Distributed neural representations of conditioned threat in the human brain |
|
An AAV-CRISPR/Cas9 strategy for gene editing across divergent rodent species: Targeting neural oxytocin receptors as a proof of concept |
|
Joseph LeDoux |
|
A generative adversarial model of intrusive imagery in the human brain |
|
Deep history and beyond: a reply to commentators |
|
The Deep History of Ourselves: The Four-Billion-Year Story of How We Got Conscious Brains |
|
Temporally and anatomically specific contributions of the human amygdala to threat and safety learning |
|
Validation of an Updated Brain Circuit to Decode the Neural Signature of Threat Conditioning and Fear Homeostasis |
|
The modulation of emotional and social behaviors by oxytocin signaling in limbic network |
|
The day I told Karim Nader, “Don't do the study” |
|
Putting the “mental” back in “mental disorders”: a perspective from research on fear and anxiety |
|
As soon as there was life, there was danger: the deep history of survival behaviours and the shallower history of consciousness |
|
Conditional Control of Instrumental Avoidance by Context Following Extinction |
|
Upregulation of eIF4E, but not other translation initiation factors, in dendritic spines during memory formation |
|
Observation of others’ threat reactions recovers memories previously shaped by firsthand experiences |
|
What emotions might be like in other animals |
|
The extra ingredient |
|
Correlation between rostral dorsomedial prefrontal cortex activation by trauma-related words and subsequent response to cbt for ptsd |
|
Seeing consciousness through the lens of memory |
|
Thoughtful feelings |
|
My Word Thoughtful feelings |
|
Higher-order memory schema and consciousness experience |
|
A little history goes a long way toward understanding why we study consciousness the way we do today |
|
How does the non-conscious become conscious? |
|
A brainstem-central amygdala circuit underlies defensive responses to learned threats |
|
Cell-type-specific drug-inducible protein synthesis inhibition demonstrates that memory consolidation requires rapid neuronal translation |
|
Motivational factors underlying aversive Pavlovian-instrumental transfer |
|
The bed nucleus of the stria terminalis and functionally linked neurocircuitry modulate emotion processing and HPA axis dysfunction in posttraumatic stress disorder |
|
Understanding the Higher-Order Approach to Consciousness |
|
Development of threat expression following infant maltreatment: Infant and adult enhancement but adolescent attenuation |
|
Axon TRAP reveals learning-associated alterations in cortical axonal mRNAs in the lateral amgydala |
|
Chemogenetic Inhibition Reveals That Processing Relative But Not Absolute Threat Requires Basal Amygdala |
|
Activation of a novel p70 S6 kinase 1-dependent intracellular cascade in the basolateral nucleus of the amygdala is required for the acquisition of extinction memory |
|
beta-Adrenergic enhancement of neuronal excitability in the lateral amygdala is developmentally gated |
|
Surviving threats: Neural circuit and computational implications of a new taxonomy of defensive behaviour |
|
The subjective experience of emotion: a fearful view |
|
Editorial overview: Survival behaviors and circuits |
|
A principled method to identify individual differences and behavioral shifts in signaled active avoidance |
|
Pavlovian extinction and recovery effects in aversive pavlovian to instrumental transfer |
|
Characterization of the amplificatory effect of norepinephrine in the acquisition of Pavlovian threat associations |
|
Noradrenergic regulation of central amygdala in aversive pavlovian-to-instrumental transfer |
|
Active avoidance: Neural mechanisms and attenuation of pavlovian conditioned responding |
|
A higher-order theory of emotional consciousness |
|
beta-Adrenergic Receptors Regulate the Acquisition and Consolidation Phases of Aversive Memory Formation Through Distinct, Temporally Regulated Signaling Pathways |
|
Updating of aversive memories after temporal error detection is differentially modulated by mTOR across development |
|
