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Orbitalfrontal cortex

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Brain: Orbitalfrontal cortex
OFC
Approximate location of the OFC shown on a sagittal MRI
Gray729
Orbital surface of left frontal lobe.
Latin '
Gray's subject #189 822
Part of
Components
Artery
Vein
BrainInfo/UW hier-73
MeSH [1]

The orbitofrontal cortex (OFC) is a region of association cortex of the human brain involved in cognitive processes such as decision-making. The name of this region is based upon the region's location within the frontal lobes, resting above the orbits of the eyes. It is defined as the part of the prefrontal cortex that receives projections from the magnocellular, medial, nucleus of the mediodorsal thalamus [1]. Considerable individual variability has been found in the OFC of both humans and non-human primates. Because of its functions in emotion and reward, the OFC is considered by some to be a part of the limbic system.

Functions of the human orbitofrontal cortexEdit

The human OFC is among the least-understood regions of the human brain; but it has been proposed that the OFC is involved in sensory integration, in representing the affective value of reinforcers, and in decision-making and expectation [2]. In particular, the human OFC is thought to regulate planning behavior associated with sensitivity to reward and punishment. [3]. This is supported by research in humans, non-human primates, and rodents. Human research has focused on neuroimaging research in healthy participants and neuropsychology research in patients with damage to discrete parts of the OFC.

Neuroimaging research in healthy participantsEdit

It is important to realise that using functional magnetic resonance imaging (fMRI) to image the human OFC is a challenge, as this brain region is in close proximity to the air-filled sinuses, which means that signal dropout, geometric distortion, and susceptibility artifacts are common when using EPI at higher magnetic field strengths. Extra care is therefore recommended for obtaining a good signal from the orbitofrontal cortex, and a number of strategies have been devised, e.g., [4].

The published neuroimaging studies have found that the reward value, the expected reward value, and even the subjective pleasantness of foods and other reinforcers are represented in the OFC. A large meta-analysis of the existing neuroimaging evidence demonstrated that activity in medial parts of the OFC is related to the monitoring, learning, and memory of the reward value of reinforcers, whereas activity in lateral OFC is related to the evaluation of punishers, which may lead to a change in ongoing behaviour [5]. Similarly, a posterior-anterior distinction was found with more complex or abstract reinforcers (such as monetary gain and loss) being represented more anteriorly in the orbitofrontal cortex than less-complex reinforcers such as taste. It has even been proposed that the human OFC has a role in mediating subjective hedonic experience [2].

Neuropsychology research in patientsEdit

  • The visual discrimination test[6] has two components: reversal learning and extinction. In "reversal learning," participants are presented with one of two pictures, A and B. They learn that they will be rewarded if they press a button when picture A is displayed, but punished if they press the button when picture B is displayed. Once this rule has been established, the rule swaps. In other words, now it is correct to press the button for picture B, not picture A. Most healthy participants pick up on this rule reversal almost immediately, but patients with OFC damage continue to respond to the original pattern of reinforcement, although they are now being punished for persevering with it. Rolls et al. noted that this pattern of behaviour is particularly unusual given that the patients reported that they understood the rule.
  • The second component of the test is "extinction." Again, participants learn to press the button for picture A but not picture B. However this time, instead of the rules reversing, the rule changes altogether. Now the participant will be punished for pressing the button in response to either picture. The correct response is not to press the button at all, but people with OFC dysfunction find it difficult to resist the temptation to press the button despite being punished for it.
  • The Iowa gambling task is a simulation of real life decision-making[7] which is widely used in research of cognition and emotion. Participants are presented with four virtual decks of cards on a computer screen. They are told that each time they choose a card they will win some game money. Every so often, however, when they choose a card they will win money, but will also lose some money, too. They are told that the aim of the game is to win as much money as possible. The task is meant to be opaque, i.e., participants are not meant to consciously work out the rule, and they are supposed to choose cards based on their "gut reaction." Two of the decks are "bad decks," which means that, over a long enough time, they will make a net loss; the other two decks are "good decks" and will make a net gain over time. Most healthy participants sample cards from each deck, and after about 40 or 50 selections are fairly good at sticking to the good decks. Patients with OFC dysfunction, however, continue to perseverate with the bad decks, sometimes even though they know that they are losing money overall. Concurrent measurement of galvanic skin response shows that healthy participants show a "stress" reaction to hovering over the bad decks after only 10 trials, long before conscious sensation that the decks are bad. By contrast, patients with OFC dysfunction never develop this physiological reaction to impending punishment. Bechara and his colleagues explain this in terms of the somatic markers hypothesis. The Iowa gambling task is currently being used by a number of research groups (including the Institute of Psychiatry and Institute of Neurology) using fMRI to investigate which brain regions are activated by the task in healthy volunteers as well as clinical groups with conditions such as schizophrenia and obsessive compulsive disorder.
  • The Faux pas test is a series of vignettes recounting a social occasion wherein someone said something he should not have said, or something awkward. The participant's task is to identify what was said that was awkward, why it was awkward, how people would have felt in reaction to the faux pas, and a factual control question. Although first designed for use in people on the autism spectrum[8], the test is also sensitive to patients with OFC dysfunction, who cannot judge when something socially awkward has happened despite appearing to understand the story perfectly well.

