Prefrontal cortex explained

Prefrontal cortex
Latin:cortex praefrontalis
Width:300
Ispartof:Frontal lobe
Components:Superior frontal gyrus
Middle frontal gyrus
Inferior frontal gyrus
Artery:Anterior cerebral
Middle cerebral
Vein:Superior sagittal sinus

In mammalian brain anatomy, the prefrontal cortex (PFC) covers the front part of the frontal lobe of the cerebral cortex. It is the association cortex in the frontal lobe.[1] The PFC contains the Brodmann areas BA8, BA9, BA10, BA11, BA12, BA13, BA14, BA24, BA25, BA32, BA44, BA45, BA46, and BA47.[2]

This brain region is involved in a wide range of higher-order cognitive functions, including speech formation (Broca's area), gaze (frontal eye fields), working memory (dorsolateral prefrontal cortex), and risk processing (e.g. ventromedial prefrontal cortex). The basic activity of this brain region is considered to be orchestration of thoughts and actions in accordance with internal goals.[3] Many authors have indicated an integral link between a person's will to live, personality, and the functions of the prefrontal cortex.[4]

This brain region has been implicated in executive functions, such as planning, decision making, working memory, personality expression, moderating social behavior and controlling certain aspects of speech and language.[5] [6] [7] Executive function relates to abilities to differentiate among conflicting thoughts, determine good and bad, better and best, same and different, future consequences of current activities, working toward a defined goal, prediction of outcomes, expectation based on actions, and social "control" (the ability to suppress urges that, if not suppressed, could lead to socially unacceptable outcomes).

The frontal cortex supports concrete rule learning, with more anterior regions supporting rule learning at higher levels of abstraction.[8]

Structure

Definition

There are three possible ways to define the prefrontal cortex:

Granular frontal cortex

The prefrontal cortex has been defined based on cytoarchitectonics by the presence of a cortical granular layer IV. It is not entirely clear who first used this criterion. Many of the early cytoarchitectonic researchers restricted the use of the term prefrontal to a much smaller region of cortex including the gyrus rectus and the gyrus rostralis (Campbell, 1905; G. E. Smith, 1907; Brodmann, 1909; von Economo and Koskinas, 1925). In 1935, however, Jacobsen used the term prefrontal to distinguish granular prefrontal areas from agranular motor and premotor areas.[9] In terms of Brodmann areas, the prefrontal cortex traditionally includes areas 8, 9, 10, 11, 12, 13, 14, 24, 25, 32, 44, 45, 46, and 47, however, not all of these areas are strictly granular – 44 is dysgranular, caudal 11 and orbital 47 are agranular.[10] The main problem with this definition is that it works well only in primates but not in nonprimates, as the latter lack a granular layer IV.[11]

Projection zone

To define the prefrontal cortex as the projection zone of the mediodorsal nucleus of the thalamus builds on the work of Rose and Woolsey,[12] who showed that this nucleus projects to anterior and ventral parts of the brain in nonprimates, however, Rose and Woolsey termed this projection zone "orbitofrontal." It seems to have been Akert, who, for the first time in 1964, explicitly suggested that this criterion could be used to define homologues of the prefrontal cortex in primates and nonprimates.[13] This allowed the establishment of homologies despite the lack of a granular frontal cortex in nonprimates.

The projection zone definition is still widely accepted today (e.g. Fuster[14]), although its usefulness has been questioned.[15] Modern tract tracing studies have shown that projections of the mediodorsal nucleus of the thalamus are not restricted to the granular frontal cortex in primates. As a result, it was suggested to define the prefrontal cortex as the region of cortex that has stronger reciprocal connections with the mediodorsal nucleus than with any other thalamic nucleus. Uylings et al. acknowledge, however, that even with the application of this criterion, it might be rather difficult to define the prefrontal cortex unequivocally.

Electrically silent area of frontal cortex

A third definition of the prefrontal cortex is the area of frontal cortex whose electrical stimulation does not lead to observable movements. For example, in 1890 David Ferrier[16] used the term in this sense. One complication with this definition is that the electrically "silent" frontal cortex includes both granular and non-granular areas.