Accumulation of polyribosomes in dendritic spine heads, but not bases and necks, during memory consolidation depends on cap-dependent translation initiation |
|
Elevating the role of subjective experience in the clinic: Response to fanselow and pennington |
|
Updating temporal expectancy of an aversive event engages striatal plasticity under amygdala control |
|
The birth, death and resurrection of avoidance: A reconceptualization of a troubled paradigm |
|
Primary auditory cortex regulates threat memory specificity |
|
Evaluation of ambiguous associations in the amygdala by learning the structure of the environment |
|
The neural foundations of reaction and action in aversive motivation |
|
Using neuroscience to help understand fear and anxiety: A two-system framework |
|
Beyond the amygdala: Linguistic threat modulates peri-sylvian semantic access cortices |
|
Modulation of instrumental responding by a conditioned threat stimulus requires lateral and central amygdala |
|
Feelings: What are they & how does the brain make them? |
|
Active avoidance requires a serial basal amygdala to nucleus accumbens shell circuit |
|
Outcome in place of an expected threat diminishes recovery of defensive responses |
|
Heterogeneity in signaled active avoidance learning: Substantive and methodological relevance of diversity in instrumental defensive responses to threat cues |
|
Medial amygdala lesions selectively block aversive pavlovian-instrumental transfer in rats |
|
Synapses lacking astrocyte appear in the amygdala during consolidation of pavlovian threat conditioning |
|
Lesions of lateral or central amygdala abolish aversive Pavlovian-to-instrumental transfer in rats |
|
Coming to terms with fear |
|
Hebbian and neuromodulatory mechanisms interact to trigger associative memory formation |
|
Comment: What's basic about the brain mechanisms of emotion? |
|
A Conversation with Joseph LeDoux |
|
Extinction resistant changes in the human auditory association cortex following threat learning |
|
Diverse effects of conditioned threat stimuli on behavior |
|
Q+A Joseph LeDoux |
|
Active vs. reactive threat responding is associated with differential c-Fos expression in specific regions of amygdala and prefrontal cortex |
|
The contribution of the amygdala to aversive and appetitive pavlovian processes |
|
Chronic antidepressant treatment impairs the acquisition of fear extinction |
|
Heterogeneity in threat extinction learning: Substantive and methodological considerations for identifying individual difference in response to stress |
|
Detection of a temporal error triggers reconsolidation of amygdala-dependent memories |
|
Active avoidance learning requires prefrontal suppression of amygdala-mediated defensive reactions |
|
Contrasting effects of pretraining, posttraining, and pretesting infusions of corticotropin-releasing factor into the lateral amygdala: Attenuation of fear memory formation but facilitation of its expression |
|
Extinction during reconsolidation of threat memory diminishes prefrontal cortex involvement |
|
Orexin/hypocretin system modulates amygdala-dependent threat learning through the locus coeruleus |
|
The selectivity of aversive memory reconsolidation and extinction processes depends on the initial encoding of the Pavlovian association |
|
Development of an aversive Pavlovian-to-instrumental transfer task in rat |
|
Basal variability in CREB phosphorylation predicts trait-like differences in amygdala-dependent memory |
|
The mystery of memory: In search of the past |
|
Afterword |
|
Controlling the elements: An optogenetic approach to understanding the neural circuits of fear |
|
The role of the lateral amygdala in the retrieval and maintenance of fear-memories formed by repeated probabilistic reinforcement |
|
Rethinking the Emotional Brain |
|
Stability of presynaptic vesicle pools and changes in synapse morphology in the amygdala following fear learning in adult rats |
|
A neuroscientist's perspective on debates about the nature of emotion |
|
Sensory-specific associations stored in the lateral amygdala allow for selective alteration of fear memories |
|
