Chapter 3
PHYSIOLOGICAL BASES OF HUMAN BEHAVIOR
INTRODUCTION
Organism
as diverse as humans and other creatures share many biological processes.
However, their unique behavioral capacities depend on the differences in their
physiological make- up.
You
and I have a larger repertoire of behavior different from the other grades of
beings because we come equipped with a more complex brain and nervous system.
The activity of the human brain is so complex that no one has ever come close
to duplicate it.
Your
nervous system contains many cells that are busy integrating and relaying
information. This could be the reason why many psychologists dedicated their
time in exploring the biological bases of human behavior (Weiten, 2008).
In
this section, we take a closer look at the communication in the nervous system.
NERVOUS TISSUE: The Basic Hardware
Your
nervous system is a living tissue composed of cells. The cells in the nervous
system fall into two major categories: GLIA AND NEURONS or NERVE CELL.
Neuron
It is the
individual cells in the nervous system that receive, integrate and transmit
information. The basic unit of the
nervous system is of differing shapes, sizes and function. There are
approximately trillion of neurons throughout the body which primarily involved
in the control of body activities and behavior.
Parts of Neuron
CELL BODY/SOMA - contains the
nucleus which provides nourishment
and insulation.
DENDRITES- receive signals
from the neighboring neurons and carry them back to the cell body.
AXONS- relatively longer
than the other neurons which carries
messages to the other neuron. Axons terminate in small bulges called TERMINAL BUTTONS that send messages to other neurons.
Myelin sheath- these are fatty
tissues and proteins surrounding the axons. It prevents interference from
electrical signals generated in adjacent axons. You may have heard that the
brain consists of the gray and white matter. Gray is the color of the cell
bodies and white is the color of myelin sheaths.
Kinds
of Neuron According to Speed
Impulses
in the fastest neuron move at a rate of 110 meters per second; in the slowest,
0.5 meters per second. The speed of condition is matched by the thickness of
the myelin sheath. The more myelin sheath, the faster the conduction. (Kahayon,
2004)
Kinds
of Neuron According to Basic Function
- Sensory (Afferent neurons)- conveys information from the body’s sense organs to the brain and spinal cord. This is initiated by the receptors- specialized cells in the sense organs, muscles, skin and joints that detect physical or chemical changes and convert these into impulses that pass along the sensory neurons.
- Motor (Efferent neurons) carry impulses away from the brain and spinal cord to the reacting organs, the muscles and glands.
- Association/Interneurons- connect the neurons together and and combine the activities of the sensory and motor neurons.
GLIAL CELLS- (Greek word “glia”
means glue) these are the non-neural cells that surround the neurons and ensure
that it can perform its functions while holding them in place.
When
the neural impulse reaches an axon’s terminal buttons, it triggers the release
of chemical messengers called neurotransmitters. The neurotransmitter molecules
diffuse across the synaptic cleft and binds through receptor sites on the
postsynaptic neuron. A specific neurotransmitter can bind only to receptor
sites that its molecular structure will fit into, much like a key must fit the
lock (Weiten, 2008).
HOW THE NEURONS
FIRE
ALL-or-NONE-LAW
The
firing of neurons occurs at either in full strength or not at all. After each
firing, the neuron needs time to recover called the refractory period. During
this period, action potential is much less likely to occur ( Miranda, 2008).
Various
neurons transmit impulses at different speeds. Most often, thicker axons
transmit neural impulses faster than the thinner ones.
RESTING STATE
This is the state of the neuron when not
firing a neural impulse and when the message arrives, gates in the cell membrane
open briefly to allow positively charged ions to rush in rates as high as
100million ions per second (Feldman, 2010).
ACTION POTENTIAL
This
is the time when there is a release of the neural impulse consisting of a
reversal of the electrical charge within the axon. After it has occurred, the
neuron cannot fire again no matter how much stimulation it receives.