Subdivisions

According to Striedter,[17] the PFC of humans can be delineated into two functionally, morphologically, and evolutionarily different regions: the ventromedial PFC (vmPFC) consisting of:

  1. the ventral prefrontal cortex (VPFC)
  2. the medial prefrontal cortex present in all mammals (MPFC)

and the lateral prefrontal cortex (LPFC), consisting of:

  1. the dorsolateral prefrontal cortex (DLPFC)
  2. the ventrolateral prefrontal cortex (VLPFC) present only in primates.

The LPFC contains the Brodmann areas BA8, BA9, BA10, BA45, BA46, and BA47. Some researchers also include BA44. The vmPFC contains the Brodmann areas BA12, BA25, BA32, BA33, BA24, BA11, BA13, and BA14.

The table below shows different ways to subdivide parts of the human prefrontal cortex based upon Brodmann areas.

8910464547441225323324111314
lateralventromedial
dorsolateralventrolateralmedialventral

Interconnections

The prefrontal cortex is highly interconnected with much of the brain, including extensive connections with other cortical, subcortical and brain stem sites.[20] The dorsal prefrontal cortex is especially interconnected with brain regions involved with attention, cognition and action,[21] while the ventral prefrontal cortex interconnects with brain regions involved with emotion.[22] The prefrontal cortex also receives inputs from the brainstem arousal systems, and its function is particularly dependent on its neurochemical environment.[23] Thus, there is coordination between one's state of arousal and mental state.[24] The interplay between the prefrontal cortex and socioemotional system of the brain is relevant for adolescent development, as proposed by the Dual Systems Model.

The medial prefrontal cortex has been implicated in the generation of slow-wave sleep (SWS), and prefrontal atrophy has been linked to decreases in SWS.[25] Prefrontal atrophy occurs naturally as individuals age, and it has been demonstrated that older adults experience impairments in memory consolidation as their medial prefrontal cortices degrade.[25] In older adults, instead of being transferred and stored in the neocortex during SWS, memories start to remain in the hippocampus where they were encoded, as evidenced by increased hippocampal activation compared to younger adults during recall tasks, when subjects learned word associations, slept, and then were asked to recall the learned words.[25]

The ventrolateral prefrontal cortex (VLPFC) has been implicated in various aspects of speech production and language comprehension. The VLPFC is richly connected to various regions of the brain including the lateral and medial temporal lobe, the superior temporal cortex, the infertemporal cortex, the perirhinal cortex, and the parahippoccampal cortex.[26] These brain areas are implicated in memory retrieval and consolidation, language processing, and association of emotions. These connections allow the VLPFC to mediate explicit and implicit memory retrieval and integrate it with language stimulus to help plan coherent speech.[27] In other words, choosing the correct words and staying "on topic" during conversation come from the VLPFC.

Function

Executive function

The original studies of Fuster and of Goldman-Rakic emphasized the fundamental ability of the prefrontal cortex to represent information not currently in the environment, and the central role of this function in creating the "mental sketch pad". Goldman-Rakic spoke of how this representational knowledge was used to intelligently guide thought, action, and emotion, including the inhibition of inappropriate thoughts, distractions, actions, and feelings.[28] In this way, working memory can be seen as fundamental to attention and behavioral inhibition. Fuster speaks of how this prefrontal ability allows the wedding of past to future, allowing both cross-temporal and cross-modal associations in the creation of goal-directed, perception-action cycles.[29] This ability to represent underlies all other higher executive functions.

Shimamura proposed Dynamic Filtering Theory to describe the role of the prefrontal cortex in executive functions. The prefrontal cortex is presumed to act as a high-level gating or filtering mechanism that enhances goal-directed activations and inhibits irrelevant activations. This filtering mechanism enables executive control at various levels of processing, including selecting, maintaining, updating, and rerouting activations. It has also been used to explain emotional regulation.[30]

Miller and Cohen proposed an Integrative Theory of Prefrontal Cortex Function, that arises from the original work of Goldman-Rakic and Fuster. The two theorize that "cognitive control stems from the active maintenance of patterns of activity in the prefrontal cortex that represents goals and means to achieve them. They provide bias signals to other brain structures whose net effect is to guide the flow of activity along neural pathways that establish the proper mappings between inputs, internal states, and outputs needed to perform a given task".[31] In essence, the two theorize that the prefrontal cortex guides the inputs and connections, which allows for cognitive control of our actions.