Regulation of the fear network by mediators of stress: Norepinephrine alters the balance between cortical and subcortical afferent excitation of the lateral amygdala |
|
Differential activity of subgenual cingulate and brainstem in panic disorder and PTSD |
|
Noradrenergic enhancement of reconsolidation in the amygdala impairs extinction of conditioned fear in rats - A possible mechanism for the persistence of traumatic memories in PTSD |
|
Inhibition of the interactions between eukaryotic initiation factors 4E and 4G impairs long-term associative memory consolidation but not reconsolidation |
|
Molecular mechanisms of fear learning and memory |
|
Neural substrates for expectation-modulated fear learning in the amygdala and periaqueductal gray |
|
Optical activation of lateral amygdala pyramidal cells instructs associative fear learning |
|
Sidman Instrumental Avoidance Initially Depends on Lateral and Basal Amygdala and Is Constrained by Central Amygdala-Mediated Pavlovian Processes |
|
Fear and safety learning differentially affect synapse size and dendritic translation in the lateral amygdala |
|
The amygdala encodes specific sensory features of an aversive reinforcer |
|
GABA(C) receptors in the lateral amygdala: a possible novel target for the treatment of fear and anxiety disorders? |
|
The role of amygdala nuclei in the expression of auditory signaled two-way active avoidance in rats |
|
Endogenous GluR1-containing AMPA receptors translocate to asymmetric synapses in the lateral amygdala during the early phase of fear memory formation: An electron microscopic immunocytochemical study |
|
Beta-adrenergic receptors in the lateral nucleus of the amygdala contribute to the acquisition but not the consolidation of auditory fear conditioning |
|
Ultrastructural characterization of noradrenergic axons and beta-adrenergic receptors in the lateral nucleus of the amygdala |
|
Antagonism of lateral amygdala alpha1-adrenergic receptors facilitates fear conditioning and long-term potentiation |
|
Preventing the return of fear in humans using reconsolidation update mechanisms |
|
Brain-derived neurotrophic factor: A dynamic gatekeeper of neural plasticity |
|
Asymmetries in long-term and short-term plasticity at thalamic and cortical inputs to the amygdala in vivo |
|
The influence of stress hormones on fear circuitry |
|
Extinction-Reconsolidation boundaries: Key to persistent attenuation of fear memories |
|
Frontolimbic function and cortisol reactivity in response to emotional stimuli |
|
Manipulating memory |
|
Dissociable roles for the ventromedial prefrontal cortex and amygdala in fear extinction: NR2B contribution |
|
Hebbian reverberations in emotional memory micro circuits |
|
Fear conditioning induces distinct patterns of gene expression in lateral amygdala |
|
Avoiding negative outcomes: Tracking the mechanisms of avoidance learning in humans during fear conditioning |
|
Diurnal cortisol amplitude and fronto-limbic activity in response to stressful stimuli |
|
Neural Circuitry Underlying the Regulation of Conditioned Fear and Its Relation to Extinction |
|
Unconditioned stimulus pathways to the amygdala: Effects of lesions of the posterior intralaminar thalamus on foot-shock-induced c-Fos expression in the subdivisions of the lateral amygdala |
|
Evidence for recovery of fear following immediate extinction in rats and humans |
|
Chapter 3.1 Brain mechanisms of Pavlovian and instrumental aversive conditioning |
|
A recurrent network in the lateral amygdala: A mechanism for coincidence detection |
|
From fear to safety and back: Reversal of fear in the human brain |
|
De novo mRNA synthesis is required for both consolidation and reconsolidation of fear memories in the amygdala |
|
Acquisition of fear extinction requires activation of NR2B-containing NMDA receptors in the lateral amygdala |
|
Brain-derived neurotrophic factor: Linking fear learning to memory consolidation |
|
Synapse-specific reconsolidation of distinct fear memories in the lateral amygdala |
|
Distribution of NMDA and AMPA receptor subunits at thalamo-amygdaloid dendritic spines |
|
