Reward Timing in the Primary Visual Cortex

We discovered that when adult rats experience an association between visual stimuli and subsequent rewards, the responses of a substantial fraction of neurons in the primary visual cortex evolve from those that relate solely to the physical attributes of the stimuli to those that accurately predict the timing of reward. In addition to revealing a remarkable type of response plasticity in adult V1, these data demonstrate that reward-timing activity—a "higher" brain function—can occur very early in sensory-processing paths. These findings challenge the traditional interpretation of activity in the primary visual cortex.

Reward Timing in the Primary Visual Cortex
Marshall G. Shuler and Mark F. Bear (17 March 2006)
Science 311 (5767), 1606. [DOI: 10.1126/science.1123513]

http://www.sciencemag.org/cgi/citmgr?gca=sci;311/5767/1606

Pathways for emotions and memory II. Afferent input to the anterior thalamic nuclei from PF, temporal, hypothalamic areas and the BG in the rhesus ...

The anterior thalamic nuclei are a key link in pathways associated with emotions and memory. In the preceding study we found that one of the anterior nuclei, the anterior medial (AM), had particularly robust connections with specific medial prefrontal and orbitofrontal cortices and moderate connections with frontal polar cortices. The goal of this study was to use a direct approach to determine the sources of projections to the AM nucleus from all prefrontal cortices, as well as from temporal structures and the hypothalamic mammillary body, known for their role in distinct aspects of memory and emotion. We addressed this issue with targeted injections of retrograde fluorescent tracers in the AM nucleus to determine its sources of input. Projection neurons directed to the AM nucleus were found in the deep layers of most prefrontal cortices (layers V and VI), and were most densely distributed in medial areas 24, 32 and 25, orbitofrontal areas 13 and 25, and lateral areas 10 and 46. Most projection neurons were found in layer VI, though in medial prefrontal cortices and dorsal area 9 about a third were found in layer V, a significantly higher proportion than in lateral and orbitofrontal cortices. In the temporal lobe, projection neurons originated mostly from the hippocampal formation (ammonic field CA3 and subicular complex), and the amygdala (basolateral, lateral, and basomedial nuclei). In the hypothalamus, a significant number of neurons in the ipsilateral medial mammillary body projected to the AM nucleus, some of which were positive for calbindin (CB) or parvalbumin (PV), markers expressed, respectively, in “diffuse” and “specific” pathways in the thalamus [Adv. Neurol. 77 (1998a) 49]. As recipient of diverse signals, the AM nucleus is in a key position to link pathways associated with emotions, and may be an important interface for systems associated with retrieval of information from long-term memory in the process of solving problems within working memory. Finally, the internal segment of the globus pallidus (GPi) issued projections to AM, suggesting direct linkage with executive systems through the basal ganglia. The diverse connections of the AM nucleus may help explain the varied deficits in memory and emotions seen in neurodegenerative and psychiatric diseases affecting the anterior thalamic nuclei.



Fig. 12. Summary of the connections of the anterior medial nucleus with prefrontal and temporal structures, the hypothalamic mammillary body and the internal segment of the globus pallidus. The bi-directional arrows for connections of prefrontal cortices with AM summarize findings obtained from this and the preceding study, and are shown on the lateral (top, left), medial (top, right) and basal surfaces (bottom) of the cerebral hemisphere. The projections from temporal cortex, the amygdala, the hippocampus, the hypothalamic mammillary body, and the basal ganglia to AM are according to the findings from this study. Density variations of prefrontal projections to AM are depicted in pseudocolor denoting dense (red) to light (blue) projections, as reconstructed from serial coronal sections (this paper). cal outputs of the AM nucleus, the cingulate cortex (Gaffan and Harrison, 1989; Gaffan, 1993, 2002; Parker and Gaffan, 1997a,b; Gaffan et al., 2001). In humans, infarction of the AM nucleus dramatically impaired episodic and recognition memory resulting in anterograde amnesia (Parkin et al., 1994; Ghika-Schmid and Bogousslavsky, 2000; Nolan et al.,

Pathways for emotions and memory II. Afferent input to the anterior thalamic nuclei from prefrontal, temporal, hypothalamic areas and the basal ganglia in the rhesus monkey.
D. Xiao b, H. Barbas.
Thalamus & Related Systems 2 (2002) 33–48.