THE SYNAPSE: SENDING THE MESSAGE TO OTHER
CELLS
Two
neurons do not actually meet. They are separated by the synaptic cleft which is
a microscopic gap between the terminal button of one neuron and the cell
membrane of another neuron.
In
this situation, the neurons that send a signal across the gap is called pre-synaptic
neuron and the neurons that receive the signals is called the post-synaptic
neuron.
NEUROTRANSMITTERS: MESSENGERS OF THE
NETWORK
These
are chemicals that carry messages across the synapse or cell body of a
receiving neuron.
It
may vary on how intense its concentration that can cause a neuron to fire when
it is secreted in one part of the brain and can inhibit the firing of neurons
when it is produced by another part (Apruebo, 2009).
Miranda (2008) presented the five
key neurotransmitters according to location and functions.
Neurotransmitter
Functions
|
Location
|
Functions
|
1. Acethylcholine
|
Brain, spinal cord
ANS, selected organs
|
Releases at neuromuscular junctions;
involved in memory
|
2. Norephinephrine
|
Brain, spinal cord, selected organs
|
Regulates physical logical arousal;
learning, memory and emotion
|
3. Dopamine
|
Brain
|
Linked to muscle activity, emotional
arousal, learning memory
|
5. Gamma Amino
|
Brain, Spinal cord
|
Involved in motor behavior and arousal
Butyric Acid (GABA)
|
ORGANIZATION OF THE NERVOUS SYSTEM
It
is important to understand the organization and functions of the nervous system
and its mutually dependent systems and divisions.
A. 
Central Nervous System (CNS): Brain-Spinal
Cord
Central Nervous System (CNS): Brain-Spinal
Cord
BRAIN-
Protection: Skull SPINAL
CORD-
Protection: Vertebrae
B. Peripheral Nervous System (PNS): Extension of CNS
Somatic System Autonomic
System
Reacts to outside stimuli Maintains
homeostasis
 |
|||
Sympathetic System Parasympathetic System
Response:
Involuntary Response: Normal
 |
 |
THE PERIPHERAL NERVOUS SYSTEM
It
is made up of all those nerves that lie outside the brain and spinal cord. The
peripheral nervous system can be divided into somatic nervous system and the
autonomic nervous system.
The Somatic Nervous System
This
is made up of nerves that connect to voluntary skeletal muscles and to sensory
receptors. These nerves are the cables that carry information from receptors in
the skin, muscles and joints to the central nervous system to the muscles.
These functions
require two kinds of nerve fibers:
ü AFFERENT nerve
fibers are axons that carry information inward to the central nervous
system from the periphery of the body.
ü EFFERENT nerve
fibers are axons that carry information outward from the central nervous system
to the periphery of the body (Weiten, 2009).
The Autonomic Nervous System
It
is concerned with parts of the body that keeps us alive- the heart, blood
vessels, glands, and other organs that operate involuntarily without our
awareness.
The
autonomic nervous system mediates much of the physiological arousal when people
experience emotions. Based on the above discussion, it is divided into
sympathetic and parasympathetic division.
The Sympathetic Division
It
is primarily located on the middle of the spinal column—running from near the
top of the ribcage to the waist area. It
is usually called as the “fight-or-flight system” because it allows people and
animals to deal with different kinds of stressful events. Emotions
during these events might be anger (hence, the term fight) or fear (the
term flight, obviously) or extreme joy and excitement. Yes, even joy can be
stressful. The sympathetic division’s job is to get the body ready to deal with
the stress (White, 2009).
The Parasympathetic Division
If
the sympathetic division can be called the fight-or-flight system, the
parasympathetic division might be called the eat-drink-and-rest system.
The neurons of this division are located at
the top and bottom of the spinal column, on either side of the sympathetic
division neurons (para means “beyond” or “next to” and in this sense
refers to the neurons located on either side of the sympathetic division
neurons).