The prefrontal cortex is of significant importance when top-down processing is needed. Top-down processing by definition is when behavior is guided by internal states or intentions. According to the two, "The PFC is critical in situations when the mappings between sensory inputs, thoughts, and actions either are weakly established relative to other existing ones or are rapidly changing". An example of this can be portrayed in the Wisconsin Card Sorting Test (WCST). Subjects engaging in this task are instructed to sort cards according to the shape, color, or number of symbols appearing on them. The thought is that any given card can be associated with a number of actions and no single stimulus-response mapping will work. Human subjects with PFC damage are able to sort the card in the initial simple tasks, but unable to do so as the rules of classification change. Miller and Cohen conclude that the implications of their theory can explain how much of a role the PFC has in guiding control of cognitive actions. In the researchers' own words, they claim that, "depending on their target of influence, representations in the PFC can function variously as attentional templates, rules, or goals by providing top-down bias signals to other parts of the brain that guide the flow of activity along the pathways needed to perform a task".

Experimental data indicate a role for the prefrontal cortex in mediating normal sleep physiology, dreaming and sleep-deprivation phenomena.[32]

When analyzing and thinking about attributes of other individuals, the medial prefrontal cortex is activated, however, it is not activated when contemplating the characteristics of inanimate objects.[33]

Studies using fMRI have shown that the medial prefrontal cortex (mPFC), specifically the anterior medial prefrontal cortex (amPFC), may modulate mimicry behavior. Neuroscientists are suggesting that social priming influences activity and processing in the amPFC, and that this area of the prefrontal cortex modulates mimicry responses and behavior.[34]

As of recent, researchers have used neuroimaging techniques to find that along with the basal ganglia, the prefrontal cortex is involved with learning exemplars, which is part of the exemplar theory, one of the three main ways our mind categorizes things. The exemplar theory states that we categorize judgements by comparing it to a similar past experience within our stored memories.[35]

A 2014 meta-analysis by Professor Nicole P.Yuan from the University of Arizona found that larger prefrontal cortex volume and greater PFC cortical thickness were associated with better executive performance.[36]

Attention and memory

A widely accepted theory regarding the function of the brain's prefrontal cortex is that it serves as a store of short-term memory. This idea was first formulated by Jacobsen, who reported in 1936 that damage to the primate prefrontal cortex caused short-term memory deficits.[37] Karl Pribram and colleagues (1952) identified the part of the prefrontal cortex responsible for this deficit as area 46, also known as the dorsolateral prefrontal cortex (dlPFC).[38] More recently, Goldman-Rakic and colleagues (1993) evoked short-term memory loss in localized regions of space by temporary inactivation of portions of the dlPFC.[39] Once the concept of working memory (see also Baddeley's model of working memory) was established in contemporary neuroscience by Alan Baddeley (1986), these neuropsychological findings contributed to the theory that the prefrontal cortex implements working memory and, in some extreme formulations, only working memory.[40] In the 1990s this theory developed a wide following, and it became the predominant theory of PF function, especially for nonhuman primates. The concept of working memory used by proponents of this theory focused mostly on the short-term maintenance of information, and rather less on the manipulation or monitoring of such information or on the use of that information for decisions. Consistent with the idea that the prefrontal cortex functions predominantly in maintenance memory, delay-period activity in the PF has often been interpreted as a memory trace. (The phrase "delay-period activity" applies to neuronal activity that follows the transient presentation of an instruction cue and persists until a subsequent "go" or "trigger" signal.)

To explore alternative interpretations of delay-period activity in the prefrontal cortex, Lebedev et al. (2004) investigated the discharge rates of single prefrontal neurons as monkeys attended to a stimulus marking one location while remembering a different, unmarked location. Both locations served as potential targets of a saccadic eye movement. Although the task made intensive demands on short-term memory, the largest proportion of prefrontal neurons represented attended locations, not remembered ones. These findings showed that short-term memory functions cannot account for all, or even most, delay-period activity in the part of the prefrontal cortex explored. The authors suggested that prefrontal activity during the delay-period contributes more to the process of attentional selection (and selective attention) than to memory storage.[7] [41]

Speech production and language

Various areas of the prefrontal cortex have been implicated in a multitude of critical functions regarding speech production, language comprehension, and response planning before speaking. Cognitive neuroscience has shown that the left ventrolateral prefrontal cortex is vital in the processing of words and sentences.