http://www.bu.edu/neural/Final/Publications/2002/Thalamus%20&%20Related%20Systems,%20Volume%202,%20Issue%201,%20December%202002,%20Pages%2033-48.PDF

Cortical Structure Predicts the Pattern of Corticocortical Connections

Cortical areas are linked through pathways which originate and terminate in specific layers. The factors underlying which layers are involved in specific connections are not well understood. Here we tested whether cortical structure can predict the pattern as well as the relative distribution of projection neurons and axonal terminals in cortical layers, studied with retrograde and anterograde tracers. We used the prefrontal cortices in the rhesus monkey as a model system because their laminar organization varies systematically, ranging from areas that have only three identifiable layers, to those that have six layers. We rated each prefrontal area based on the number and definition of its cortical layers (level 1, lowest; level 5, highest). The structural model accurately predicted the laminar pattern of connections in ~80% of the cases. Thus, projection neurons from a higher-level cortex originated mostly in the upper layers and their axons terminated predominantly in the deep layers (4–6) of a lower-level cortex. Conversely, most projection neurons from a lower-level area originated in the deep layers and their axons terminated predominantly in the upper layers (1–3) of a higher-level area. In addition, the structural model accurately predicted that the proportion of projection neurons or axonal terminals in the upper to the deep layers would vary as a function of the number of levels between the connected cortices. The power of this structural model lies in its potential to predict patterns of connections in the human cortex, where invasive procedures are precluded.



Figure 11. Summary of the pattern of connections predicted by the structural model. (A) Connections between cortices with large differences in laminar definition show a readily distinguishable pattern. (Top) Projection neurons originate predominantly in the deep layers of cortices with low laminar definition and their axons terminate predominantly in the upper layers of cortices with high laminar definition. (Bottom) The opposite pattern is seen for the reciprocal connections. (B) A less extreme version of the above pattern is predicted in the interconnections of cortices with moderate differences in laminar definition. (Top) Most neurons (though fewer than in A) originate in the deep layers of the cortex with comparatively lower laminar definition, and their axons terminate primarily in the upper layers of the cortex with comparatively higher laminar definition. (Bottom) The opposite pattern is predicted for the reciprocal connections.

Cortical Structure Predicts the Pattern of Corticocortical Connections.
H. Barbas and N. Rempel-Clower.
Cerebral Cortex Oct/Nov 1997;7:635–646; 1047–3211/97/

http://www.bu.edu/neural/Final/Publications/1997/Cereb%20Cortex.%201997%20Oct-Nov.%207(7)635-46.pdf

Circuits through prefrontal cortex, basal ganglia, and ventral anterior nucleus map pathways beyond motor control

The ventral anterior (VA) nucleus of the thalamus is connected with prefrontal and premotor cortices and with the basal ganglia. Although classically associated with motor functions, recent evidence implicates the basal ganglia in cognition and emotion as well. Here, we used two complementary approaches to investigate whether the VA is a key link for pathways underlying cognitive and emotional processes through prefrontal cortices and the basal ganglia. After application of bidirectional tracers in functionally distinct lateral, medial, and orbitofrontal cortices, we found that projection neurons were embedded in much larger patches of axonal terminations found in the magnocellular part of VA (VAmc), and in the principal part of VA. Connections from medial prefrontal cortices occupied the dorsomedial and ventromedial VA, and orbitofrontal connections were found in ventrolateral VAmc. Moreover, about half of all projection neurons in orbitofrontal areas directed to the VA or VAmc were positive for calbindin but not parvalbumin, even though comparable populations of neurons were positive for each marker in the VA.We then applied tracers in VA and investigated simultaneously projections from all prefrontal areas, the internal segment of the globus pallidus (GPi), the substantia nigra reticulata (SNr), and the thalamic reticular nucleus. Projection neurons were most densely distributed in anterior cingulate areas 24 and 32, and dorsolateral areas 9 and 8, innervating the same VA sites that received projections from a large part of GPi and dorsal SNr. Nearly as many projection neurons originated from cortical layer V as from layer VI. There is evidence that cortical layer VI neurons innervate thalamic neurons that project focally to the middle cortical layers, whereas layer V neurons synapse with thalamic neurons projecting widely to cortical layer I. Projections from layer V to the VA may facilitate cortical recruitment for executive functions within a cognitive context through lateral prefrontal areas, and autonomic responses within an emotional context through anterior cingulate areas.