Human fear-related motor neurocircuitry |
|
Acute selective serotonin Reuptake inhibitors increase conditioned fear expression: Blockade with a 5-HT2C receptor antagonist |
|
Emotion Enhances Learning via Norepinephrine Regulation of AMPA-Receptor Trafficking |
|
Response Variation following Trauma: A Translational Neuroscience Approach to Understanding PTSD |
|
Escape From Fear: A Detailed Behavioral Analysis of Two Atypical Responses Reinforced by CS Termination |
|
A robust automated method to analyze rodent motion during fear conditioning |
|
Long-term potentiation in the amygdala: A cellular mechanism of fear learning and memory |
|
Brain Mechanisms of Fear Extinction: Historical Perspectives on the Contribution of Prefrontal Cortex |
|
Associative Pavlovian conditioning leads to an increase in spinophilin-immunoreactive dendritic spines in the lateral amygdala |
|
Increased brainstem volume in panic disorder: A voxel-based morphometric study |
|
Myosin light chain kinase regulates synaptic plasticity and fear learning in the lateral amygdala |
|
Fear conditioning drives profilin into amygdala dendritic spines |
|
Directly reactivated, but not indirectly reactivated, memories undergo reconsolidation in the amygdala |
|
Rethinking the fear circuit: The central nucleus of the amygdala is required for the acquisition, consolidation, and expression of pavlovian fear conditioning |
|
In search of one’s self |
|
Fear-related activity in subgenual anterior cingulate differs between men and women |
|
Memory consolidation of Pavlovian fear conditioning requires nitric oxide signaling in the lateral amygdala |
|
Auditory fear conditioning and long-term potentiation in the lateral amygdala require ERK/MAP kinase signaling in the auditory thalamus: A role for presynaptic plasticity in the fear system |
|
The lateral amygdala processes the value of conditioned and unconditioned aversive stimuli |
|
Postsynaptic receptor trafficking underlying a form of associative learning |
|
Differential time courses and specificity of amygdala activity in posttraumatic stress disorder subjects and normal control subjects |
|
Localization of glucocorticoid receptors at postsynaptic membranes in the lateral amygdala |
|
Tracking the fear engram: The lateral amygdala is an essential locus of fear memory storage |
|
Contributions of the amygdala to emotion processing: From animal models to human behavior |
|
AMPA receptor trafficking and GluR1 [2] (multiple letters) |
|
Fear learning transiently impairs hippocampal cell proliferation |
|
Activation of extracellular signal-regulated kinase-mitogen-activated protein kinase cascade in the amygdala is required for memory reconsolidation of auditory fear conditioning |
|
Molecular mechanisms underlying emotional learning and memory in the lateral amygdala |
|
Extinction learning in humans: Role of the amygdala and vmPFC |
|
Lesions in the bed nucleus of the stria terminalis disrupt corticosterone and freezing responses elicited by a contextual but not by a specific cue-conditioned fear stimulus |
|
Emotional perseveration: An update on prefrontal-amygdala interactions in fear extinction |
|
Putting fear in its place: Remapping of hippocampal place cells during fear conditioning |
|
New vistas on amygdala networks in conditioned fear |
|
The selective serotonin reuptake inhibitor citalopram increases fear after acute treatment but reduces fear with chronic treatment: A comparison with tianeptine |
|
Unconditioned stimulus pathways to the amygdala: Effects of posterior thalamic and cortical lesions on fear conditioning |
|
Pavlovian fear conditioning regulates Thr(286) autophosphorylation of Ca2+/calmodulin-dependent protein kinase II at lateral amygdala synapses |
|
Fear and the brain |
|
Disruption of reconsolidation but not consolidation of auditory fear conditioning by noradrenergic blockade in the amygdala |
|
Heterosynaptic long-term potentiation of inhibitory interneurons in the lateral amygdala |
|
Structural plasticity and memory |
|
Long-term potentiation in freely moving rats reveals asymmetries in thalamic and cortical inputs to the lateral amygdala |