The right prefrontal cortex has been found to be responsible for coordinating the retrieval of explicit memory for use in speech, whereas the deactivation of the left is responsible for mediating implicit memory retrieval to be used in verb generation. Recollection of nouns (explicit memory) is impaired in some amnesic patients with damaged right prefrontal cortices, but verb generation remains intact because of its reliance on left prefrontal deactivation.

Many researchers now include BA45 in the prefrontal cortex because together with BA44 it makes up an area of the frontal lobe called Broca's area. Broca's Area is widely considered the output area of the language production pathway in the brain (as opposed to Wernicke's area in the medial temporal lobe, which is seen as the language input area). BA45 has been shown to be implicated for the retrieval of relevant semantic knowledge to be used in conversation/speech. The right lateral prefrontal cortex (RLPFC) is implicated in the planning of complex behavior, and together with bilateral BA45, they act to maintain focus and coherence during speech production. However, left BA45 has been shown to be activated significantly while maintaining speech coherence in young people. Older people have been shown to recruit the right BA45 more so than their younger counterparts. This aligns with the evidence of decreased lateralization in other brain systems during aging.

In addition, this increase in BA45 and RLPFC activity in combination of BA47 in older patients has been shown to contribute to "off-topic utterances." The BA47 area in the prefrontal cortex is implicated in "stimulus-driven" retrieval of less-salient knowledge than is required to contribute to a conversation. In other words, elevated activation of the BA47 together with altered activity in BA45 and the broader RLPFC has been shown to contribute to the inclusion of less relevant information and irrelevant tangential conversational speech patterns in older subjects.

Clinical significance

In the last few decades, brain imaging systems have been used to determine brain region volumes and nerve linkages. Several studies have indicated that reduced volume and interconnections of the frontal lobes with other brain regions is observed in patients diagnosed with mental disorders; those subjected to repeated stressors;[42] those who excessively consume sexually explicit materials;[43] suicides;[44] criminals; sociopaths; those affected by lead poisoning;[45] It is believed that at least some of the human abilities to feel guilt or remorse, and to interpret reality, are dependent on a well-functioning prefrontal cortex.[46] The advanced neurocircuitry and self-regulatory function of the human prefrontal cortex is also associated with the higher sentience in humans,[47] as the prefrontal cortex in humans occupies a far larger percentage of the brain than in any other animal. It is theorized that, as the brain has tripled in size over five million years of human evolution,[48] the prefrontal cortex has increased in size sixfold.[49]

A review on executive functions in healthy exercising individuals noted that the left and right halves of the prefrontal cortex, which is divided by the medial longitudinal fissure, appears to become more interconnected in response to consistent aerobic exercise.[50] Two reviews of structural neuroimaging research indicate that marked improvements in prefrontal and hippocampal gray matter volume occur in healthy adults that engage in medium intensity exercise for several months.[51] [52]

Chronic intake of alcohol leads to persistent alterations in brain function including altered decision-making ability. The prefrontal cortex of chronic alcoholics has been shown to be vulnerable to oxidative DNA damage and neuronal cell death.[53]

History

Perhaps the seminal case in prefrontal cortex function is that of Phineas Gage, whose left frontal lobe was destroyed when a large iron rod was driven through his head in an 1848 accident. The standard presentation is that, although Gage retained normal memory, speech and motor skills, his personality changed radically: He became irritable, quick-tempered, and impatient—characteristics he did not previously display — so that friends described him as "no longer Gage"; and, whereas he had previously been a capable and efficient worker, afterward he was unable to complete.[54] However, careful analysis of primary evidence shows that descriptions of Gage's psychological changes are usually exaggerated when held against the description given by Gage's doctor, the most striking feature being that changes described years after Gage's death are far more dramatic than anything reported while he was alive.[55] [56]

Subsequent studies on patients with prefrontal injuries have shown that the patients verbalized what the most appropriate social responses would be under certain circumstances. Yet, when actually performing, they instead pursued behavior aimed at immediate gratification, despite knowing the longer-term results would be self-defeating.