Circuits through prefrontal cortex, basal ganglia, and ventral anterior nucleus map pathways beyond motor control.
Danqing Xiao, Helen Barbas.
Thalamus & Related Systems 2 (2004) 325–343.

http://www.bu.edu/neural/Final/Publications/2004/Thalamus%20&%20Related%20Systems,%20Volume%202,%20Issue%204,%20July%202004,%20Pages%20325-343.pdf

Does gender play a role in functional asymmetry of ventromedial prefrontal cortex?

We found previously in a lesion study that the right-sided sector of the ventromedial prefrontal cortices (VMPCs) was critical for social/emotional functioning and decision-making, whereas the left side appeared to be less important. It so happened that all but one of the subjects in that study were men, and the one woman did not fit the pattern very well. This prompted a follow-up investigation, in which we explored the following question: Does gender play a role in the development of defects in social conduct, emotional functioning and decision-making, following unilateral VMPC damage? We culled from our Patient Registry same-sex pairs of men or women patients who had comparable unilateral VMPC damage in either the left or right hemisphere. Two male pairs and one female pair were formed, and we included two additional women with unilateral right VMPC damage (8 patients in all). The domains of measurement covered social conduct, emotional processing and personality, and decision-making. We found a systematic effect of gender on the pattern of left–right asymmetry in VMPC. In men, there were severe defects following unilateral right VMPC damage, but not following left-sided damage. In women, there were defects following unilateral left VMPC damage; following right-sided damage, however, defects were mild or absent. The findings suggest that men and women may use different strategies to solve similar problems—e.g. men may use a more holistic, gestalt-type strategy, and women may use a more analytic, verbally-mediated strategy. Such differences could reflect asymmetric, gender-related differences in the neurobiology of left and right VMPC sectors.

Daniel Tranel , Hanna Damasio , Natalie L. Denburg , and Antoine Bechara
Does gender play a role in functional asymmetry of ventromedial prefrontal cortex?
Brain Advance Access published on December 1, 2005, DOI 10.1093/brain/awh643.
Brain 128: 2872-2881.

http://brain.oxfordjournals.org/cgi/content/full/128/12/2872

Common inhibitory mechanism in human inferior prefrontal cortex revealed by event-related functional MRI

Inhibition of an ongoing reaction tendency for adaptation to changing environments is a major function of the human prefrontal cortex. This function has been investigated frequently using the go/no-go task and set-shifting tasks such as the Wisconsin Card Sorting Test (WCST). Studies in humans and monkeys suggest the involvement of the dorsolateral prefrontal cortex in the two task paradigms. However, it remains unknown where in the dorsolateral prefrontal cortex this function is localized, whether a common inhibitory mechanism is used in these task paradigms and how this inhibitory function acts on two different targets, i.e. the go response in the go/no-go task and the cognitive set in the WCST. In the go/no-go task of this study, subjects were instructed to either respond (go trial) or not respond (no-go trial), depending on the cue stimulus presented. The signals of functional MRI (fMRI) related to the inhibitory function should be transient by nature. Thus, we used the temporal resolution of fMRI (event-related fMRI) by which transient signals in go and no-go trials can be analysed separately and compared with each other. We found a focus that showed transient no-go dominant activity in the posterior part of the inferior frontal sulcus in the right hemisphere. This was true irrespective of whether the subjects used their right or left hands. These results suggest that the transient activation in the right inferior prefrontal area is related to the neural mechanism underlying the response inhibition function. Furthermore, this area was found to be overlapped spatially with the area that was activated transiently during cognitive set shifting in the WCST. The transient signals in the go/no-go task peaked 5 s after the transient expression of the inhibitory function, and the transient signals in the WCST peaked 7 s after the transient expression, reflecting different durations of neuronal activity in the two inhibitory task paradigms. These results imply that the right inferior prefrontal area is commonly involved in the inhibition of different targets, i.e. the go response during performance of the go/no-go task and the cognitive set during performance of the WCST.