|
Rodent doxapram model of panic: Behavioral effects and c-Fos immunoreactivity in the amygdala |
|
Hippocampal place cells acquire location-specific responses to the conditioned stimulus during auditory fear conditioning |
|
Ventral medial prefrontal cortex and emotional perseveration: The memory for prior extinction training |
|
The emotional brain, fear, and the amygdala |
|
The Group I Metabotropic Glutamate Receptor mGluR5 Is Required for Fear Memory Formation and Long-Term Potentiation in the Lateral Amygdala |
|
NMDA Receptors and L-Type Voltage-Gated Calcium Channels Contribute to Long-Term Potentiation and Different Components of Fear Memory Formation in the Lateral Amygdala |
|
Redefining the tonotopic core of rat auditory cortex: Physiological evidence for a posterior field |
|
Fear memory formation involves p190 RhoGAP and ROCK proteins through a GRB2-mediated complex |
|
Cellular and systems reconsolidation in the hippocampus |
|
Parallels between cerebellum- and amygdala-dependent conditioning |
|
A-kinase anchoring proteins in amygdala are involved in auditory fear memory |
|
A gradient of plasticity in the amygdala revealed by cortical and subcortical stimulation, in vivo |
|
Intra-amygdala blockade of the NR2B subunit of the NMDA receptor disrupts the acquisition but not the expression of fear conditioning |
|
Aversive learning in patients with unilateral lesions of the amygdala and hippocampus |
|
Memory consolidation of Pavlovian fear conditioning: A cellular and molecular perspective |
|
Fear conditioning and LTP in the lateral amygdala are sensitive to the same stimulus contingencies |
|
Damage to the lateral and central, but not other, amygdaloid nuclei prevents the acquisition of auditory fear conditioning |
|
A call to action: Overcoming anxiety through active coping |
|
Synaptic plasticity in the lateral amygdala: A cellular hypothesis of fear conditioning |
|
Two different lateral amygdala cell populations contribute to the initiation and storage of memory |
|
The brain decade in debate: III. Neurobiology of emotion |
|
Cells in the posterior thalamus project to both amygdala and temporal cortex: A quantitative retrograde double-labeling study in the rat |
|
The amygdala modulates memory consolidation of fear-motivated inhibitory avoidance learning but not classical fear conditioning |
|
Fear memories require protein synthesis in the amygdala for reconsolidation after retrieval |
|
Emotion circuits in the brain |
|
Activation of ERK/MAP kinase in the amygdala is required for memory consolidation of Pavlovian fear conditioning |
|
Different lateral amygdala outputs mediate reactions and actions elicited by a fear-arousing stimulus |
|
Reply – reconsolidation: The labile nature of consolidation theory |
|
The induction of c-Fos in the NTS after taste aversion learning is not correlated with measures of conditioned fear |
|
Memory consolidation of auditory pavlovian fear conditioning requires protein synthesis and protein kinase A in the amygdala. |
|
Opiate receptor avidity in the thalamus is sexually dimorphic in the elderly |
|
Organization of projections to the lateral amygdala from auditory and visual areas of the thalamus in the rat |
|
Afferents from rat temporal cortex synapse on lateral amygdala neurons that express NMDA and AMPA receptors |
|
Memory consolidation for contextual and auditory fear conditioning is dependent on protein synthesis, PKA, and MAP kinase |
|
L-type voltage-gated calcium channels mediate NMDA-independent associative long-term potentiation at thalamic input synapses to the amygdala |
|
Lesions of periaqueductal gray dissociate-conditioned freezing from conditioned suppression behavior in rats |
|
GABAergic antagonists block the inhibitory effects of serotonin in the lateral amygdala: a mechanism for modulation of sensory inputs related to fear conditioning. |
|
Functional inactivation of the amygdala before but not after auditory fear conditioning prevents memory formation. |
|
Contribution of ventrolateral prefrontal cortex to the acquisition and extinction of conditioned fear in rats |
|