The interpretation of this data indicates that not only are skills of comparison and understanding of eventual outcomes harbored in the prefrontal cortex but the prefrontal cortex (when functioning correctly) controls the mental option to delay immediate gratification for a better or more rewarding longer-term gratification result. This ability to wait for a reward is one of the key pieces that define optimal executive function of the human brain.

There is much current research devoted to understanding the role of the prefrontal cortex in neurological disorders. Clinical trials have begun on certain drugs that have been shown to improve prefrontal cortex function, including guanfacine, which acts through the alpha-2A adrenergic receptor. A downstream target of this drug, the HCN channel, is one of the most recent areas of exploration in prefrontal cortex pharmacology.[57]

Etymology

The term "prefrontal" as describing a part of the brain appears to have been introduced by Richard Owen in 1868. For him, the prefrontal area was restricted to the anterior-most part of the frontal lobe (approximately corresponding to the frontal pole). It has been hypothesized that his choice of the term was based on the prefrontal bone present in most amphibians and reptiles.

See also

External links

Notes and References

  1. Web site: Prefrontal Cortex - an overview ScienceDirect Topics . 2024-02-08 . www.sciencedirect.com.
  2. Book: Murray E, Wise S, Grahatle K . The Evolution of Memory Systems: Ancestors, Anatomy, and Adaptations. 2016. Oxford University Press. 978-0-19-150995-7 . 22–24. 1st. https://books.google.com/books?id=eMNjDQAAQBAJ&pg=PA24. 12 March 2017. Chapter 1: The History of Memory Systems.
  3. Miller EK, Freedman DJ, Wallis JD . The prefrontal cortex: categories, concepts and cognition . Philosophical Transactions of the Royal Society of London. Series B, Biological Sciences . 357 . 1424 . 1123–1136 . August 2002 . 12217179 . 1693009 . 10.1098/rstb.2002.1099 .
  4. DeYoung CG, Hirsh JB, Shane MS, Papademetris X, Rajeevan N, Gray JR . Testing predictions from personality neuroscience. Brain structure and the big five . Psychological Science . 21 . 6 . 820–828 . June 2010 . 20435951 . 3049165 . 10.1177/0956797610370159 .
  5. Yang Y, Raine A . Prefrontal structural and functional brain imaging findings in antisocial, violent, and psychopathic individuals: a meta-analysis . Psychiatry Research . 174 . 2 . 81–88 . November 2009 . 19833485 . 2784035 . 10.1016/j.pscychresns.2009.03.012 .
  6. Gabrieli JD, Poldrack RA, Desmond JE . The role of left prefrontal cortex in language and memory . Proceedings of the National Academy of Sciences of the United States of America . 95 . 3 . 906–913 . February 1998 . 9448258 . 33815 . 10.1073/pnas.95.3.906 . free . 1998PNAS...95..906G .
  7. Baldauf D, Desimone R . Neural mechanisms of object-based attention . Science . 344 . 6182 . 424–427 . April 2014 . 24763592 . 10.1126/science.1247003 . 34728448 . 2014Sci...344..424B . free .
  8. Badre D, Kayser AS, D'Esposito M . Frontal cortex and the discovery of abstract action rules . Neuron . 66 . 2 . 315–326 . April 2010 . 20435006 . 2990347 . 10.1016/j.neuron.2010.03.025 .
  9. Book: Finger S . Origins of neuroscience: a history of explorations into brain function . Oxford University Press . Oxford [Oxfordshire] . 1994 . 978-0-19-514694-3 .
  10. Preuss TM . Do rats have prefrontal cortex? The rose-woolsey-akert program reconsidered . Journal of Cognitive Neuroscience . 7 . 1 . 1–24 . 1995 . 23961750 . 10.1162/jocn.1995.7.1.1 . 2856619 .
