Human Body Function (HBF) 102 Lecture 1 PDF

Summary

This lecture covers the concept of homeostasis, physiologic control mechanisms, and feedback mechanisms in the human body. The lecture also discusses positive and negative feedback examples, and their roles in maintaining the internal environment.

Full Transcript

Faculty of
Medicine

Academic Year: 2024-2025
Year: 1 Semester: 1
Module: Human Body Function (HBF) 102
 Physiology of
Homeostasis
By: Dr. Mohamed abo el hassan
Dr. Ramadan Saad
Department: Physiology
11/8/2024 2
 Objectives

oDefine and discuss the concept of homeostasis and its
importance to the living organism.
oDiscuss the physiologic control mechanisms that
enable maintenance of the normal steady state of the
body.
oDefine a feedback mechanism and describe its
components.
oDifferentiate between positive and negative feedback
mechanisms and give examples for each in the body.
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 Homeostasis is the ability of the body's systems
to maintain a stable, relatively constant internal
environment within the body despite
What is
fluctuations in either the external
environment. Homeostasis?
Homeostasis is the tendency to resist change
in order to maintain a stable, relatively
constant internal environment.​

Homeostasis refers to the maintenance of
relatively constant internal conditions.

For example, your body shivers to maintain a
relatively constant body temperature when the
external environment gets colder.

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 Pathophysiology
Disruption of Homeostasis Failure of homeostasis

Disease Death

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 Control system
1. Nervous system 2. Endocrine system
Controls the body Regulates the activities
activities that requires that requires duration.
rapid responses (speed)
Detects and initiates Endocrine gland ,
reactions to changes in Pancreas, thyroid
external environment
(sensory input ,central
nervous system ,motor e.g. parathyroid
out put)
e.g. regulation of blood hormone regulating
pressure upon rising calcium levels, insulin
control glucose level.

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 Control centers in the brain play
roles in regulating physiological
parameters and keeping them
within the normal range.
Feedback
As the body works to maintain loops
homeostasis, any significant
deviation from the normal range
will be resisted and homeostasis
restored through a process called a
feedback loop.

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Feedback mechanisms
Feedback mechanisms mean :
Loop system in which the system responds to changes

Positive feedback Negative feedback
original stimulus
reversed (resulting
action in the opposite
Resulting action on the
direction of stimulus)
same direction of the
most feedback system in
stimulus
the body are negative
If stimulus increases,
If stimulus
homeostatic control
increases ,homeostasis
system activated to
control system activated
cause a decrease in the
to cause increase in the
stimulus and vice versa.
stimulus
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Type of feedback mechanisms
Feedback

Negative Positive
feedback feedback
The effector
The effector
response of the
response of the
system is in the
system is in the
opposite direction
same direction to
to stimulus that
stimulus that
initiated the
initiated the
response.
response.
Most of the control
Only few systems
systems of the body
display positive
act by negative
feedback.
High feedback.LOWER
Make temperature Make temperature HIGHER
temperatur
e
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 feedback loops
A feedback loop has three basic components:
1. Sensors / Receptors - Monitors the internal physiological
parameter and reports changes to the Control Center
2. The Control Center - Receives sensory input and compares
the reported physiological parameter's value to the set
point.
3. Effectors - If the Control Center finds that the value of the
physiological parameter is too far away from the set point,
the control center will send a command to effectors.
1. The effector will function to bring the physiological
parameter closer to the set point. is the component in
a feedback system that causes a change to reverse the
situation and return the value to the normal range.
2. Effectors are muscles and glands.
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 HOMEOSTASIS

The maintenance of a constant internal environment

Principles of Homeostasis

Stimulus Receptors Self-corrective Mechanism Negative Feedback

Change in internal Detect the To rectify the The reverse effect
environment change change of the change

Examples

Regulation of blood Regulation of blood Regulation of body
glucose water potential temperature
concentration

Copyright ©11/18/2024
2006-2011 Marshall Cavendish International (Singapore) Pte. Ltd. November 18, 2024 11 11
 Negative Feedback Loop Schematic
Negative feedback loops are the body’s
most common mechanisms used to
maintain homeostasis.
A negative feedback system is one that tries
to keep the body constant. ​
Negative feedback is a mechanism in which
the effect of the response to the stimulus is
to shut off the original stimulus or reduce
its intensity.
In a negative feedback loop, when a
mismatch is sensed by the control center,
this deviation from the set point is resisted
(counter-acted) through a physiological
process that returns the body to
homeostasis.