Repeated restraint stress facilitates fear conditioning independently of causing hippocampal CA3 dendritic atrophy |
|
Psychoanalytic theory: Clues from the brain |
|
Inhibition of the mesoamygdala dopaminergic pathway impairs the retrieval of conditioned fear associations |
|
The dopaminergic modulation of fear: Quinpirole impairs the recall of emotional memories in rats |
|
Distinct populations of NMDA receptors at subcortical and cortical inputs to principal cells of the lateral amygdala |
|
Differential effects of amygdala lesions on early and late plastic components of auditory cortex spike trains during fear conditioning |
|
Fear and the brain: Where have we been, and where are we going? |
|
Nature vs. nurture: The pendulum still swings with plenty of momentum |
|
Serotonin modulation of sensory inputs to the lateral amygdala: Dependency on corticosterone |
|
Human amygdala activation during conditioned fear acquisition and extinction: A mixed-trial fMRI study |
|
The amygdala: Myth or monolith? [1] (multiple letters) |
|
Functional inactivation of the lateral and basal nuclei of the amygdala by muscimol infusion prevents fear conditioning to an explicit conditioned stimulus and to contextual stimuli |
|
AMPA receptor facilitation accelerates fear learning without altering the level of conditioned fear acquired |
|
Computational modeling of emotion: Explorations through the anatomy and physiology of fear conditioning |
|
Stimulus generalization of fear responses: Effects of auditory cortex lesions in a computational model and in rats |
|
Lateral nucleus of the rat amygdala is reciprocally connected with basal and accessory basal nuclei: A light and electron microscopic study |
|
Fear conditioning induces associative long-term potentiation in the amygdala |
|
Organization of intra-amygdaloid circuitries in the rat: An emerging framework for understanding functions of the amygdala |
|
Is it time to invoke multiple fear learning systems in the amygdala? |
|
NMDA and AMPA receptors in the lateral nucleus of the amygdala are postsynaptic to auditory thalamic afferents |
|
Fear conditioning enhances different temporal components of tone-evoked spike trains in auditory cortex and lateral amygdala |
|
Hippocampal-dependent learning and experience-dependent activation of the hippocampus are preferentially disrupted by ethanol |
|
Topographic projections from the periamygdaloid cortex to select subregions of the lateral nucleus of the amygdala in the rat |
|
Interamygdaloid projections of the basal and accessory basal nuclei of the rat amygdaloid complex |
|
Intrinsic connections of the rat amygdaloid complex: Projections originating in the accessory basal nucleus |
|
Partial disruption of fear conditioning in rats with unilateral amygdala damage: Correspondence with unilateral temporal lobectomy in humans |
|
GABA(A) and GABA(B) receptors differentially regulate synaptic transmission in the auditory thalamo-amygdala pathway: An in vivo microiontophoretic study and a model |
|
Emotion: Systems, cells, synaptic plasticity |
|
Convergent but temporally separated inputs to lateral amygdala neurons from the auditory thalamus and auditory cortex use different postsynaptic receptors: In vivo intracellular and extracellular recordings in fear conditioning pathways |
|
Emotional networks and motor control: A fearful view |
|
Disruptive Effects of Posttraining Perirhinal Cortex Lesions on Conditioned Fear: Contributions of Contextual Cues |
|
Differential Contribution of Dorsal and Ventral Medial Prefrontal Cortex to the Acquisition and Extinction of Conditioned Fear in Rats |
|
NMDA and non-NMDA receptors contribute to synaptic transmission between the medial geniculate body and the lateral nucleus of the amygdala |
|
Septal Lesions Potentiate Freezing Behavior to Contextual but Not to Phasic Conditioned Stimuli in Rats |
|
Impaired fear conditioning following unilateral temporal lobectomy in humans |
|
LTP is accompanied by commensurate enhancement of auditory-evoked responses in a fear conditioning circuit |
|
Intrinsic connections of the rat amygdaloid complex: Projections originating in the basal nucleus |