Seiki Konishi , Kyoichi Nakajima , Idai Uchida , Hideyuki Kikyo , Masashi Kameyama , and Yasushi Miyashita
Common inhibitory mechanism in human inferior prefrontal cortex revealed by event-related functional MRI
Bain 122: 981-991.

http://brain.oxfordjournals.org/cgi/content/full/122/5/981

Right ventromedial prefrontal lesions result in paradoxical cardiovascular activation with emotional stimuli

Ventromedial prefrontal cortex (VMPFC) lesions can alter emotional and autonomic responses. In animals, VMPFC activation results in cardiovascular sympathetic inhibition. In humans, VMPFC modulates emotional processing and autonomic response to arousal (e.g. accompanying decision-making). The specific role of the left or right VMPFC in mediating somatic responses to non-arousing, daily-life pleasant or unpleasant stimuli is unclear. To further evaluate VMPFC interaction with autonomic processing of non-stressful emotional stimuli and assess the effects of stimulus valence, we studied patients with unilateral VMPFC lesions and assessed autonomic modulation at rest and during physical challenge, and heart rate (HR) and blood pressure (BP) responses to non-stressful neutral, pleasant and unpleasant visual stimulation (VES) via emotionally laden slides. In 6 patients (54.0 ± 7.2 years) with left-sided VMPFC lesions (VMPFC-L), 7 patients (43.3 ± 11.6 years) with right-sided VMPFC lesions (VMPFC-R) and 13 healthy volunteers (44.7 ± 11.6 years), we monitored HR as R–R interval (RRI), BP, respiration, end-tidal carbon dioxide levels, and oxygen saturation at rest, during autonomic challenge by metronomic breathing, a Valsalva manoeuvre and active standing, and in response to non-stressful pleasant, unpleasant and neutral VES. Pleasantness versus unpleasantness of slides was rated on a 7-point Likert scale. At rest, during physical autonomic challenge, and during neutral VES, parameters did not differ between the patient groups and volunteers. During VES, Likert scores also were similar across the three groups. During pleasant and unpleasant VES, HR decreased (i.e. RRI increased) significantly whereas BP remained unchanged in volunteers. In VMPFC-L patients, HR decrease was insignificant with pleasant and unpleasant VES. BP slightly increased (P = 0.06) with pleasant VES but was stable with unpleasant VES. In contrast, VMPFC-R patients had significant increases in HR and BP during pleasant and not quite significant HR increases (P = 0.06) with only slight BP increase during unpleasant VES. Other biosignals remained unchanged during VES in all groups. Our results show that VMPFC has no major influence on autonomic modulation at rest and during non-emotional, physical stimulation. The paradoxical HR and BP responses in VMPFC-R patients suggest hemispheric specialization for VMPFC interaction with predominant parasympathetic activation by the left, but sympathetic inhibition by the right VMPFC. Valence of non-stressful stimuli has a limited effect with more prominent left VMPFC modulation of pleasant and more right VMPFC modulation of unpleasant stimuli. The paradoxical sympathetic disinhibition in VMPFC-R patients may increase their risk of sympathetic hyperexcitability with negative consequences such as anxiety, hypertension or cardiac arrhythmias.

Max J. Hilz , Orrin Devinsky , Hanna Szczepanska , Joan C. Borod , Harald Marthol , and Marcin Tutaj
Right ventromedial prefrontal lesions result in paradoxical cardiovascular activation with emotional stimuli
Brain Advance Access published on December 1, 2006, DOI 10.1093/brain/awl299.
Brain 129: 3343-3355.

http://brain.oxfordjournals.org/cgi/content/full/129/12/3343

Prefrontal regions involved in keeping information in and out of mind

Goal-directed behaviour depends on keeping relevant information in mind (working memory) and irrelevant information out of mind (behavioural inhibition or interference resolution). Prefrontal cortex is essential for working memory and for interference resolution, but it is unknown whether these two mental abilities are mediated by common or distinct prefrontal regions. To address this question, functional MRI was used to identify brain regions activated by separate manipulations of working memory load and interference within a single task (the Sternberg item recognition paradigm). Both load and interference manipulations were associated with performance decrements. Subjects were unaware of the interference manipulation. There was a high degree of overlap between the regions activated by load and interference, which included bilateral ventrolateral and dorsolateral prefrontal cortex, anterior insula, anterior cingulate and parietal cortex. Critically, no region was activated exclusively by interference. Several regions within this common network exhibited a brain–behaviour correlation across subjects for the load or interference manipulation. Activation within the right middle frontal gyrus and left inferior frontal gyrus was correlated with the ability to resolve interference efficiently, but not the ability to manage an increased working memory load efficiently. Conversely, activation of the anterior cingulate was correlated with load susceptibility, but was not correlated with interference susceptibility. These findings suggest that, within the circuitry engaged by this task, some regions are more critically involved in the resolution of interference whereas others are more involved in the resolution of an increase in load. The anterior cingulate was engaged to a greater extent by the load than interference manipulation, suggesting that this region, which is thought to be involved in detecting the need for greater allocation of attentional resources, may be particularly implicated during awareness of the need for cognitive control. In the present study, interference resolution did not involve recruitment of additional inhibitory circuitry, but was instead mediated by a subset of the neural system supporting working memory.