  11. Uylings HB, Groenewegen HJ, Kolb B . Do rats have a prefrontal cortex? . Behavioural Brain Research . 146 . 1–2 . 3–17 . November 2003 . 14643455 . 10.1016/j.bbr.2003.09.028 . 32136463 .
  12. Rose JE, Woolsey CN . The orbitofrontal cortex and its connections with the mediodorsal nucleus in rabbit, sheep and cat . Research Publications – Association for Research in Nervous and Mental Disease . 27 . 210–232 . 1948 . 18106857 .
  13. Preuss TM, Goldman-Rakic PS . Myelo- and cytoarchitecture of the granular frontal cortex and surrounding regions in the strepsirhine primate Galago and the anthropoid primate Macaca . The Journal of Comparative Neurology . 310 . 4 . 429–474 . August 1991 . 1939732 . 10.1002/cne.903100402 . 34575725 .
  14. Book: Fuster JM . The Prefrontal Cortex . 4th . Academic Press . Boston . 2008 . 978-0-12-373644-4 .
  15. Markowitsch HJ, Pritzel M . Hans Markowitsch . The prefrontal cortex: Projection area of the thalamic mediodorsal nucleus? . Physiological Psychology . 7 . 1 . 1–6 . 1979 . 10.3758/bf03326611. free .
  16. Ferrier D . The Croonian Lectures on Cerebral Localisation . British Medical Journal . 1 . 1537 . 1349–1355 . June 1890 . 20753055 . 2207859 . 10.1136/bmj.1.1537.1349 .
  17. Book: Striedter GF . Principles of brain evolution . 2005 . Sinauer Associates . 978-0-87893-820-9 . en.
  18. Sheline . Yvette . Yan . Shizi . 2010 . Resting-state functional MRI in depression unmasks increased connectivity between networks via the dorsal nexus . PNAS . 107. 24. 11020–11025. 10.1073/pnas.1000446107 . 20534464 . 2890754. 2010PNAS..10711020S . free.
  19. Web site: Broca area anatomy. Encyclopedia Britannica. en. 2019-12-12.
  20. Alvarez JA, Emory E . Executive function and the frontal lobes: a meta-analytic review . Neuropsychology Review . 16 . 1 . 17–42 . March 2006 . 16794878 . 10.1007/s11065-006-9002-x . 207222975 .
  21. Goldman-Rakic PS . Topography of cognition: parallel distributed networks in primate association cortex . Annual Review of Neuroscience . 11 . 137–156 . 1988 . 3284439 . 10.1146/annurev.ne.11.030188.001033 .
  22. Price JL . Prefrontal cortical networks related to visceral function and mood . Annals of the New York Academy of Sciences . 877 . 1 . 383–396 . June 1999 . 10415660 . 10.1111/j.1749-6632.1999.tb09278.x . 37564764 . 1999NYASA.877..383P .
  23. Robbins TW, Arnsten AF . The neuropsychopharmacology of fronto-executive function: monoaminergic modulation . Annual Review of Neuroscience . 32 . 267–287 . 2009 . 19555290 . 2863127 . 10.1146/annurev.neuro.051508.135535 .
  24. Arnsten AF, Paspalas CD, Gamo NJ, Yang Y, Wang M . Dynamic Network Connectivity: A new form of neuroplasticity . Trends in Cognitive Sciences . 14 . 8 . 365–375 . August 2010 . 20554470 . 2914830 . 10.1016/j.tics.2010.05.003 .
  25. Mander BA, Rao V, Lu B, Saletin JM, Lindquist JR, Ancoli-Israel S, Jagust W, Walker MP . 6 . Prefrontal atrophy, disrupted NREM slow waves and impaired hippocampal-dependent memory in aging . Nature Neuroscience . 16 . 3 . 357–364 . March 2013 . 23354332 . 4286370 . 10.1038/nn.3324 .
  26. Encyclopedia: Kuhl BA, Wagner AD . Strategic Control of Memory. 2009-01-01 . Encyclopedia of Neuroscience. 437–444. Squire LR . Academic Press. 10.1016/b978-008045046-9.00424-1. 978-0-08-045046-9 .
  27. Hoffman P . Reductions in prefrontal activation predict off-topic utterances during speech production . Nature Communications . 10 . 1 . 515 . January 2019 . 30705284 . 6355898 . 10.1038/s41467-019-08519-0 . 2019NatCo..10..515H .
