BRAIN. Broad Research in Artificial Intelligence and Neuroscience 
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2020, Volume 11, Issue 3, Sup.1, pages: 127-136 | 

https://doi.org/10.18662/brain/11.3Sup1/128 
 

A Tale of Two 
Frontal Lobes. 
Clinical 
Perspectives of 
Cortical 
Interconnectivity 

Alina – Ioana VOINEA¹*,  
Mirona Letitia DOBRI

2
,  

Codrina MORARU
3
,  

Petronela NECHITA
4
, 

Anamaria CIUBARA
5
 

1 LAS CT, Hertfordshire Partnership 
University NHS Foundation Trust, St. 
Albans, United Kingdom, 
alina_ioana92@yahoo.com  

2 IIIrd Year Psychiatry Resident, “Socola” 
Institute of Psychiatry, Iasi, Romania  

3 IInd Year Psychiatry Resident, “Socola” 
Institute of Psychiatry, Iasi, Romania  

4 MD, PhD, Senior Psychiatrist, “Socola” 
Institute of Psychiatry, Iasi, Romania  

5 MD, PhD, Professor of Psychiatry, 
“Dunarea de Jos” University, Galati, 
Romania  

 

Abstract: Even through centuries passed, while neurosciences were 
mistaken only for phrenology, and neuronal mapping did not exist as a 
self-sustained science, structural changes of the brain were associated, at 
various degrees, with reoccurring activities or behavioural patterns of the 
patient. An extraordinary neuroplasticity was therefore described, meant 
to complete the cerebral network, which sustained superior cognitive 
functioning and played an essential role in adapting to the environment. 
Most of this web of electrical impulses has its nodes inside the frontal 
system, in such a way that no one lobe can be identical to another, 
structurally or when considering informational content. Cortical 
interconnectivity observed in frontal lobes may be a measure of 
physiological variety, but also an aid in understanding linked 
psychopathology. 
The first case we will focus our attention on is Phineas Gage, the railway 
worker who marked the history of neuroscience through his bizarre 
accident and unexpected outcome. Beyond the myth, this famous patient 
amended the understanding of the brain’s organization and revolutionized 
functional cerebral mapping. From here on, we will follow the evolution of 
neuronal connectivity studies and their implications in psychiatric 
pathology, as they are known today. Neuroimaging studies on obsessive 
compulsive disorders, cerebral lesions masked by different psychiatric 
phenomena, as well as correlations between certain affected tracts and 
symptoms of psychotic disturbances, are all scientific events which may 
offer new directions in clinical psychopathology and can invoke different 
therapeutic resources.  
In conclusion, to follow studies of neuronal mapping and use the 
understanding we already have, might be the answer to more complex case 
management, improving a patient’s outcome and helping us choose 
treatment plans more effectively. As a story unfolding from two opposing 
perspectives, the science behind cortical interconnectivity stands witness to 
different principles acting in conjunction for better results, should one only 
use it. 
 

Keywords: frontal systems; neuronal interconnectivity; cortical mapping; 
clinical psychopathology. 
 
How to cite: Voinea, A.-I., Dobri, M.L., Moraru, C., Nechita, 
P., & Ciubara, A. (2020). A Tale of Two Frontal Lobes. 
Clinical Perspectives of Cortical Interconnectivity. BRAIN. 
Broad Research in Artificial Intelligence and Neuroscience, 11(3), 127-
136. https://doi.org/10.18662/brain/11.3Sup1/128 

https://doi.org/10.18662/brain/11.3Sup1/128
mailto:alina_ioana92@yahoo.com
https://doi.org/10.18662/brain/11.3Sup1/128


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Main Character – The Frontal Lobe System 

