of the basal ganglia -mediates motivation and reinforcement, i.e., REWARD -appears to be a major site of action for may addictive drugs -these drugs increase dopamine in NA -blocking dopamine in NA strongly reduces pleasure from these drugs
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Nucleus Accumbens Functions: -referred to as emotional component of the basal ganglia -mediates motivation and reinforcement, i.e., REWARD -appears to be a major site of action for may addictive drugs -these drugs increase dopamine in NA -blocking dopamine in NA strongly reduces pleasure from these drugs
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Nucleus Accumbens Functions: -referred to as emotional component of the basal ganglia -mediates motivation and reinforcement, i.e., REWARD -appears to be a major site of action for may addictive drugs -these drugs increase dopamine in NA -blocking dopamine in NA strongly reduces pleasure from these drugs
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Nucleus Accumbens Functions: -referred to as emotional component of the basal ganglia -mediates motivation and reinforcement, i.e., REWARD -appears to be a major site of action for may addictive drugs -these drugs increase dopamine in NA -blocking dopamine in NA strongly reduces pleasure from these drugs
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Nucleus Accumbens Functions: -referred to as emotional component of the basal ganglia -mediates motivation and reinforcement, i.e., REWARD -appears to be a major site of action for may addictive drugs -these drugs increase dopamine in NA -blocking dopamine in NA strongly reduces pleasure from these drugs
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1)Hypothalamus 2)Amygdala 3)Hippocampus 4)Cingulate cortex 5)Nucleus accumbens 6)Septal nuclei
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Septal Nuclei Inputs: -hippocampus (via fornix) -amygdala
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Prefrontal
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Septal Nuclei Outputs: -hippocampus (via fornix) -hypothalamus (via stria terminalis) -amygdala (via medial forebrain bundle)
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Prefrontal
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Septal Nuclei Outputs: -hippocampus (via fornix) -hypothalamus (via stria terminalis) -amygdala (via medial forebrain bundle)
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Prefrontal
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stria terminalis
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Prefrontal stria terminalis
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Septal Nuclei Outputs: -hippocampus (via fornix) -hypothalamus (via stria terminalis) -amygdala (via medial forebrain bundle)
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Septal Nuclei Functions: -related to experience of pleasure -electrical stimulation of the septal nuclei humans causes extreme feelings of pleasure and joy -animals lever press for stimulation here to the exclusion of food and sleep -septal nuclei are more active during sexual orgasm -provide Ach input to hippocampus and may mediate some memory function -in some animals damage to septal nuclei cause “sham rage” in which animals become extremely violent and angry with little or no external stimuli
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Papez Circuit
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Ende
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