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Neurological
Basis of Behavior (PSY -
610)
VU
Lesson29
Basic
Neuroanatomy
Objectives:
The
main objective of this lesson is to study
·
The
Brain and the Peripheral systems:
·
Brain:
Forebrain, Mid brain, Hind Brain functioning of each anatomical location in the
CNS.
Starting
from the posterior located areas upto the anterior-most.
·
Cerebral
Cortex: its layers, Corpus Callosum and the two hemispheres
Main
purpose:
Students
will come to relate the
importance of location of various
areas in the Diecephalon and
the
Telencephalon,
their functions and their
relationship to other areas.
The students would also
understand
how
control and modulation of
behavior related to these
neuroanatomical site takes place
Diencephalon:
This
comprises of two major areas of the brain both equally important in their
functions and their
involvement
in a wide range of behaviors and connection, the hypothalamus and the
Thalamus
Hypothalmus:
it
lies at the base of the brain, on both sides of the 3rd ventricle. It is very small in size a
compared
to other brain areas but is very important in it s role and function.
Hypothalamus is located
immediately
beneath the thalamus and lies above the pituitary.
Hypothalamus
is part of the Limbic
system, and in all situations
requiring a fight-flight or other
survival
responses. There are several important fibre bundles passing through the
hypothalamus,
including
the-MFB Medial
forebrain bundle which carries major
neurotransmitters along with other
fibers
to the higher areas.
Underneath
the hypothalamus lies the superchiasmatic
nucleus (SCN). The SCN plays an
important
role
in the day night cycles i.e. diurnal cycles. Within this region we also see the
mammiliary bodies
which
are important in memory.
The
hypothalamus also secretes its own hormones which act as releasing factors for
hormonal secretions
in
the pituitary. The neurosecretory cells of the hypothalmic hormones are located
near base of
hypothalamus,
very close to the pituitary. Therefore hypothalamic-pituitary connection is
important for
the
neural and endocrinal connections. The brain talks to the pituitary through the
hypothalamus, and
vice
versa. All the endocrinal glands communicate for fear aggression,
temperature regulation, food
and
water, and mating. The Anterior hypothalamus is important in thrist regulation
and there are
important
sensors which continuously monitor fluid (and isotonic saline levels) of
neurons. The
Ventromedial
(VMH) and Lateral Hypohtalamus (LH) are involved in regulation of feeding.
Research
has
shown that the VMH is the satiety center (have- enough- food -stop -signal), and
the lateral
hypothalamus
is the center for initiation of feeding. Hypothalamus important in all major
survival and
maintenance
functions; it is related to the management functions of the body and survival
rather than
intellectual
functioning.
Thalamus:
this
is the largest component of Deincephalon with an ovalish shape; it has two
lobes
which
are connected by the mass intermedia which go through the midline of the third
ventricle.
The
thalamus comprises of large clusters of nuclei. The thalamus is a staging area,
information
received
from sensory receptors systems and other lower areas and then it is projected to
the
relevant
cortical areas. 1. Sensory relay nuclei: All afferent sensory input are received
classified,
sorted
and the passed through the thalamus, these go from the receptor to the Thalamus
which then
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Neurological
Basis of Behavior (PSY -
610)
VU
sends
the selected projections to the related cortices. The Visual, auditory input
goes through the
lateral
geniculate nuclei and the medial geniculate nuclei, and somatosensory sensory
fibers go to
the
somatosensory cortices. There is a reciprocal one to one relationship of these
connections in the
cortex.
If one fiber degenerates in the cortex, it would lead to atrophy of the relevant
thalamic areas.
The
Dorsal group of fibers is multimodal (that is it receives and sends input to
different sensory
areas).
This receives input from within the thalamic regions, and project to the
association cortex.
There
is another group of fibers in the thalamus the Intrinsic or the non-specific. If
this area is
stimulated
it leads to wide spread electrical discharge in the cortex and other areas,
evidence that
this
bundle is important in electrical activity of the cortex. It is involved in
sleep awakening as well
as
attention. It is also important in affective behavior, memory (there is severe
amnesia after lesions
to
midline thalamic area). Thus the thalamus is important in every aspect of
behavior
Telencephalon:
The
End brain comprises mainly of the areas of the cerebral cortex and some parts
of
the
Corpus striatum, the limbic system. The two hemispheres of the cerebral cortex
and the other parts
are
connected to each other by commissures (bands of fibers connecting the left and
the right
hemispheres).
Corpus
Callosum is the major band of
fibers joining the two hemispheres it is wide, white and
visible
to the naked eye. The commisures are mainly for interaction between the two
hemispheres
and
for crossing over of information (so that the two hemispheres acna coordinate
decisions).