The genius of Italian Renaissance artist Michelangelo Buonarroti 
remains one of the essential topics of the history of art. Alongside da Vinci, 
he is elementary to the discovery of the human mind, as we now know it. He 
painted magnificent frescoes on the ceiling of the Vatican’s Sistine Chapel, 
laboring from 1508 to 1512. Commissioned by Pope Julius II, Michelangelo 
performed this work himself, without assistance, and revealed the grandiose 
layout in its entirety, withstanding the pressure of christian figures of 
importance during those 4 years. Scholars debate whether he had any 
guidance from the Church in the selection of the scenes, and what meaning 
the scenes were to convey. Neuroscientists though, have proclaimed over 
time numerous findings of absolute importance in those images. In the 
fresco traditionally called the „Creation of Adam”, but which might be more 
aptly titled the Endowment of Adam, Michelangelo encoded a hidden 
message. It is a message consistent with thoughts he expressed in his 
sonnets. Supreme in sculpture and painting, he understood that his skill was 
in his brain and not in his hands. He believed that the “divine part” we 
“receive” from God is the “intellect”, this bringing with itself a power higher 
than any other could be. 

Below God’s hand pointing towards Adam, the pink cloak has a fold 
that may be recognized as the Sylvian fissure as shown in the pictures above. 
Similarly, following anticlockwise, the cherub’s knee assumes the shape of 
the optic chiasm and the back of the angel below God takes the shape of the 
pons. The sulcus cinguli extends along the hip of the angel in front of God, 
across his shoulders and over Eve’s forehead. The flowing green textured 
robe stand in place for the vertebral artery, in it’s rapport to the spinal cord 
as represented by the intertwined legs. The pituitary stalk and gland are 
depicted by the foot of the angel that go beyond the base of the picture.  

Most importantly thoug, is not to identify detailed neuroanatomical 
structures, but better yet to understand the larger image of the Creator as 
being compatible with cognitive and high functioning commands yielded by 
the cerebral cortex. God gives to Adam, a mere mortal, the power of 
knowing and learning the world around him, and by spearing with his hand 
the prefrontal area of the brain, he endowes Adam with personality and 
archetypal traits (Meshberger, 1990). 

Beyond all neuroscientific stories (Bamijoko-Okungbaye, 2018; 
Sandu, 2017), the frontal lobe is one of the most important anatomical areas 
of the brain, in dimensions as well as in functionality. It is considered the 



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largest, macroscopically, the cortical layer of the lobe accounting for 
approximately 37–39% of the cerebral cortex, where part of this structure is 
composed of the prefrontal cortex (PFC). This cortical region forms part of 
an extensive connective network involved in socioemotional abilities and in 
the executive function of humans and other primates.  

Comparative studies suggest that the characteristic differentiation of 
the prefrontal lobe of humans compared to that of other primates lies more 
in circuit organization than mere size of the structure. From a phylogenetic 
perspective, it is believed that the relatively recent reorganization of the 
frontal cortical circuitry has been pivotal to the emergence of the specific 
cognitive functions of the frontal lobe in humans (Burlea et al., 2010).  

Functionality of the Highest Importance 

At a first glance towards indepth anatomy of the brain, the 
prefrontal areas are devouted to specific functionalities. The higher cognitive 
expressions are linked moreso to the dorsolateral parts of the frontal lobe 
(Broadmann 9, 10, 4), while social abilities are related to the orbitofrontal 
cortex within Broadmann areas 10, 11, 13, 47 (João & Filgueiras, 2018). 

Few distinctive circuits are considered of major significance 
throughout the frontal gray matter, mainly the dorsolateral circuit, 
orbitofrontal circuit, and the circuit including the front cingulate parcels of 
the frontal projection. These connective pathways begin and end within the 
prefrontal cortex, whereas their direction can extend them to particular 
structures, such as the caudate, globus pallidus, thalamus, and other 
neocortical areas. The dorsolateral circuit (DLC) fundamentally advances 
organizational capacity and decision weighing. 

Taking the clinicians stand, harm to these pathways can cause 
hyperperseveration, diminished capacity for deliberation, lack of moral and 
social etiquette, disabled verbal output, and destitute execution on complex 
figure replicating. According to Burruss et al., Brodmann areas 9 and 10 
contain neuron cellular bodies that correspond to the start and end of the 
dorsolateral circuitry. The neurons of this region project to the dorsolateral 
portion of the caudate nucleus, from which juncture they develop direct and 
indirect pathways which appear to have a reciprocal modulation mechanism 
via excitatory and inhibitory stimuli.  