  28. Goldman-Rakic PS . The prefrontal landscape: implications of functional architecture for understanding human mentation and the central executive . Philosophical Transactions of the Royal Society of London. Series B, Biological Sciences . 351 . 1346 . 1445–1453 . October 1996 . 8941956 . 10.1098/rstb.1996.0129 . 3069191 .
  29. Fuster JM, Bodner M, Kroger JK . Cross-modal and cross-temporal association in neurons of frontal cortex . Nature . 405 . 6784 . 347–351 . May 2000 . 10830963 . 10.1038/35012613 . 4421762 . 2000Natur.405..347F .
  30. Shimamura AP . The role of the prefrontal cortex in dynamic filtering . Psychobiology . 28 . 207–218 . 2000 . 2 . 10.3758/BF03331979. 140274181 . free .
  31. Miller EK, Cohen JD . An integrative theory of prefrontal cortex function . Annual Review of Neuroscience . 24 . 167–202 . 2001 . 11283309 . 10.1146/annurev.neuro.24.1.167 . 7301474 .
  32. Muzur A, Pace-Schott EF, Hobson JA . The prefrontal cortex in sleep . Trends in Cognitive Sciences . 6 . 11 . 475–481 . November 2002 . 12457899 . 10.1016/S1364-6613(02)01992-7 . 5530174 .
  33. Mitchell JP, Heatherton TF, Macrae CN . Distinct neural systems subserve person and object knowledge . Proceedings of the National Academy of Sciences of the United States of America . 99 . 23 . 15238–15243 . November 2002 . 12417766 . 137574 . 10.1073/pnas.232395699 . free . 2002PNAS...9915238M .
  34. Wang Y, Hamilton AF . Anterior medial prefrontal cortex implements social priming of mimicry . Social Cognitive and Affective Neuroscience . 10 . 4 . 486–493 . April 2015 . 25009194 . 4381231 . 10.1093/scan/nsu076 .
  35. Schacter, Daniel L., Daniel Todd Gilbert, and Daniel M. Wegner. Psychology. 2nd ed, pages 364–366 New York, NY: Worth Publishers, 2011. Print.
  36. Yuan P, Raz N . Prefrontal cortex and executive functions in healthy adults: a meta-analysis of structural neuroimaging studies . Neuroscience and Biobehavioral Reviews . 42 . 180–192 . May 2014 . 24568942 . 4011981 . 10.1016/j.neubiorev.2014.02.005 .
  37. Jacobsen C.F. (1936) Studies of cerebral function in primates. I. The functions of the frontal associations areas in monkeys. Comp Psychol Monogr 13: 3–60.
  38. Pribram KH, Mishkin M, Rosvold HE, Kaplan SJ . Effects on delayed-response performance of lesions of dorsolateral and ventromedial frontal cortex of baboons . Journal of Comparative and Physiological Psychology . 45 . 6 . 565–575 . December 1952 . 13000029 . 10.1037/h0061240 .
  39. Funahashi S, Bruce CJ, Goldman-Rakic PS . Dorsolateral prefrontal lesions and oculomotor delayed-response performance: evidence for mnemonic "scotomas" . The Journal of Neuroscience . 13 . 4 . 1479–1497 . April 1993 . 8463830 . 6576716 . 10.1523/JNEUROSCI.13-04-01479.1993 .
  40. Baddeley A. (1986) Working memory. Oxford: Oxford University Press. p.289
  41. Bedini M, Baldauf D . Structure, function and connectivity fingerprints of the frontal eye field versus the inferior frontal junction: A comprehensive comparison . The European Journal of Neuroscience . 54 . 4 . 5462–5506 . August 2021 . 34273134 . 10.1111/ejn.15393 . 9291791 . 235999643 .
  42. Liston C, Miller MM, Goldwater DS, Radley JJ, Rocher AB, Hof PR, Morrison JH, McEwen BS . 6 . Stress-induced alterations in prefrontal cortical dendritic morphology predict selective impairments in perceptual attentional set-shifting . The Journal of Neuroscience . 26 . 30 . 7870–7874 . July 2006 . 16870732 . 6674229 . 10.1523/JNEUROSCI.1184-06.2006 .