|
Brain mechanisms in human classical conditioning: A PET blood flow study |
|
Fear conditioning enhances short-latency auditory responses of lateral amygdala neurons: Parallel recordings in the freely behaving rat |
|
Lesions of the fornix but not the entorhinal or perirhinal cortex interfere with contextual fear conditioning |
|
An Anatomically Constrained Neural Network Model of Fear Conditioning |
|
Intrinsic connections of the rat amygdaloid complex: Projections originating in the lateral nucleus |
|
Emotion: Clues from the brain |
|
Differential localization of NMDA and AMPA receptor subunits in the lateral and basal nuclei of the amygdala: A light and electron microscopic study |
|
Lesions of the dorsal hippocampal formation interfere with background but not foreground contextual fear conditioning |
|
Response properties of single units in areas of rat auditory thalamus that project to the amygdala - II. Cells receiving convergent auditory and somatosensory inputs and cells antidromically activated by amygdala stimulation |
|
Response properties of single units in areas of rat auditory thalamus that project to the amygdala - I. Acoustic discharge patterns and frequency receptive fields |
|
The amygdala: Contributions to fear and stress |
|
Emotion, memory and the brain. |
|
Somatosensory and Auditory Convergence in the Lateral Nucleus of the Amygdala |
|
Emotional memory systems in the brain |
|
Information cascade from primary auditory cortex to the amygdala: Corticocortical and corticoamygdaloid projections of temporal cortex in the rat |
|
Extinction of emotional learning: Contribution of medial prefrontal cortex |
|
Single-Unit Activity in the Lateral Nucleus of the Amygdala and Overlying Areas of the Striatum in Freely Behaving Rats: Rates, Discharge Patterns, and Responses to Acoustic Stimuli |
|
Emotional Memory: In Search of Systems and Synapses |
|
Organization of rodent auditory cortex: anterograde transport of pha-l from mgv to temporal neocortex |
|
Cognition versus emotion, again-this time in the brain: A response to parrott and schulkin |
|
Bilateral destruction of neocortical and perirhinal projection targets of the acoustic thalamus does not disrupt auditory fear conditioning |
|
Differential Contribution of Amygdala and Hippocampus to Cued and Contextual Fear Conditioning |
|
Glutamate immunoreactive terminals in the lateral amygdaloid nucleus: a possible substrate for emotional memory |
|
Sensory tuning beyond the sensory system: An initial analysis of auditory response properties of neurons in the lateral amygdaloid nucleus and overlying areas of the striatum |
|
Equipotentiality of thalamo-amygdala and thalamo-cortico-amygdala circuits in auditory fear conditioning |
|
Brain mechanisms of emotion and emotional learning |
|
Projections from the lateral nucleus to the basal nucleus of the amygdala: A light and electron microscopic PHA?L study in the rat |
|
Ultrastructure and synaptic associations of auditory thalamo-amygdala projections in the rat |
|
Neurons of the acoustic thalamus that project to the amygdala contain glutamate |
|
Overlapping projections to the amygdala and striatum from auditory processing areas of the thalamus and cortex |
|
The lateral amygdaloid nucleus: Sensory interface of the amygdala in fear conditioning |
|
Synaptic plasticity in fear conditioning circuits: Induction of LTP in the lateral nucleus of the amygdala by stimulation of the medial geniculate body |
|
Topographic organization of neurons in the acoustic thalamus that project to the amygdala |
|
Unit responses evoked in the amygdala and striatum by electrical stimulation of the medial geniculate body |
|
Cognitive—emotional interactions in the brain |
|
Indelibility of subcortical emotional memories |
|
Dissociation of Associative and Nonassociative Concommitants of Classical Fear Conditioning in the Freely Behaving Rat |
|
Different projections of the central amygdaloid nucleus mediate autonomic and behavioral correlates of conditioned fear |
|