With respect to the orbitofrontal circuit, it takes on the work of 
balancing satisfactory social behavior and is principal for keeping up 
sympathy. Disturbances within the pathways of this framework lead to 
certain neuropsychiatric admittances such as impulsivity, passionate lability, 



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shifts in personality, unstable behavioral tendencies, and need of 
interpersonal affectability. Like the dorsolateral circuit, the orbitofrontal 
begins in the tenth and eleventh Brodmann regions. Their axons project to 
the ventromedial parcel of the caudate nuclei, where they veer into a direct 
and an indirect path. 

The coordinate pathway enters the dorsomedial globus pallidus and 
the medial rostral area of the pars reticulata, where they proceed to the 
anterior parcel of the thalamus, after which coming back to the prefrontal. 
The circuitous pathway of the orbitofrontal circuit enters a feedback loop by 
connecting to the dorsal part of the external globus pallidus and to the 
sidelong subthalamic nucleus. The indirect track of the orbitofrontal 
regulates the direct one through the association to the dorsal part of the 
external globus pallidus and the horizontal subthalamic core. Both pathways 
go up next to each other next to dorsolateral circuitry (Mega & Cummings, 
1994). 

Remotely to this, the horizontal parcel of the orbitofrontal inputs 
afferences primarily from the temporal grey matter, the amygdala, and 
ventral tegmental region. Thus, the associations to the distal collateral ranges 
are also complementary, as it happens with comparative integrator pathways 
within the dorsolateral circuits. 

The anterior cingulate and its connections control incentive by 
tweaking downregulated input within the supplemental motor zone, using its 
own signals for keeping up the awake and alert state. The foremost apparent 
shortfalls of stops in the circuitry arranged within the prefrontal cortex are 
related with respective injuries of the front cingulate, the clinical signs being 
akinetic mutism, lack of concern, abulia, and no response to sensorial 
stimulation.  

Business Enough 

Phineas Gage, a seemingly healthy man aged 25 was a head railroad 
worker coordinating others who were building the train line from Rutland to 
Burlington in the United States of America. They were handling the clearing 
and leveling of the landscape when the gruesome mischance took place, on 
the 13th of September 1848, close to Cavendish. As they had done 
numerous times until then, Gage made a hole in the stone and packed 
gunpowder inside of it with a tamping iron. This is exactly the rod you can 
see in the picture next to this paragraph, as by mistake an explosion was 
caused by the friction inside the rock and the metallic object hit Phineas in 
the head. It passed through his left hemifacies and penetrated the front side 



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of his skull. He was urgently taken to a hotel in the city by his coworkers, at 
which point he was fully conscious and able to move without support of any 
kind. He retold the mindboggling story of the accident to Edward Higginson 
Williams, the first doctor to see him, and greeted him by way of: „Doctor, 
here is business enough for you”. 

Under Dr John Martyn Harlow’s attentive medical care, Gage was 
able to survive his injuries. What needed to be done firstly was to stop the 
massive haemorrhage and remove the remaining bone fragments from the 
affected area. In addition, by elevating Gage's head, Harlow allowed drainage 
at the sight of the wound. In the weeks after, the primary course of action 
was to treat the infection that followed the accident. Based on 19th century 
medical beliefs, Harlow made use of colchicum and mercury chloride for 
their cathartic properties as he tried to stop the inflammatory process from 
progressing. Almost 3 months afterwards, Phineas Gage’s physical state had 
improved significantly and he was declared cured.  

Two decades from the accident, dr Harlow managed to rebuild the 
chronology of what happened to his stellar patient between the fateful 
spring of 1849 and his demise. Following statements from his mother, it 
seemed that Gage had moved and found work in Chile for a long time, but 
eventually returned to his birthplace, where he ended up dying after a string 
of previously undiagnosed tonico-clonic convulsions and their 
complications. 