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 TEMPERATURE REGULATION
(Thermoregulation)

The body regulates its temperature through a
process called thermoregulation.
Thermoregulation is the ability of the body to
maintain its temperature between ~36.5–37.5
°C (or 97.7–99.5 °F).
Thermoregulation is an example of negative
feedback. ​
The negative feedback loop that regulates
temperature can function to ultimately turn the
internal temperature up or down (as needed) to
get closer to the body's necessary set point.
 TEMPERATURE REGULATION
(Thermoregulation)

The hypothalamus in the brain is the master switch that
works as a thermostat to regulate the body’s core
temperature.
The living organisms can normally survive only within a
certain range of temperature of about 0-45° C.
A. Above 45°C: the enzymes are destroyed, proteins get
denatured, plasma membrane breaks down, and cells
suffer lack of oxygen.
B. Below 0°C. At temperatures below freezing point, the
cells may burst by the formation of needle-like ice crystals
inside and between the cells. The enzymes are inactive.
If the temperature goes above the set core temperature:
Blood Flow Redirection
Blood vessels in the skin begin to dilate
allowing more blood from the body core to
flow to the extremities and the surface of the
skin.
This allows for heat loos through the skin
which cools the internal temperature.
Sweat glands are activated to increase their
secretion of sweat.
As the sweat evaporates from the skin
surface into the surrounding air, it dissipates
heat and cools the skin.
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 If the temperature falls below the set core temperature:

Blood Flow Redirection -
Blood vessels in the skin begin to restrict the
blood flow away from the body's extremities and
away from the skin's surface, thereby conserving
heat.
The blood flow is diverted to the body's core to
ensure that the vital organ continue normal
function.
Shivering
If heat loss is severe, the brain triggers muscle
contraction known as shivering.
The act of shivering releases heat while using up
ATP.
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 Negative Feedback Example:
Insulin in Blood Glucose Regulation

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 Glucose and Insulin
Pancreas

Glucose intake occurs during digestion of
food that is needed for energy expenditure
to perform routine physical activities.
The pancreas is the key organ that regulates
the glucose levels in body by secreting two Liver
hormones, insulin and glucagon.
The liver also helps to store the excess
glucose in form of glycogen to be utilized
later.

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 Glucose and Insulin Negative Feedback
Loop
Boy eating cake

Increases
Glucose
Levels

(-) Stimulates β cells of
CYCLE 1
Lowers Blood pancreas to secrete insulin
Glucose levels

Insulin stimulates the
cells to take up glucose
from the blood.
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 CYCLE 2
Low Blood Glucose
Levels

(-)

Stimulated Alpha Cells in
High blood glucose levels Pancreas
and Cycle 1 continues

Glucagon is released
Glucagon stimulates liver cells to
release glucose into the blood

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 Glycogen
If there is too
much glucose in
the blood,
Insulin converts
Insulin some of it to
glycogen

Glucose in the blood
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 Glycogen
If there is not
enough glucose
in the blood,
Glucagon
Glucagon converts some
glycogen into
glucose.

Glucose in the blood
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Diabetes
Some people do not produce enough insulin.
When they eat food, the glucose levels in their blood cannot
be reduced.
This condition is known as DIABETES.
Diabetics sometimes have to inject insulin into their blood.
They have to be careful of their diet.

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 Glycogen
The glucose
But there in the
is no
Glucose
blood
insulinincreases.
to convert
concentration rises
it into glycogen.
to dangerous
Insulin levels.

Glucose in the blood
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BP regulation
Calcium regulation
Effects of
Parathyroid
Hormone
Effects of Calcitonin
Attenuates absorptive ability of osteoclasts
Inhibits formation of new osteoclasts
Osteoclast decrease causes osteoblast decrease
Effect to decrease calcium is transitory
Causes reduced bone turnover
Has weak effect in kidney and intestines
 Kidney and Water Regulation
The nephron is the
most important
functional part of the
kidney.
It filters nutrients like
salts and amino acids
in the Bowman’s
capsule into ascending
loop and filters the
urine.