Everyday consequences of damage to the OFCEdit

Destruction of the OFC through acquired brain injury typically leads to a pattern of disinhibited behaviour. Examples include swearing excessively, hypersexuality, poor social interaction, compulsive gambling, excessive alcohol / smoking / drug use, and poor empathising ability. Disinhibited behaviour by patients with some forms of frontotemporal dementia is thought to be caused by degeneration of the OFC[9]. Patients with damage to the OFC tend to make rash decisions, and typically manage their finances poorly.

See alsoEdit

ReferencesEdit

  1. Fuster, J.M. The Prefrontal Cortex, (Raven Press, New York, 1997).
  2. 2.0 2.1 Kringelbach, M. L. (2005) "The orbitofrontal cortex: linking reward to hedonic experience." Nature Reviews Neuroscience 6: 691-702.
  3. Bechara, A.; Damasio, A. R.; Damasio H. & Anderson, S.W. (1994) "Insensitivity to future consequences following damage to human prefrontal cortex". Cognition 50: 7-15.
  4. Wilson, J.; Jenkinson, M.; de Araujo, I. E. T.; Kringelbach, M. L.; Rolls, E. T. & Jezzard, P. (2002) "Fast, fully automated global and local magnetic field optimization for fMRI of the human brain." Neuroimage 17: 967-976.
  5. Kringelbach, M. L. and Rolls, E. T. (2004) "The functional neuroanatomy of the human orbitofrontal cortex: evidence from neuroimaging and neuropsychology." Progress in Neurobiology 72: 341-372.
  6. Rolls, E. T.; Hornak, J.; Wade, D. & McGrath, J. (1994) "Emotion-related learning in patients with social and emotional changes associated with frontal lobe damage." J Neurol Neurosurg Psychiatry 57: 1518-1524.
  7. Cite error: Invalid <ref> tag; no text was provided for refs named Bechara_1994.2C
  8. Stone, V.E.; Baron-Cohen, S. & Knight, R. T. (1998a) "Frontal Lobe Contributions to Theory of Mind." Journal of Medical Investigation 10: 640-656.
  9. Snowden, J. S.; Bathgate, D.; Varma, A.; Blackshaw, A.; Gibbons, Z. C. & Neary. D. (2001) "Distinct behavioural profiles in frontotemporal dementia and semantic dementia". J Neurol Neurosurg Psychiatry 70: 323-332.

External linksEdit


Human brain: Limbic system
Amygdala - Cingulate gyrus - Fornicate gyrus - Hippocampus - Hypothalamus - Mammillary body - Nucleus accumbens - Orbitofrontal cortex - Parahippocampal gyrus
Telencephalon (cerebrum, cerebral cortex, cerebral hemispheres) - edit

primary sulci/fissures: medial longitudinal, lateral, central, parietoöccipital, calcarine, cingulate

frontal lobe: precentral gyrus (primary motor cortex, 4), precentral sulcus, superior frontal gyrus (6, 8), middle frontal gyrus (46), inferior frontal gyrus (Broca's area, 44-pars opercularis, 45-pars triangularis), prefrontal cortex (orbitofrontal cortex, 9, 10, 11, 12, 47)

parietal lobe: postcentral sulcus, postcentral gyrus (1, 2, 3, 43), superior parietal lobule (5), inferior parietal lobule (39-angular gyrus, 40), precuneus (7), intraparietal sulcus

occipital lobe: primary visual cortex (17), cuneus, lingual gyrus, 18, 19 (18 and 19 span whole lobe)

temporal lobe: transverse temporal gyrus (41-42-primary auditory cortex), superior temporal gyrus (38, 22-Wernicke's area), middle temporal gyrus (21), inferior temporal gyrus (20), fusiform gyrus (36, 37)

limbic lobe/fornicate gyrus: cingulate cortex/cingulate gyrus, anterior cingulate (24, 32, 33), posterior cingulate (23, 31),
isthmus (26, 29, 30), parahippocampal gyrus (piriform cortex, 25, 27, 35), entorhinal cortex (28, 34)

subcortical/insular cortex: rhinencephalon, olfactory bulb, corpus callosum, lateral ventricles, septum pellucidum, ependyma, internal capsule, corona radiata, external capsule

hippocampal formation: dentate gyrus, hippocampus, subiculum

basal ganglia: striatum (caudate nucleus, putamen), lentiform nucleus (putamen, globus pallidus), claustrum, extreme capsule, amygdala, nucleus accumbens

Some categorizations are approximations, and some Brodmann areas span gyri.

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