Fig. 3 Rendering of group-averaged brain activations. (A) Load-related activations identified by the contrast Load 4 > Load 1 (P <>B) Load-related activations identified by the contrast Load 6 > Load 4 (P <>P <>C) Interference-related activations identified by the contrast Load 4 High Recency > Load 4 (P <>P < 0.05). Liberal thresholds were chosen to illustrate the overlap between regions activated by each contrast. The level of significance of activation at each voxel (T value) is colour-coded according to the scale on the right of each figure. Silvia A. Bunge , Kevin N. Ochsner , John E. Desmond , Gary H. Glover , and John D. E. Gabrieli Prefrontal regions involved in keeping information in and out of mind Brain 124: 2074-2086. Silvia A. Bunge , Kevin N. Ochsner , John E. Desmond , Gary H. Glover , and John D. E. Gabrieli Prefrontal regions involved in keeping information in and out of mind Brain 124: 2074-2086.

Silvia A. Bunge , Kevin N. Ochsner , John E. Desmond , Gary H. Glover , and John D. E. Gabrieli
Prefrontal regions involved in keeping information in and out of mind
Brain 124: 2074-2086.

http://brain.oxfordjournals.org/cgi/content/full/124/10/2074

Right prefrontal cortex and episodic memory retrieval: a functional MRI test of the monitoring hypothesis

Though the right prefrontal cortex is often activated in neuroimaging studies of episodic memory retrieval, the functional significance of this activation remains unresolved. In this functional MRI study of 12 healthy volunteers, we tested the hypothesis that one role of the right prefrontal cortex is to monitor the information retrieved from episodic memory in order to make an appropriate response. The critical comparison was between two word recognition tasks that differed only in whether correct responses did or did not require reference to the spatiotemporal context of words presented during a previous study episode. Activation in a dorsal midlateral region of the right prefrontal cortex was associated with increased contextual monitoring demands, whereas a more ventral region of the right prefrontal cortex showed retrieval-related activation that was independent of task instructions. This functional dissociation of dorsal and ventral right prefrontal regions is discussed in relation to a theoretical framework for the control of episodic memory retrieval.



Fig. 2 Lateral areas showing BOLD signal increases (red) and decreases (blue) in comparisons of (A) the Encoding condition relative to the Control condition, (B) the Inclusion condition relative to the Control condition, (C) the Exclusion condition relative to the Control condition and (D) the Exclusion condition relative to the Inclusion condition. For the purpose of illustration the threshold is slightly lower (P < 0.0001 uncorrected) than in Tables 2–5.

R. N. A. Henson , T. Shallice , and R. J. Dolan
Right prefrontal cortex and episodic memory retrieval: a functional MRI test of the monitoring hypothesis
Brain 122: 1367-1381.

http://brain.oxfordjournals.org/cgi/content/full/122/7/1367

Prefrontal cortex and recognition memory. Functional-MRI evidence for context-dependent retrieval processes