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 Kidney and Water Regulation
Anti-Diuretic Hormone, ADH (also called vasopressin), is
secreted by the pituitary gland and acts on the nephron to
conserve water and regulate the tonicity of body fluids.

Anti-
Diuretic
Hormone

ADH acts on Nephron to
reabsorb water and decrease
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blood osmolality (saltiness) 31
 ADH regulated water conservation in kidneys

Less water in the Excess water
blood in the blood

Stimulates osmoreceptors in Stimulates osmoreceptors in
hypothalamus to send signals to hypothalamus to send signals to
the pituitary gland the pituitary gland

Pituitary glands secretes Pituitary glands secretes
high levels of ADH low levels of ADH

Less ADH makes the tubules less
ADH makes the tubules more permeable
permeable and less water is reabsorbed
and more water is reabsorbed back into the
back into the bloodstream (urine is
bloodstream (urine is concentrated).
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 Positive feedback intensifies a
change in the body’s
physiological condition rather
than reversing it.

Positive A deviation from the normal
range results in more change,
Feedback and the system moves farther
Loops away from the normal range.

Positive feedback in the body
is normal only when there is a
definite end point.

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 Positive Feedback
In most cases, once the purpose of the feedback loop is
completed, counter-signals are released that suppress or
break the loop.

Childbirth contractions stop when the baby is out of the
mother's body.

Chemicals break down the blood clot.

Lactation stops when the baby no longer nurses.
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 Positive Feedback Loops
Normal childbirth is driven by a positive feedback loop.
A positive feedback loop results in a change in the body’s status, rather
than a return to homeostasis.
The first contractions of labor (the stimulus) push the baby toward the
cervix (the lowest part of the uterus).
The cervix contains stretch-sensitive nerve cells that monitor the
degree of stretching (the sensors).
These nerve cells send messages to the brain, which in turn causes the
pituitary gland at the base of the brain to release the hormone
oxytocin into the bloodstream.
Oxytocin causes stronger contractions of the smooth muscles in of the
uterus (the effectors), pushing the baby further down the birth canal.
This causes even greater stretching of the cervix.
The cycle of stretching, oxytocin release, and increasingly more forceful
contractions stops only when the baby is born.
At this point, the stretching of the cervix halts, stopping the release of
oxytocin.

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 Positive Feedback
A positive feedback loop occurs when the output of a system acts to
enhance the changes to the input of the system.

One example of a biological positive feedback loop is the onset of
contractions in childbirth.

When a contraction occurs, the hormone oxytocin is released into the body,
which stimulates further contractions.

This results in contractions increasing in amplitude and frequency.

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 Positive Feedback
Another example is blood clotting.
The loop is initiated when injured tissue releases signal
chemicals that activate platelets in the blood.
An activated platelet releases chemicals to activate more
platelets, causing a rapid cascade and the formation of a blood
clot.

Lactation involves positive feedback so that the more the
baby suckles, the more milk is produced.

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Which is an example of negative feedback?
1. Lowering of blood glucose after meal.
2. Blood clotting after injury
3. Lactation during nursing
4. Uterine contraction during nursing

The body’s thermostat is located in the ___.
1. Cerebral cortex
2. Hypothalamus
3. Spinal cord
4. Cerebellum
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This mechanism is in play when the original state is
restored due to a response that opposes that change.
a) Positive feedback loop
b)Negative feedback loop
c) Effector loop
d)Control center loop
e) Receptor feedback loop

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 summary
“Homeostasis” is the ability of the body to maintain a
constant internal environment by making small internal
adjustments to compensate for large external disturbances.
Injuries, illness, disease and death can disrupt homeostasis.
Diabetes causes disruption of glucose homeostasis. It is
only one example of the potentially severe problems caused
by disrupting homeostasis.
Science is actively pursuing a broader, more detailed
understanding of homeostatic mechanisms and the
consequences of their disruptions.
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 Carry Home Message
Negative Feedback: Example
1. Regulation of blood glucose
2. Regulation of blood pressure
3. Regulation of body temperature

Positive Feedback: Example
1. Clotting
2. Protein digestion
3. A temperature of 100.2 0F
causes further increase

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