The
parasympathetic division’s job is to restore the body to normal functioning
after a stressful situation ends. It slows the heart and breathing, constricts
the pupils and reactivates digestion and excretion.
Signals
to the adrenal glands stop because the parasympathetic division is not connected
to the adrenal glands. In a sense, the parasympathetic division allows the body
to put back all the energy it burned—which is why people are often hungry after
the stress is all over. It also functions on most ordinary, day-to-day
functioning such as regular heartbeat, normal breathing and digestion (White,
2009).
THE CENTRAL NERVOUS
SYSTEM
Brain
This is the true
core of nervous system. It takes information from senses, processes it, makes
decisions and sends commands to the rest of the body (White, 2009).
Modern Brain Scanning Techniques:
Providing Snapshots of its Internal Works
- Electroencephalogram (EEG)- records electrical activity in the brain through electrodes placed on the outside of the skull. The device is used to assess brain damage, epilepsy and other problems.
- Positron Emission Tomography (PET)- scans show the biochemical activity within the brain while hearing, seeing, thinking and speaking.
It measures the amount of glucose in
various areas of the
brain, and then sends this information to
a computer for
analysis.
- Functional Magnetic Resonance Imaging (fMRI)- scans provide a detailed, three-dimensional computer-generated image of the brain structures and activity by aiming a powerful magnetic field at the body. Through fMRI, it is possible to produce a vivid, detailed image of the functioning of the brain.
- Computerized/Computed Tomography (CT) scan- produces a three-dimensional image obtained from X-rays of the head that are assembled into a composite image by a computer. It provides valuable information about the location and extent of damage involving stroke, language disorder or loss of memory.
- Transcranial Magnetic Stimulation (TMS)- one of the newest types of scan. By exposing a tiny region of the brain to a strong magnetic field, TMS causes a momentary interruption of electrical activity. The procedure is sometimes called a “virtual lesion” because it produces effects analogous to what would occur if areas of the brain were physically cut. The enormous advantage of TMS, of course, is that the virtual cut is only temporary (Fedman, 2010,/Santrock,2005,/ White, 2009).
MAJOR PARTS OF THE BRAIN
A
human brain which can easily be held in one hand, weighs about 1,350 grams or 3
pounds, and has the consistency of a firm Jell-O. The brain is protected by a
thick skull and covered with thin, tough, plastic -like membranes.
If shot in the head, he may or may not die
depending on which area is damaged. For example, damage to an area in the
forebrain would result in paralysis, damage to an area in the midbrain would
result in coma but damage to an area in the hindbrain would certainly result in
death (Plotnik,et.al., 2008).
Let’s
begin to explore the brain by looking into the major areas: the forebrain, the
midbrain and the hindbrain.
The Hindbrain
It is located at
the skull’s rear, which is the lowest portion of the brain. The hindbrain has
three identified structures: the medulla, the pons and the cerebellum.
- Medulla- it controls some sensitive body functions such as breathing, heartbeat, blood pressure and body posture. Medulla begins where the spinal cord enters the skull.
- Pons- joining two halves of the cerebellum, this lies adjacent to it containing large bundles of nerves, the pons acts as neurotransmitter of motor information, coordinating muscles and integrating movement between the right and left halves of the body. It is involved in regulating sleep ( Feldman, 2010).
- Cerebellum- extends from the rear of the hindbrain, just above the medulla and behind the pons. It consists of two-rounded structures thought to play important roles in motor coordination (Santrock, 2005). It is also involved in several intellectual functions ranging from the analysis and coordination of sensory information to problem solving (Feldman, 2010).
The cerebellum is
also involved in performing timed motor responses such as those needed in
playing games or sports, and in automatic or reflexive learning, such as
blinking the eye to a signal which is called as classical conditioning (Plotnik
et al., 2008).
The Midbrain
It is located
between the hindbrain and the forebrain. It is an area in which many
nerve-fiber systems ascend and descend to connect the higher and lower portions
of the brain.