Cardiovascular responses elicited by stimulation of neurons in the central amygdaloid nucleus in awake but not anesthetized rats resemble conditioned emotional responses |
|
Topographic organization of convergent projections to the thalamus from the inferior colliculus and spinal cord in the rat |
|
Some central neural mechanisms governing resting and behaviorally coupled control of blood pressure |
|
Intrinsic neurons in the amygdaloid field projected to by the medial geniculate body mediate emotional responses conditioned to acoustic stimuli |
|
Disruption of auditory but not visual learning by destruction of intrinsic neurons in the rat medial geniculate body |
|
Destruction of intrinsic neurons in the lateral hypothalamus disrupts the classical conditioning of autonomic but not behavioral emotional responses in the rat |
|
Interruption of projections from the medial geniculate body to an archi-neostriatal field disrupts the classical conditioning of emotional responses to acoustic stimuli |
|
Sympathetic nervous system and control of blood pressure during natural behaviour |
|
Projections to the subcortical forebrain from anatomically defined regions of the medial geniculate body in the rat |
|
Auditory Emotional Memories: Establishment by Projections from the Medial Geniculate Nucleus to the Posterior Neostriatum and/or Dorsal Amygdala |
|
Strain difference in fear between spontaneously hypertensive and normotensive rats is mediated by adrenal cortical hormones |
|
Constraints on the processing of indirect speech acts: Evidence from aphasiology |
|
Subcortical efferent projections of the medial geniculate nucleus mediate emotional responses conditioned to acoustic stimuli |
|
Strain differences in fear between spontaneously hypertensive and normotensive rats |
|
Alpha-methylDOPA dissociates hypertension, cardiovascular reactivity and emotional behavior in spontaneously hypertensive rats |
|
Sympathetic nerves and adrenal medulla: contributions to cardiovascular-conditioned emotional responses in spontaneously hypertensive rats |
|
Inferential processing of context: Studies of cognitively impaired subjects |
|
Local cerebral blood flow increases during auditory and emotional processing in the conscious rat |
|
Arterial pressure and heart rate changes during natural sleep in rat |
|
Neuroevolutionary mechanisms of cerebral asymmetry in man |
|
Opiate dependent hypoemotionality in spontaneously hypertensive rats |
|
Behaviorally selective cardiovascular hyperreactivity in spontaneously hypertensive rats: Evidence for hypoemotionality and enhanced appetitive motivation |
|
Hierarchic organization of blood pressure responses during the expression of natural behaviors in rat: Mediation by sympathetic nerves |
|
The brain and the split brain: A duel with duality as a model of mind |
|
A hierarchical organization of blood pressure during natural behaviour in rat and the effects of central catecholamine neurons thereon. |
|
Left Hemisphere Visual Processes in a Case of Right Hemisphere Symptomatology: Implications for Theories of Cerebral Lateralization |
|
Plasticity in speech organization following commissurotomy |
|
Information processing of visual stimuli in an 'extinguished' field [19] |
|
Spatially oriented movements in the absence of proprioception |
|
Block Design Performance Following Callosal Sectioning: Observations on Functional Recovery |
|
The anterior commissure in man: Functional variation in a multisensory system |
|
Cognition and commissurotomy |
|
Manipulo-spatial aspects of cerebral lateralization: Clues to the origin of lateralization |
|
Language, praxis, and the right hemisphere: Clues to some mechanisms of consciousness |
|
A divided mind: Observations on the conscious properties of the separated hemispheres |
|
Stereotaxic mapping of brainstem areas critical for the expression of the rodent’s preference for the dark |
|
A stereotaxic map of brainstem areas critical for locomotor responses in a novel environment |
|
Brightness discrimination loss after lesions of the corpus striatum in the white rat |
|
Common brain regions essential for the expression of learned and instinctive visual habits in the albino rat |
|