In November 1848, the same clinician that had helped Gage at the 
time of his impressive accident wrote a letter for the Boston Medical and 
Surgical Journal in which he described everything that happened and the 
medical challenges overcome. What followed after, as far as behavior and 
personality disorders go, was highlighted through a presentation entitles 
„Recovery from the passage of an iron bar through the head”made by dr 
Harlow in front of the Massachusetts Medical Society”, in 1868: “The 
balance between his intellectual faculties and animal propensities, seems to 
have been destroyed. He is fitful, irreverent, indulging at times in the 
grossest profanity (…), manifesting but little deference for his fellows, 
impatient of restraint of advice when it conflicts with his desires, at times 
pertinaciously obstinate, yet capricious and vacillating, devising many plans 
of future operation, which are no sooner arranged than they are abandoned 
in turn for others appearing more feasible” (Harlow, 1868). 

In the years of Phineas Gage’s sustained wound, the brain was 
though to be a homogenous jelly-like substance with no specific capabilities. 
This have only later and gradually shifted, as advances in the understanding 
of functionality and anatomy of the cortex were made at quite a fast pace. 



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Paul Broca was one of the most prominent scholars with an avid interest in 
this topic, and he wrote his contribution in 1861, when he put brain areas 
and their targeted function under the limelight. His anatomy focused studies 
were carried on two patients with loss of verbal acuity and expressivity, and 
it was demonstrated this was in connection to injuries sustained of the left 
frontal lobe, on the third ridge. The link between cognitive exercise and a 
specific cerebral region was thereafter widely accepted and acknowledged by 
the scientific community. 

 
David Ferrier was one of the frontrunners studying cortical 

localisation fo function. He managed to draw a precise motor and sensory 
map of the cortical processes through the removal of some cerebral tissues 
and by using alternate electricity as stimulus. At the same time, Ferrier 
surgically extirpated a substantial part of the prefrontal cortex of 3 monkeys. 
Not even a single one presented with changes in their motricity, sensory or 
perceptual process (Bolos et al., 2012; MacFall et al., 2001). The story of 
how neuroscience began to delevop starts therefore in the functional 
consequences of frontal cortex injury, as  Phineas Gage and his medical 
revolution shows. 

The Frontal Lobe Amidst Psychotic Symptoms 
An essential symptom of schizophrenia is represented, as we all 

know, by the delusions and hallucinations progressively lowering an 
individual’s quality of life. This is a form of functional mishap of the frontal 
cortex which, according to recent studies, has been negatively correlated 
with the gray matter volume of the lobe. The decreased dopamine release 
activation in the dorsal and lateral prefrontal part has been noted in 
connection to this (Chirita et al., 2012). 

The behavioral pattern this lobe is heavily involved in is that of 
suicidal ideation, which is a severe symptom of psychotic disturbances and 
can be unequivocally attributed to the dysfunctionality of prefrontal 
circuitry. Patients suffering from this perceptual disorder have decreased 
controlling feedback in their premotor cortex, and lowered response to goal-
driven actions in multiple areas, but usually on the same side with the 
primary motor cortex.  

Fractional anisotropy is another guidance in schizophrenic 
symptoms’ correlation to functional neuroanatomy. This is reduced in the 
left anteromedial orbitofrontal cortex, anterior cingulate and bilateral 



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posterior projections. Higher percentages of abulia, apathy or anhedonia 
were seen in cases with changes in the left posterior cortical connections. 

A smaller volume of grey matter in the prefrontal region has been 
shown to relate to impaired advanced functioning and the duration of the 
disorder has a direct proportionality relationship to the area modified. With 
this comes a lowered metacognitive insight as well as changes to the 
putamen, insula, the left ventrolateral prefrontal and right dorsal prefrontal 
cortex. The white matter fasciculi suffer shifts as well, being decreased in 
volume as well, especially in the corona radiata, forceps minor and superior 
longitudinal pathways. On the cellular level, schizophrenia leads to a smaller 
number of spinal radiations and shorter length of each dendrite. At the same 
time there appears a turnover of pericapillary oligodendrocytes in the 
prefrontal cortex of patients, which might as well highlight new study 
directions in the pathophysiology of neuronal psychotic disturbances. 