Cerebral
Cortex: (cortex means outer
covering: bark of the brain). This is made up of layers of
grey
matter which covers the white matter. The thickness of the cerebral cortex
varies from 1.5 to
4.5
mm; the average is about 2.00 mm. It is thickest in the primary motor cortex
about 4.5 mm thick
and
thinnest about 1.5 mm at the primary visual cortex. It is laid out in a straight
line; the total
surface
of the cerebral cortex would be about 20 sq.foot. How does this fit into the
cranium, it is
sqeezed
into folds. These folds are irregular convulations and grooves called sulci (for
smaller size)
and
fissures (for large sized). The area lying between two fissures is called gyrus
and there is 2/3rds
of
the cerebral collosum is these gyri. The two major fissures which are used as
the
dividing/identifying
borders are the Central fissure or the Fissure of Rolando separates the
Frontal
from
the Parietal Lobe and Temporal Fissure (or the Sylvian fissure) which separates
the Frontal
from
the Temporal Lobe. The Central Fissure divides Cerebral Cortex into the
anterior-posterior
(frontal
parietal).
There
are several types of cortices the neo
cortex- the newly evolved
areas of cortex, and the
allocortex
-
the older cortex
The
allocortex or the paleocortex (/archicortex) is a three layered older cortical
structure subdividied
into
the apleo cortex and the archicortex. These two have very close ties with the
kinbic system and
the
olfactory system.
Paleocortex:
(Have
the primary olfactory cortex
and other areas)
Archicortex
(consists
of the hippocampal formation) this is
similar to the human cerebral cortex
in
terms
of a) connections b) characteristics, c) kinds of
neurons found in these
areas.
Mesocortex:
the
middle cortex is found in the
cingulate gyrus, parahippocampal
areas and also between
the
iso cortex and the
allocortex
Neocortex:
the
new cortex, the iso cortex,
consists of 6 layers which are more
recent evolution:
organized
in one-one: incoming in specific areas.
Outgoing in others, association cortex
takes care of
higher
order functions
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Neurological
Basis of Behavior (PSY -
610)
VU
The
higher the evolutionary scale, the
greater the neocortical development to
the extent that in
humans
where
cortical development is maximal,
90% of the cortex is neocortex. In the
primitive or less
developed
animals the cortical surface is smooth,
whereas in the more evolved and
sophisticated
animals
the surface is rough and convulated. In
rats the cortical surface is
relatively smooth, in the
squirrel
monkeys it is somewhat rougher and the
cortex of the chimpanzees and humans
increase in
convulations.
In humans, rhesus monkeys or chimpanzees
have a very large disproportionate,
rough
surface
of the cerebral cortex.
The
cortex is organized in a one-to-one
manner a) incoming information
goes to specific areas (
most of
the
cortex is receiving information) b)
Outgoing information is sent
out from motor cortex and
other
relevant
areas ( visual information
sent out by visual cortex)
c) Association cortex takes place of
other
important
and higher order
functions.
Lobes
of the cerebral Cortex:
Frontal
Lobe: lies
rostrally to the Central fissure, and
caudally to the precentral fissure are
the primary
motor
area. The primary motor
area is most important in movement of the
body. The motor
homunculus
is
the dictionary of motor movements, where
each motor movement and muscle is
mapped. The body
parts
are represented in well
defined but a disproportionate manner.
For, example the tongue and
the
thumb
gets greater representation as compared to the
body torso and the extremeties (
depending on the
evolutionary
importance of the areas) Electrical
stimulation of specific areas in
the primary motor
cortex
leads
to movement in the contralateral area of the
body, and lesions lead to
contralateral paralysis ( as
in
stroke). Rostral to the precentral
sulcus is the premotor area;
this is involved in initiating of
a
movement
and changes in the already ongoing
movement. Rostral to premotor is the Bordmanns
area 8
which
is has the frontal eye fields,
(for conjugate eye movements). There
are other important areas
such
as
the Brocas area which is
important in speech articulation and
production. If this area is
lesioned it
leads
to aphasia.
Parietal:lies
caudally ( behind) the central
sulcus, and primary somatosensory
cortex is located here.
The
sensory homunculus is mapped in the same
manner as the motor humonculus (not in
proportion to
the
size of the body part, but
in direct proportion to the needs).
Stimulation of the areas leads
to
sensations
of tingling and numbness in the
contralateral part. The
parietal lobe is also
involved in the
behavioral
interaction of individual with the
space around him. If
lesioned these lead to
sensory neglect
of
contralteral space (e.g. the patient
would shave contralteral
half of face, eat half the
plate, and not
respond
to chairs and tables in contralateral
half of damage). The
parietal is also involved in
object
recognition,
and language comprehension.
Temporal:
lies
caudal to the lateral gyrus in the
superior area and is primary
auditory cortex,
Wernicke's
area important for speech
comprehension. The spoken language is comprehended
here.
In
the inferior temporal lobe, the
perception of visual form
and color is located (this
is in the close
vicinity
of the occipital and the parietal
lobes.
Occipital
Lobe: The
primary and secondary visual
cortex visual processing is
carried out here. This
is
laid
out in very well organized
layers, in Brodmanns areas 17,
18, 19. This is the striated
cortex, i.e. the
layered
cortex, where both the left
and the right eye images get
represented in these layers. Hubel
and
weasel
have identified coular dominance
columns.
