Homeostasis ppt.pptx

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INTRODUCTION TO
HOMEOSTASIS

Dr Nisreen Daffa Alla
M.B.B.S, Ph. D, MSc Health
Profession Education
Important variables within the
body:
 Fluid balance
 Body temperature
 Oxygen& carbon dioxide levels
 Blood pressure
 pH
 Plasma level of creatinine, urea, sodium, potassium,
glucose, amino acids, etc…..

These variables must stay within certain ranges.

 Changes in the external environment can cause these
variables to change.
Homeostasis:
definition is:

The process by which a stable or
constant internal environment is
maintained despite changes in the
external environment.

What is the internal
environment of the body?
The Internal body enviroment
The internal environment of an
organism is the extracellular fluid
the fluid environment surrounds cells,
exchanges nutrients and wastes, and
acts as a buffer.
The cell is the simplest unit of life.
The cell needs a constant internal
environment.
Cells obtain nutrients from, and
remove wastes to, the internal
environment.
Homeostasis is necessary for healthy
cells.
Major systems control
homeostasis
 All different body systems operate in
harmony to provide homeostasis
Endocrine and nervous systems are the
major control systems
Nervous system
– Controls and coordinates bodily activities that
require rapid responses
Endocrine system
– Regulate activities that require duration
rather than speed.
Components of a homeostatic
control system
Receptor = The structure that detects changes in a
variable, the stimulus e.g., a change in temperature.
Afferent pathway: send the data to the control center
C. Control Center= receives data, interprets
information, sends messages out.
 brain
 Endocrine glands
D. Communication System/efferent= delivers
messages to effector organs, tissues
PNS (e.g. motor neurons)
Hormone
E. Effectors = respond to change. It can be muscles or
glands (release hormones)
 3 Input: Control
center 4 Output:
Information Information sent
sent along along efferent
afferent pathway to
pathway to

Receptor (sensor) Effector

2 Change
detected
by receptor Homeostatic Control Mechanisms
5 Response of
effector feeds
back to influence
1 Stimulus: magnitude of
Produces I mb stimulus and
al a
change nce returns
in variable variable to
homeostasis
Variable (in homeostasis)
I mb
al a
nce

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The hypothalamus
 Part of the brain

 Often serves as the co-ordinating centre:
Receives messages from receptors
 Initiates a hormonal/nervous response
Homeostatic control
mechanisms
The control centers function to
maintain homeostasis through
Feedback & feedforward
mechanisms.
Types of feedback mechanism
are:
1. Negative feedback
2. Positive feedback
 Homeostatic Control
Systems
Feedback - refers to responses made after change has
been detected
– Types of feedback systems
Negative
Positive

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Negative feedback
Negative feedback: Response triggered
by changed conditions serves to reverse the
change
E.g., Body temperature increases  Skin
blood vessels dilate  Body temperature
decreases
Resulting action is in the opposite direction
of stimulus
If stimulus increases, homeostatic control
system activated to cause a decrease in the
stimulus
If stimulus decreases, homeostatic control
 Body
temperature
increases

Normal Hypothalamu
body s sends a
temperat message to
ure blood vessels

Body Skin blood
temperature vessels
decreases dilate
 Glucose Homeostasis Chart
Low Blood Sugar
Condition High Blood Sugar Do not meet energy
Toxic
requirements of cell

Receptor Glucose transporter Glucose transporter

Control -cell of the pancreas -cell of the pancreas
Center
Effector Insulin Glucagon

Glucose uptake by Liver breaks down
muscle/fat tissue glycogen to create
Result
Lowers blood-glucose glucose
Raises blood-glucose
Positive feedback
 Positive feedback: The response triggered by
changing conditions serves to move the
variable even further away from its steady
state

 E.g., uterine contractions are stimulated by
oxytocin  baby moves towards cervix  more
oxytocin is released
Homeostatic Systems Regulated by
Positive Feedback
Positive feedback during
breastfeeding
Sensory detectors detect baby
suckling
Message is transmitted to the
hypothalamus
Hypothalamus signals posterior
pituitary to release the hormone
oxytocin
Oxytocin stimulates the mammary
Feedforward control
Based on forecast result or anticipated
change.
The response of the control system is taken
well in advance of actual result
Example: rise of heartbeat in advance of
actual physical exertion by the central
autonomic network.
Feed-forward control can be likened to
learned anticipatory responses to known
cues (predictive coding).
Significance of homeostasis
Homeostasis maintains a relatively
stable internal environment, allowing
the body to adapt to external changes
while preserving essential functions.
Survival: Every living organism relies
on homeostatic processes for survival.
Imbalance and Disease: When
homeostasis fails, internal imbalances
can lead to sickness or even death.
For example, diabetes occurs when blo
od sugar homeostasis is
disrupted.
A disruption of homeostasis is
harmful.
 Homeostasis can be disrupted for several
reasons.
1. Sensors fail (don’t detect changes)
2. Effectors do not receive messages (nerve,
endocrine issues)
3. Injury (overwhelm homeostatic controls)
4. Illness (viruses or bacteria)
*Disruption of homeostasis can begin in one organ
and cause a chain reaction in the others
therefore causing a major body disturbance.
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