Functional neuroimaging studies of episodic recognition memory consistently demonstrate retrieval-associated activation in right prefrontal regions, including the right anterior and right dorsolateral prefrontal cortices. In theory, these activations could reflect processes associated with retrieval success, retrieval effort or retrieval attempt; each of these hypotheses has some support from previous studies. In Experiment 1, we examined these functional interpretations using functional MRI to measure prefrontal activation across multiple levels of recognition performance. Results revealed similar patterns of right prefrontal activation across varying levels of retrieval success and retrieval effort, suggesting that these activations reflect retrieval attempt. Retrieval attempt may include initiation of retrieval search or evaluation of the products of retrieval, such as scrutiny of specific attributes of the test item in an effort to determine whether it was encountered previously. In Experiment 2, we examined whether engagement of retrieval attempt is context-dependent by varying the context in which retrieval was performed; this was done by changing test instructions. Importantly, study and test stimuli were held constant, with only the test instructions varying across conditions. Results revealed that the pattern of right prefrontal activation varied across retrieval contexts. Collectively, these experiments suggest that right prefrontal regions mediate processes associated with retrieval attempt, with the probability of engaging these regions depending upon the retrieval context. Conflicting results across previous studies may be reconciled if the influence of retrieval context on the adopted retrieval strategy is considered. Finally, these results suggest that right prefrontal regions activated during recognition are not critical for successful performance as similar magnitudes of activation were present across multiple levels of performance. These findings reconcile imaging results with the selective effects of prefrontal lesions on retrieval- intensive episodic memory tests.

AD Wagner , JE Desmond , GH Glover , and JD Gabrieli.
Prefrontal cortex and recognition memory. Functional-MRI evidence for context-dependent retrieval processes.
Brain 121: 1985-2002.

http://brain.oxfordjournals.org/cgi/content/abstract/121/10/1985

Decisional role of the dorsolateral prefrontal cortex in ocular motor behaviour

Three patients with a unilateral cortical lesion affecting the dorsolateral prefrontal cortex (DLPFC), i.e. Brodmann area 46, were tested using different paradigms of reflexive saccades (gap and overlap tasks), intentional saccades (antisaccades, memory-guided and predictive saccades) and smooth pursuit movements. Visually guided saccades with gap and overlap, latency of correct antisaccades and memory-guided saccades and the gain of smooth pursuit were normal, compared with controls. These results confirm our anatomical data showing that the adjacent frontal eye field (FEF) was unimpaired in these patients. The specific pattern of abnormalities after a unilateral DLPFC lesion, compared with that of the FEF lesions previously reported, consists mainly of: (i) a bilateral increase in the percentage of errors in the antisaccade task (misdirected reflexive saccades); (ii) a bilateral increase in the variable error in amplitude, without significant decrease in the gain, in the memory-guided saccade task; and (iii) a bilateral decrease in the percentage of anticipatory saccades in the predictive task. Taken together, these results suggest that the DLPFC plays a crucial role in the decisional processes, preparing saccades by inhibiting unwanted reflexive saccades (inhibition), maintaining memorized information for ongoing intentional saccades (short-term spatial memory) or facilitating anticipatory saccades (prediction), depending upon current external environmental and internal circumstances.




Fig. 6 Cortical areas involved in saccades. After receiving visual information in the occipital lobe and after visuospatial integration in the PPC, a saccade may be either triggered reflexively, mainly by the PEF, or triggered intentionally by the FEF, an area which also appears to be involved in active visual fixation. If a reflexive saccade must be inhibited, the DLPFC appears to play a crucial role (1). This area is also involved in short-term spatial memory (2) and prediction (3) when anticipatory saccades must be performed. With these three different actions, the DLPFC could play an important role in the decisional processes controlling ocular motor behaviour. The SEF could be involved in motor programmes including several successive saccades, or saccades combined with other body movements, whereas the CEF appears to activate all the areas controlling intentional saccades via a motivation process. ACC = anterior cingulate cortex; CEF = cingulate eye field; cs = central sulcus; DLPFC = dorsolateral prefrontal cortex; FEF = frontal eye field; ips = intraparietal sulcus; ls = lateral sulcus; pcs = precentral sulcus; PEF = parietal eye field; PPC = posterior parietal cortex; RF = brainstem reticular formation; SC = superior colliculus; SEF = supplementary eye field; 1, 2, 3 = the main actions of the DLPFC; + = saccade triggering; – = saccade inhibition.