Cytoarchitectonics:
The
cellular architecture of the cerbal cortical layers.
There are six layers in
which
cortex
can be divided (not on an
all or none basis), but it is
mainly in terms of the organization of
cell
layers.
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Neurological
Basis of Behavior (PSY -
610)
VU
Table:
Layers of cerebral cortex
Lay
Cytoarchitecture,
network
Area
Order
of
er
name
migration
I
Molecular
layer
Fibers
going in a Primary area
for Oldest (cellular)
network
fewer
synapses
interneurons
and glial
cells
granular
Dense packing of small
Dendrites of the 5th wave of
II
External
layer
and
medium pyramidal
pyramidal
neuronal
cells
and interneurons project to layer 5
development
from
other layers.
and
other
extensions
go
deeper
Pyramidal
cells which Dendrites send
4th wave of the
III
External
Pyramidal
to
neuronal
(
medium and large)
increase
in size as the extensions
layers
1, axons migration
cell
layers deepens
extend
to other
deeper
layers in
the
same and
contralateral
hemisphere
densely
3rd wave of
granular
Pyramidal cells are
Most
IV
Internal
densely
packed. There is packed, project
neuronal
layer
and
stellate and granular to
deeper layers, migration
(
pyramidal
cells
terminating in this
thalamocortical
granular)
fibers
end here
layer
Large
and medium sized Lowest
density 2nd wave of
V
Internal
Pyramidal
pyramidal
stellate cells. as cells sends
neuronal
Betz
cells ( apical out
projections migration
to
other areas.
dendrite)
VI
Multiform
layer
Varying
shapes and
1st
wave of
sizes
short axons and
neuronal
dendrites
migration
·
The
first layer contains cells with
horizontal fibres and
horizontal cells of Cajal
·
Granule
cells- Short branching axons
and amny dendritic
branches
·
Pyramidal
cells shaped like a pyramid,
send axons to layers below
cortex. They also have
long
Apical
dendrite which extend to
other layers ( and even down to the
spinal cord) therefore a
bigger
cell
body is need to energize the cell to
send messages out for
longer extensions and carry
messages
effectively.
Cerebral
Cortex: Two Lobes
There
are two independent lobes
connected with the commissures.
Many researchers have worked
on
the
question do we have two brains or one.
Are there two independently
functioning brains or do they
coordinate
as one. Research by Gazzaniga, Milner,
Sperry and others has shown
that the two
hemispheres
are specialized for different
functions, Speech in left
hemisphere (first identified by
Broca)
and
spatial functioning in right
hemisphere. Milner carried
out the WADA TEST on patients, in this
test
one
side of the brain is anesthetized
with slow infusion of sodium
amytal through the carotid
artey
(major
artery of the brain). It was
reported by Milner that all
right handed persons have left
hemisphere
speech
dominance (92%), as their speech
stopped with the anesthetization of the
left hemisphere.
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Neurological
Basis of Behavior (PSY -
610)
VU
There
are specific disorder known
as Aphasias, which are language and
speech disorders with
left
hemisphere
damage
The
Apraxias are movement disorders which
occur when patient is required to
perform on a verbal
command
and fails to do so, even though
spontaneously it can be performed.
(Additional
references, Graham 735, Gazzaniga, Pinel, Kolb and Wishaw)
In
order to explain the cerebral differences, there are several theories of
cerebral asymmetry: Levy
and
Sperry state that there are two basic modes of thinking: the analytical
(LH)/synthetic and the
(RH)
more gestalts more organized therefore the neural circuitry is differently
wired.
Both
hemispheres are equipotential upto two years states Lenenberg, that each
hemisphere can take
on
any role of specialization. However, Kinsberg states that each child is born
with specialized
functions
of the two hemispheres (the planum temporale, in the temporal lobe is large in
the left side
in
the fetus)
The
research is ongoing and continues to this day to identify the specializations
and roles of the two
Hemispheres.
The
complexity of the cerebral cortex and
that of the mysteries of how
each neuron adds up to
the
behaviours
we exhibit are an interesting
ongoing journey.
References:
1.
Kalat J.W (1998) Biological
Psychology Brooks/ Cole
Publishing
2.
Carlson N.R. (2005) Foundations of
Physiological Psychology Allyn and Bacon,
Boston
3.
Pinel, John P.J. (2003)
Biopsychology (5th edition) Allyn and Bacon
Singapore
4
Bloom F, Nelson and Lazerson (2001),
Behavioral Neuroscience: Brain, Mind and
Behaviors (3rd
edition)
Worth Publishers New
York
5.
Bridgeman, B (1988) The
Biology of Behaviour and Mind. John
Wiley and Sons New
York
6.
Brown,T.S. and Wallace.(1980) P.M
Physiological Psychology
Academic
Press New York
Note:
References
2, 3, 4, 7 more closely followed in
addition to the references cited in
text.
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