  43. Web site: Viewers of pornography have a smaller reward system. 2 June 2014. MAX-PLANCK-GESELLSCHAFT. 2 July 2018.
  44. Rajkowska G . Morphometric methods for studying the prefrontal cortex in suicide victims and psychiatric patients . Annals of the New York Academy of Sciences . 836 . 1 . 253–268 . December 1997 . 9616803 . 10.1111/j.1749-6632.1997.tb52364.x . 32947726 . 1997NYASA.836..253R .
  45. Cecil KM, Brubaker CJ, Adler CM, Dietrich KN, Altaye M, Egelhoff JC, Wessel S, Elangovan I, Hornung R, Jarvis K, Lanphear BP . 6 . Decreased brain volume in adults with childhood lead exposure . PLOS Medicine . 5 . 5 . e112 . May 2008 . 18507499 . 2689675 . 10.1371/journal.pmed.0050112 . Balmes J . free .
  46. Anderson SW, Bechara A, Damasio H, Tranel D, Damasio AR . Impairment of social and moral behavior related to early damage in human prefrontal cortex . Nature Neuroscience . 2 . 11 . 1032–1037 . November 1999 . 10526345 . 10.1038/14833 . 204990285 .
  47. Book: Fariba K, Gokarakonda SB . Impulse Control Disorders . 2021 . http://www.ncbi.nlm.nih.gov/books/NBK562279/ . StatPearls. Treasure Island (FL) . StatPearls Publishing . 32965950 . 2021-05-04.
  48. Schoenemann PT, Budinger TF, Sarich VM, Wang WS . Brain size does not predict general cognitive ability within families . Proceedings of the National Academy of Sciences of the United States of America . 97 . 9 . 4932–4937 . April 2000 . 10781101 . 18335 . 10.1073/pnas.97.9.4932 . free . 2000PNAS...97.4932S .
  49. Web site: Cascio T . House & Psychology, Episode 14 . Psychology Today . https://archive.today/20130408080640/http://www.psychologytoday.com/blog/hollywood-phd/201109/house-psychology-episode-14. dead. 2013-04-08. 2011-11-15.
  50. Guiney H, Machado L . Benefits of regular aerobic exercise for executive functioning in healthy populations . Psychonomic Bulletin & Review . 20 . 1 . 73–86 . February 2013 . 23229442 . 10.3758/s13423-012-0345-4 . 24190840 . free .
  51. Erickson KI, Leckie RL, Weinstein AM . Physical activity, fitness, and gray matter volume . Neurobiology of Aging . 35 . Suppl 2 . S20–S28 . September 2014 . 24952993 . 4094356 . 10.1016/j.neurobiolaging.2014.03.034 .
  52. Valkanova V, Eguia Rodriguez R, Ebmeier KP . Mind over matter--what do we know about neuroplasticity in adults? . International Psychogeriatrics . 26 . 6 . 891–909 . June 2014 . 24382194 . 10.1017/S1041610213002482 . 20765865 .
  53. Fowler AK, Thompson J, Chen L, Dagda M, Dertien J, Dossou KS, Moaddel R, Bergeson SE, Kruman II . 6 . Differential sensitivity of prefrontal cortex and hippocampus to alcohol-induced toxicity . PLOS ONE . 9 . 9 . e106945 . 2014 . 25188266 . 4154772 . 10.1371/journal.pone.0106945 . free . 2014PLoSO...9j6945F .
  54. [Antonio Damasio]
  55. Malcolm Macmillan, An Odd Kind of Fame: Stories of Phineas Gage (MIT Press, 2000), pp.116–119, 307–333, esp. pp.11,333.
  56. Macmillan M . 2008 . Phineas Gage – Unravelling the myth . The Psychologist . . 21 . 9 . 828–831 . dead . https://web.archive.org/web/20100903034625/http://www.thepsychologist.org.uk/archive/archive_home.cfm?volumeID=21&editionID=164&ArticleID=1399 . 2010-09-03 . 2014-06-21 .
  57. Wang M, Ramos BP, Paspalas CD, Shu Y, Simen A, Duque A, Vijayraghavan S, Brennan A, Dudley A, Nou E, Mazer JA, McCormick DA, Arnsten AF . 6 . Alpha2A-adrenoceptors strengthen working memory networks by inhibiting cAMP-HCN channel signaling in prefrontal cortex . Cell . 129 . 2 . 397–410 . April 2007 . 17448997 . 10.1016/j.cell.2007.03.015 . 741677 . free .