In recent years, neuroscientists have tried various ways of focusing 
on the connections between executive functionality and psychosis in the 
detailed cortical sense, and so made use of any means possible to understand 
the disturbances found (Mubarik & Tohid, 2016). For example, using a 
technique called BOLD RM (blood oxygen level dependent), it was noted 
that the blood supply to the prefrontal cortex in schizophrenic patients is 
significantly lower than in healthy controls, with OxyHB standing proof to 
the progression of illness. This has a positive proportionality relation to the 
degree in severity of the psychotic symptoms and shows a greater measure 
of hypofrontality (Lim et al., 1999).  

Loss of Control Mirrored by the Frontal Systems 

Even in the 19th century reports were given that frontal lobe injuries 
could lead to an acute onset of antisocial traits in the patient, being 
associated with impulsivity, explosive outbursts, inappropriate actions or 
verbal cues, while the basic functioning of cognition, and motricity remain 
relatively spared. In adult age there was a term coined for individuals 
suffering from prefrontal lesions – „acquired sociopathy” – showcasing a 
minimum of impaired executive functionality but important inability towards 
palpable tasks requiring judgement calls, being morally and socially aware 
and having the capacity to predict outcomes before taking actions 
(O'Driscoll & Leach, 1998). In almost the same manner, patients who 
suffered frontal circuitry damage at a young age, report recurrences of 
impulsivity, aggresiveness and comitting antisocial acts, as well as a 
dysfunctionality of primary cognitive functions, poor abstract or 



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conceptualized thinking, lacking in empathy and moral naivety to a variable 
extent upon reaching adulthood. 

Frontal abnormal findings were brought up by both the 
morphometric and brain imaging studies of impulsive individuals. One study 
focusing on volumetry on MRI brain scans compared an antisocial behavior 
individuals group with substance abusers, psychiatric and healthy control 
groups. The most important differences could be structured into three tiers: 
more aggressive antisocial actions, better highlighted psychopathic traits, and 
low overall prefrontal grey matter volume (Goghari et al., 2015). These were 
much more accentuated in the antisocial personality disorder group than in 
any of the others. With regards to the substance misusers, it was shown that 
alcohol dependent subjects who also displayed personality traits of abuse 
and impulsivity had comparatively greater frontal hypoperfusion than those 
with no antisocial tendencies (Haukvik et al., 2013).  

 
Forensic patients were paralleled to a healthy control group 

throughout a number ot PET brain scan studies. The positron emission 
tomography showed a decrease in the bloodflow and metabolic reactions 
brought on by thoughtless abusive behaviors repeated a number of times. 
The lower anteromedial and left orbitofrontal metabolism in individuals with 
personality disorders such as narcissistic or border, was connected to higher 
levels of aggressive actions using standardized scales (Slifstein et al., 2015). 

When evaluating violent patients, the neuropsychiatrist should pay 
attention to the clinical findings on frontal lobe impairment and assesing of 
their high executive functionality, especially when the situation surrounds a 
pattern of recurrent impulsivity and abuse. In order to advance in this field 
of study, need arises for a multidisciplinary approach that can bring together 
psychological techniques, neurology issues, and physiological changes for the 
in depth understanding of localised functionality of the brain, especially in 
areas such as emotion processing, social adaptability and higher cognitive 
capabilities. 

Conclusions 

The human brain was built indeed to tell stories. What kind of 
stories, and for how long will we go on without understanding them is 
anyone’s question. If one sits still enough, one can decipher the going ons 
inside their mind. This is a precious but fleeting sensation we should struggle 
to explain more clearly. 



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As psychiatrists we are indebted to the world of neurosciences and 
obliged to measure our strength in front of technologically advanced systems 
that can guide us and bring us valuable information on the state of 
functionality of the cerebral cortex. CT scans, MRI with added BOLD 
contrast techniques, tractography, are but a few of the widely used tools that 
aid us in gathering pivotal data to research the mind wavelength. 

In keeping up with advancements in the field, while understanding 
where we came from, we explore innovative trajectories that not only shade 
new light on cognitive functionality, but improve outcomes in the clinical 
setting. Whether we try to understand the phase of the psychotic narrative 
our patient finds himself in, or adjust medications accordingly to the state of 
receptoral disponibility, imaging techniques and metabolic measurements are 
the new musts for a better quality of life. 

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