In
particular, the midbrain relays information between the brain and the eyes and
ears. The ability to attend to objects visually, for example, is linked to one
bundle of neurons in the midbrain.
Parkinson’s
disease, deterioration of movement that produces rigidity and tremors, damages
a section near the bottom of the midbrain (Santrock, 2005).
Two systems of the
midbrain that are of special interest:
Reticular Formation- diffused
collection of neurons involved in stereotyped patterns of behavior such as
walking, sleeping or turning to attend to a sudden noise.
Small groups of neurons that use the
neurotransmitter serotonin, dopamine and norepinephrine. Although these
two groups contain relatively few cells, they send their axons to a remarkable
variety of brain regions, perhaps explaining their involvement in high-level,
integrative factors (Santrock,2005).
The Forebrain
The forebrain is
the largest part of the brain, has left and right sides that are called
hemispheres.
The
hemispheres, connected by a wide band of fibers, are responsible for an
incredible number of functions, including learning and memory, speaking and
language, having emotional responses, experiencing sensations, initiating
voluntary movements, planning and making decisions (Plotnik et al., 2008).
THE
CEREBRAL CORTEX: Our New Brain
In
Latin, cortex means “cover” which is referred to as the new brain because of
its relatively recent evolution.
It
consists of a mass of deeply folded, rippled, convoluted tissue.
Although
only about one-twelfth of an inch thick, if flattened out, cover an area more
than two feet square (Feldman, 2010).
It
is the highest region of the forebrain where the highest mental functions, such
as thinking and planning takes place (Santrock, 2005).
The
cortex is divided into two hemispheres called CEREBRAL HEMISPHERES, which are
connected by a thick, tough band of neural fibers (axons) called CORPS CALLOSUM
(literally means “hard bodies” as calluses on the feet are hard (White, 2009).
The cortex has four
major sections called LOBES.
- Frontal lobe-(Broca’s Area) lies at the front center of the cortex; involved with personality, emotions and motor behaviors.
- Parietal lobe- area at the top of the head functions with perception and memory experiences; also involved in spatial location, attention and motor control.
- Temporal lobe- (Wernickes’s Area) found in the lower center portion of the cortex just above the ears which involved with hearing, language processing and memory.
- Occipital lobe- found at the back of the head which is involved with vision.
The
four sets of lobes are physically separated with deep grooves called SULCI.
There
are three main areas in the cerebral cortex: (1) the motor areas, (2) the
sensory areas, and (3) the association areas.
- Motor Areas- Located just behind the frontal lobes which are largely responsible for the body’s voluntary movement.
For example, the control movements that
is relatively large scale and
requires little precision, such as the movement of a knee or hip, is centered in a very small space in the
motor area.
In contrast, movements
that must be precise and delicate,
such as facial expressions and finger movements are controlled by a considerably larger portion of the
motor area. (Feldman, 2010)
- Association Areas- Areas within each lobe of the cortex is responsible for the coordination and interpretation of information as well as higher mental processes such as thought, language, memory and speech. (White, 2009).
- Sensory Areas- Areas of the cerebral cortex that includes three regions: (1) processes information about body sensations including touch and pressure, (2) relating to sight and (3) relating to sound (Feldman, 2010).
THE LIMBIC SYSTEM: Old Brain
The
limbic system (the word limbic means, marginal) and its structures are
found in the inner margin of the upper brain which includes the thalamus,
hypothalamus, and amygdale. In general, the limbic system is involved in
emotions, motivation and learning (White, 2009).
The
limbic system is often referred to as our primitive, or animal brain because
its same structures are found in the brains of animals that are evolutionarily
very old, such as alligators (Plotnik et al.,2008).
Thalamus (inner chamber)
The
part of the brain located in the middle of the central core that acts primarily
to relay information about senses (Feldman, 2010).