C. Pierrot-Deseilligny , R. M. Müri , C. J. Ploner , B. Gaymard , S. Demeret , and S. Rivaud-Pechoux .
Decisional role of the dorsolateral prefrontal cortex in ocular motor behaviour.
Brain Advance Access published on June 1, 2003, DOI 10.1093/brain/awg148.
Brain 126: 1460-1473.

http://brain.oxfordjournals.org/cgi/content/full/126/6/1460

Functional Internal Complexity of Amygdala: Focus on Gene Activity Mapping After Behavioral Training and Drugs of Abuse

The amygdala is a heterogeneous brain structure implicated in processing of emotions and storing the emotional aspects of memories. Gene activity markers such as c-Fos have been shown to reflect both neuronal activation and neuronal plasticity. Herein, we analyze the expression patterns of gene activity markers in the amygdala in response to either behavioral training or treatment with drugs of abuse and then we confront the results with data on other approaches to internal complexity of the amygdala. c-Fos has been the most often studied in the amygdala, showing specific expression patterns in response to various treatments, most probably reflecting functional specializations among amygdala subdivisions. In the basolateral amygdala, c-Fos expression appears to be consistent with the proposed role of this nucleus in a plasticity of the current stimulus-value associations. Within the medial part of the central amygdala, c-Fos correlates with acquisition of alimentary/gustatory behaviors. On the other hand, in the lateral subdivision of the central amygdala, c-Fos expression relates to attention and vigilance. In the medial amygdala, c-Fos appears to be evoked by emotional novelty of the experimental situation. The data on the other major subdivisions of the amygdala are scarce. In conclusion, the studies on the gene activity markers, confronted with other approaches involving neuroanatomy, physiology, and the lesion method, have revealed novel aspects of the amygdala, especially pointing to functional heterogeneity of this brain region that does not fit very well into contemporarily active debate on serial versus parallel information processing within the amygdala.

Ewelina Knapska, Kasia Radwanska, Tomasz Werka, and Leszek Kaczmarek.
Functional Internal Complexity of Amygdala: Focus on Gene Activity Mapping After Behavioral Training and Drugs of Abuse.
Physiol. Rev. 87: 1113-1173, 2007. doi:10.1152/physrev.00037.2006.

http://physrev.physiology.org/cgi/content/abstract/87/4/1113

Lesions of the Basal Amygdala Block Expression of Conditioned Fear But Not Extinction

Although the role of the amygdala in acquisition of conditioned fear is well established, there is debate concerning the intra-amygdala circuits involved. The lateral nucleus of the amygdala (LA) is thought to be an essential site of plasticity in fear conditioning. The LA has both direct and indirect [via the basal nuclei; basal amygdala (BA)] projections to the central nucleus (Ce) of the amygdala, an essential output for fear behaviors. Lesions of the LA or Ce prevent acquisition of conditioned freezing to a conditioned stimulus, but BA lesions do not, suggesting that the BA is not normally involved in fear conditioning. If true, posttraining BA lesions should also have no effect. Replicating previous studies, we found that rats given electrolytic BA lesions before training acquired conditioned fear normally. They also showed normal long-term retention and extinction of conditioned fear. Unexpectedly, BA lesions made after training completely blocked expression of conditioned fear. Despite this deficit, lesioned rats were able to learn a new tone-shock association. Thus, although the LA-Ce system is sufficient for fear acquisition in the absence of the BA, it is not sufficient when the BA is present, suggesting that the BA is an important site of plasticity in fear conditioning. The pattern of lesion deficits we observed (after but not before training) might be explained by homeostatic mechanisms that balance plasticity over multiple inputs, regulating the influence of the BA and LA onto Ce output neurons.



Figure 5. Model to account for deficits with posttraining, but not pretraining, lesions. We suggest that homeostatic mechanisms that balance plasticity over multiple inputs could regulate the influence of the BA, LA, and MGm onto CeM neurons. 1, The CeM receives inputs from the MGm, BA, and LA via ITC cells (dashed line). 2, After fear conditioning, BA inputs gain a large proportion of the total plasticity, inhibiting the development of plasticity in neighboring inputs. 3, Posttraining lesions of the BA remove this plasticity, leaving the system subthreshold for producing a fear response. 4, With pretraining removal of the BA, however, increased plasticity in the LA and MGm supports fear learning. For simplicity, projections from the MGm to the LA and from the LA to the BA are not shown.

