Body Temperature PDF

Summary

This document discusses body temperature, covering aspects like normal temperature ranges, factors influencing temperature variations (age, sex, activities), the mechanisms of heat production and loss, and the role of the hypothalamus in temperature regulation. It also details how the body adjusts to maintain a stable core temperature.

Full Transcript

Body Temperature
Normal body Temperatures
Body temperature or Core temperature is the average
temperature of structures present in deeper part of the body;
it is always more than oral or rectal temperature. It is about
37.8°C (100°F) and it’s usually remains very constant, within
±1°F (±0.6°C), except when a person has a febrile illness.
The skin temperature, in contrast to the core temperature,
rises and falls with the temperature of the surroundings.
The normal body temperature in human is 37°C (98.6°F) when
measured by placing the clinical thermometer in the mouth
(oral temperature). It varies between 35.8°C and 37.3°C
(96.4° and 99.1°F).
 Variations of body temperature
Physiological Variations:
1. Age: In infants, the body temperature varies in
accordance to environmental temperature for the
first few days after birth. It is because the
temperature regulating system does not function
properly during infancy. In children the
temperature is slightly (0.5°C) more than in adults
because of more physical activities. In old age,
since the heat production is less, the body
temperature decreases slightly.
2. Sex: In females, the body temperature is less
because of low basal metabolic rate when
compared to that of males.
3. Diurnal variation: In early morning, the temperature is
1°C less. In the afternoon, it reaches the maximum
(about 1°C more than normal).
4. After meals: The body temperature rises slightly
(0.5°C) after meals.
5. Exercise: During exercise, the temperature raises due
to production of heat in muscles.
6. Sleep: During sleep, the body temperature decreases by
0.5°C.
7. Emotion: During emotional conditions, the body
temperature increases.
8. Menstrual cycle: In females, immediately after
ovulation, the temperature rises (0.5° to 1°C) sharply.
It decreases (0.5°C) during menstrual phase.
Heat Balance

 Regulationof body temperature depends upon
the balance between heat produced in the
body and the heat lost from the body.

 Heat gain or heat production in the body
The various mechanisms involved in the
production of heat in the body are:
1. Metabolic Activities: The major portion of heat
produced in the body is due to the metabolism of
food. Heat production is more during metabolism of
fat (about 9 calories/ liter). Then less calories of heat
is produced during carbohydrate metabolism (4.7
calories). Protein metabolism produces heat the less
of all (4.5 calories).
2. Muscular Activity: Heat is produced in the muscle
both at rest and during activities. During rest, heat is
produced by muscle tone. About 80% of heat of
activity is produced by the activity of skeletal
muscles.
3. Role of Hormones: Thyroxin (T4) and adrenaline
increase the heat production by accelerating the
metabolic activities.
4. Radiation of Heat from the Environment: Body
gains heat by radiation. It occurs when the
environmental temperature is higher than the body
temperature.
5. Shivering: Shivering refers to shaking of the body
caused by rapid involuntary contraction or twitching
of the muscles during exposure to cold.
Heat loss from the body
 Maximum heat is lost from the body
through skin and small amount of heat is
lost through respiratory system, kidney
and gastrointestinal tract. When
environmental temperature is less than
body temperature, heat is lost from the
body.
Heat loss occurs by the following methods:

1. Conduction: Only minute quantities of heat, about 3%,
are normally lost from the body by direct conduct from
the surface of the body to solid objects, such as a chair
or a bed. Loss of heat by conduction to air, however,
represents a sizable proportion of the body’s heat loss
(about 15%) even under normal conditions.
Once the temperature of the air adjacent to the skin
equals the temperature of skin, no further loss of heat
occurs in this way because now an equal amount of heat
is conducted from air to the body.
2. Radiation: 60% of heat is lost by means of
radiation, transfer of heat by infrared ray
(electromagnetic ray) radiation from body to
other objects through the surrounding air. The
human body radiates heat rays in all directions.
Heat rays are also being radiated from the walls
of rooms and other objects toward the body. If
the temperature of the body is greater than the
temperature of the surroundings, a greater
quantity of heat is radiated from the body than
is radiated to the body.
3. Convection: A small amount of heat
convection almost always occurs around the
body, about 15% of total heat loss occurs by
conduction to the air and then by air
convection away from the body. The heat
from the skin is first conducted to the air
and then carried away by the convection air
currents.
4. Evaporation – Insensible Perspiration:
Normally, a small quantity of water is
continuously evaporated from skin and lungs
(22%). So it is called insensible perspiration or
insensible water loss. When body temperature
increases, more heat is lost by evaporation of
more water.
Insensible evaporation through the skin and
lungs cannot be controlled for purposes of
temperature regulation because it results from
continual diffusion of water molecules through
the skin and respiratory surfaces.
Insulator System of the Body
The skin, the subcutaneous tissues, and
especially the fat of the subcutaneous tissues
act together as a heat insulator for the body.
The fat is important because it conducts heat
only one third as readily as other tissues. The
insulation beneath the skin is an effective
means of maintaining normal internal core
temperature, even though it allows the
temperature of the skin to approach the
temperature of the surroundings.
Blood flow to the skin from the body core
provides heat transfer
Blood vessels are distributed profusely
beneath the skin. Especially important is a
continuous venous plexus that is supplied by
inflow of blood from the skin capillaries. In the
most exposed areas of the body (the hands,
feet, and ears) blood is also supplied to the
plexus directly from the small arteries.
The environmental air temperature is affect
quantitatively on conductance of heat from the
core to the skin surface and then into the air,
an approximate eightfold increase in heat
conductance between the fully vasoconstricted
state and the fully vasodilated state.
Therefore, the skin is an effective controlled
“heat radiator” system, and the flow of blood
to the skin is a most effective mechanism for
heat transfer from the body core to the skin.
Detection of temperature by receptors in
the skin and deep body tissues
Although the signals generated by the temperature
receptors of the hypothalamus are extremely
powerful in controlling body temperature; receptors
in other parts of the body play additional roles in
temperature regulation. This is especially true of
temperature receptors in the skin and in a few
specific deep tissues of the body. The skin has far
more cold receptors than warmth receptors in fact,
10 times as many in many parts of the skin.
Therefore, peripheral detection of temperature
mainly concerns detecting cool and cold instead of
warm temperatures.
Deep body temperature receptors are found mainly
in the spinal cord, in the abdominal viscera, and in
or around the great veins in the upper abdomen and
thorax. These deep receptors function differently
from the skin receptors because they are exposed to
the body core temperature rather than the body
surface temperature. Yet, like the skin temperature
receptors, they detect mainly cold rather than
warmth. It is probable that both the skin and the
deep body receptors are concerned with preventing
hypothermia.
Regulation of body temperature
Role of sympathetic nervous system
 Heat conduction to the skin is controlled by the
sympathetic nervous system.
 Heat conduction to the skin by the blood is
controlled by the degree of vasoconstriction of the
arterioles and the arteriovenous anastomoses that
supply blood to the venous plexus of the skin.
 This vasoconstriction is controlled entirely by the
sympathetic nervous system in response to changes
in body core temperature and changes in
environmental temperature.
 Role of Hypothalamus in regulation of body
temperature
The temperature of the body is regulated almost
entirely by nervous feedback mechanisms, and
almost all these mechanisms operate through
temperature regulating centers located in the
hypothalamus. For these feedback mechanisms to
operate, there must also be temperature detectors
to determine when the body temperature becomes
either too high or too low. The set point under normal
physiological conditions is 37°C.
Hypothalamus has two centers which regulate
the body temperature:
1- Heat loss center- Anterior Hypothalamic-
Preoptic Area
2- Heat gain center- Posterior Hypothalamus.
Heat loss center- Anterior Hypothalamic-
Preoptic Area
This center is situated in preoptic area of anterior
hypothalamus and contains large numbers of heat-
sensitive neurons, which are called thermo-
receptors, as well as about one third as many cold-
sensitive neurons. These neurons are believed to
function as temperature sensors for controlling body
temperature. Stimulation of preoptic area results in
cutaneous vasodilatation and sweating. Therefore, it
is clear that the hypothalamic-preoptic area has the
capability to serve as a thermostatic body
temperature control center.
 Heat gain center- Posterior Hypothalamus