Hypothalamus (below the inner chamber)
The hypothalamus regulates
body temperature, thirst, hunger, sleeping and waking, sexual activity and
emotions. It seats right above the pituitary gland, which is called as the
“master gland” because it controls the functions of all the other endocrine
glands that will be discussed later in this chapter. ]
The
hypothalamus controls the pituitary, so the ultimate regulation of hormones
lies with the hypothalamus (White, 2009).
Hippocampus (Greek word for sea horse)
Curved
structure located inside the temporal lobe which is responsible for the
formation of long-term memories and the storage of memory for location of
objects (White, 2009).
Amygdala (almond)
It
is the area of the brain located near the hippocampus. Amygdala receives input
for all the senses.
It
plays a major role in evaluating the emotional significance of stimuli and
facial expressions, especially those involving fear, distress and threat
(Plotnik et al., 2008).
THE CHEMICAL CONNECTION: THE ENDOCRINE
GLANDS
Another body’s
communication system is the endocrine system. ENDORINE SYSTEM is a chemical
communication network that sends messages throughout the body via the
bloodstream (Feldman, 2010).
Glands
are organs in the body that secrete chemicals. Some glands, such as salivary
glands and sweat glands secrete their chemicals directly onto the body’s
tissues through tiny tubes, or ducts. This kind of gland affects the
functioning of the body but doesn’t really affect behavior.
Other
glands called ENDOCRINE GLANDS, which have no ducts and secrete their chemicals
directly into the bloodstream. The chemicals secreted by this type of gland are
called HORMONES (White, 2009).
A. Pituitary Gland: The Master of Hormonal
Universe (White, 2009)
Pituitary gland is
located in the brain itself, just below the hypothalamus.
It is called as the
master gland because it is the one that controls or influences all of
the other endocrine glands.
The
pituitary gland is divided into the anterior (front) and posterior (back)
sections.
·
Anterior Pituitary
It regulates growth
through secretion of growth hormones and produces hormones that control the
adrenal cortex, pancreas, thyroid and gonads.
·
Posterior Pituitary
The
rear portion of the pituitary gland that regulates water and salt balance
B. Pineal Gland (White, 2009)
Pineal gland is
also located in the brain near the back. It secretes hormones called MELATONIN,
which regulates the sleep-wake cycle.
C. Thyroid Gland (White, 2009)
The thyroid gland
is located inside the neck and secretes hormone called THYROXIN that regulates
metabolism.
D. Pancreas (White, 2009)
The pancreas
controls the level of blood sugar in the body by secreting INSULIN and
GLUCAGONS. If the pancreas
secretes too little insulin, it results in diabetes. If it secretes too
much insulin, it results to hypoglycemia or low blood sugar, which
causes a person to feel hungry all the time and often become overweight as a
result.
E. Gonads (White, 2009)
The gonads are sex
glands, including the ovaries in the female and testes in the
male. They secrete hormones that regulate sexual behavior and reproduction.
They do not control all sexual behavior, though. In a very real sense, the
brain itself is the master of the sexual system—human sexual behavior is not
controlled totally by instincts and the actions of the glands as in the animal
world but also by psychological factors such as attractiveness.
F. Adrenal Glands (White, 2009)
Everyone has two adrenal
glands, one on top of each kidney. By etymology, renal comes from the
Latin word meaning “kidney”, and ad is Latin for “to”, so adrenal
means “to or on the kidney”.
Each
adrenal gland is divided into two sections, the ADRENAL MEDULLA and the ADRENAL
CORTEX.
It is the adrenal medulla that releases ephinephrine
and norepinephrine when people are under stress and that aids in
sympathetic arousal.
The
adrenal cortex produces over 30 different hormones called CORTICOIDS (also
called steroids) that regulate salt intake, help initiate and control stress
reactions and also provides a source of sex hormones in addition to those
provided by the gonads.
One
of the most important of these adrenal hormones is CORTISOL, released when the
body experiences stress both physical stress (illness, surgery, or extreme heat
or cold) and psychological stress (such as emotional upset)