David Anglada-Figueroa, and Gregory J. Quirk
Lesions of the Basal Amygdala Block Expression of Conditioned Fear But Not Extinction
J. Neurosci. 25: 9680-9685; doi:10.1523/JNEUROSCI.2600-05.2005

http://www.jneurosci.org/cgi/content/full/25/42/9680

Cortical Connections of the Insular and Adjacent Parieto-temporal Fields in the Cat

We present a comprehensive analysis of the cortical connections of the insular and adjacent cortical areas in the domestic cat by using microinjections of wheat-germ agglutinin conjugated to horseradish peroxidase. We examined the identity and extent of the cortical fields connected to each area, the relative anatomical weights of the various connections, their laminar origin, and their paths across the cerebral commissures. Our main finding is that despite their relatively small size and close apposition, the connections of the insular and adjacent areas are far more widespread and more specific to each area than previously realized, suggesting that each area is involved in disparate aspects of cortical integration. The granular insular area is linked to a constellation of somatosensory, motor, premotor and prefrontal districts. The dysgranular insular area is chiefly associated with lateral prefrontal and premotor, lateral somatosensory and perirhinal cortices. The dorsal agranular insular area is connected with limbic neocortical fields, while the ventral agranular insular area is associated with an array of olfactory allocortical fields. The anterior sylvian area is associated with visual, auditory and multimodal areas, with the dorsolateral prefrontal cortex, and with perirhinal area 36. The parainsular area is linked to non-tonotopic auditory and ventromedial frontal areas. Trajectories followed by the callosal axons of each of the investigated areas are extremely divergent. As a whole, the picture of the insular region that emerges from this and a parallel study (Clascá et al., J Comp Neurol 384:456–482, 1997) is that of an extreme heterogeneity, both in terms of histological architecture and neural connections. Comparison with earlier published reports on primates suggests that most, but not all, of the areas we investigated in cats may have an direct counterpart within the insula of Old World monkeys.



Figure 1



Figure 17. Summary of cortical and thalamic relationships of the areas under study. Each panel represents the connections of an area on standard medial and lateral views of the hemisphere. Outlined letters identify the area of interest. Thicker lines and bold case highlight heavier connections, while thin or dashed lines indicate less numerous connections. Thalamic input is represented by the ellipsoids and arrow at the bottom of each panel. Connections of (A) GI, (B) DI, (C) AId, (D) AIv, (E) Pi, (F) AS. Abbreviations for thalamic nuclei (n): CeM, centralis medialis n.; LM, lateralis medialis n.; M(D), mediodorsal nucleus; MGm, medial geniculate n., medial division; MGvl, medial geniculate n., ventrolateral subnucleus; Pf, parafascicular n.; PoM, posterior thalamic n., medial division; Re, reuniens n.; Rh, rhomboid n.; VL, ventrolateral n.; VM, ventromedial n.; VPi, ventralis posteroinferior n.; VPmP, ventralis posteromedialis n., peripheral subnucleus. For other abbreviations see Table 1.

Francisco Clascá , Alfonso Llamas , and Fernando Reinoso-Suárez
Cortical Connections of the Insular and Adjacent Parieto-temporal Fields in the Cat.
Cereb. Cortex 10: 371-399.

http://cercor.oxfordjournals.org/cgi/content/full/10/4/371

Superior temporal gyrus and insula provide response and outcome-dependent information during assessment and action selection in a decision-making ...

Decision-making is a complex process that comprises the assessment of a situation, the selection of an action, and the evaluation of an outcome. Distinct neural systems may contribute differentially during various stages within a decision-making situation. This study investigated whether neural activation during assessment or action selection is critically dependent on previous outcomes or actions. Twelve healthy, right-handed subjects (6 females) played a Rock Paper Scissors (RPS) computer game during functional magnetic resonance imaging. Bilateral insula and medial prefrontal cortex (including the anterior cingulate) were specifically engaged during the assessment and action selection stages of decision-making, whereas bilateral superior frontal gyrus and right inferior parietal lobule activated more during the outcome. Two regions of activation within the bilateral superior temporal gyrus activated only when the previous outcome was a win. Moreover, right insula and superior temporal gyrus were active more when the subject switched responses relative to staying with the same choice made on the previous trial. These findings support the hypothesis that distinct neural systems underlie different stages of the decision-making process. Furthermore, the superior temporal gyrus may play an important role in integrating previous actions and successful outcomes into one's decision-making strategy.

Paulus MP, Feinstein JS, Leland D, Simmons AN.
Superior temporal gyrus and insula provide response and outcome-dependent information during assessment and action selection in a decision-making situation.
Neuroimage. 2005 Apr 1;25(2):607-15.

http://www.ncbi.nlm.nih.gov/sites/entrez?Db=pubmed&Cmd=ShowDetailView&TermToSearch=15784440