It is otherwise known as heat production center, it is
situated in posterior hypothalamic area. Stimulation of
posterior hypothalamus causes shivering. The
temperature sensory signals from the anterior
hypothalamic preoptic area are also transmitted into
this posterior hypothalamic area. Here the signals from
the preoptic area and signals from elsewhere in the
body is combined and integrated to control heat-
producing and heat-conserving reactions of the body.
Figure: Response of hypothalamic
thermoregulatory center to temp. change
(Sympathetic cholinergic &adrenergic
neurons)
Mechanisms that decrease or increase body
temperature

 When the hypothalamic temperature
centers detect that the body temperature
is either too high or too low, they institute
appropriate temperature-decreasing or
temperature-increasing procedures:
 Temperature-decreasing mechanisms when
body temperature increases
 When body temperature increases, blood
temperature also increases. When blood with
increased temperature passes through
hypothalamus, it stimulates thermoreceptors
present in the heat loss center in preoptic area.
Now, the heat loss center brings the
temperature back to normal by promotion of
heat loss and prevention of heat production
through theses mechanisms:
1. Heat loss center promotes heat loss from the body
by:
A- Vasodilation of skin blood vessels- In almost all
areas of the body, the skin blood vessels becomes
extremely dilated. Full vasodilation can increase the
rate of heat transfer to the skin as much as eightfold.
B- Increasing the secretion of sweat- When sweat
secretion increases, more water is lost from skin along
with heat.
2. Decrease in heat production- The mechanisms that
cause excess heat production, such as shivering and
chemical thermogenesis, is strongly inhibited.
 Temperature-increasing mechanisms when
body temperature decreases

 When the body is too cold, the temperature
controls system institutes exactly opposite
procedures, it is brought back to normal by
prevention of heat loss and promotion of
heat production through theses
mechanisms:
1. Prevention of heat loss by Skin
vasoconstriction throughout the body-
This vasoconstriction is caused by
stimulation of the posterior hypothalamic
sympathetic centers, (when body
temperature decreases, the preoptic
thermoreceptors are not activated). The
blood flow to skin decreases, and so the
heat loss is prevented.
2. Increase in thermogenesis (heat
production) by two ways:
A- Shivering: The primary motor center for
shivering is situated in posterior hypothalamus.
When body temperature is low, this center is
activated by heat gain center and, shivering
occurs. Enormous heat is produced during
shivering due to severe muscular activities.
B- Increased metabolic reactions: The
sympathetic centers, which are activated by heat
gain center, stimulate secretion of adrenaline and
noradrenaline. These hormones, particularly
adrenaline increase heat production by
accelerating cellular metabolic activities. At the
same time, hypothalamus secretes thyrotropic
releasing hormone (TRH). It causes release of
thyroid stimulating hormone (TSH) from pituitary.
It in turn increases release of thyroxin (T4) from
thyroid. T4 accelerates the metabolic activities in
the body and increases heat production.
Sympathetic “Chemical” Excitation of heat
production
 An increase in either sympathetic stimulation
or circulating adrenaline and noradrenaline in
the blood can rapidly increase the rate of
cellular metabolism. This effect is called
chemical thermogenesis, or non-shivering
thermogenesis.
 Chemical thermogenesis: It is the process in
which heat is produced in the body by
metabolic activities induced by hormones.