Physiological Psychology Week 10 Handout PDF

Summary

This handout provides an overview of homeostasis, focusing on thermoregulation, and osmoregulation. It explains how the body maintains internal balance, using examples like temperature regulation and the role of hormones. The document also touches on the concept of physiological and behavioral responses to maintain homeostasis.

Full Transcript

Republic of the Philippines
KOLEHIYO NG LUNGSOD NG DASMARIÑAS
Brgy. Burol Main
Dasmariñas, City, Cavite

PSYCHOLOGY DEPARTMENT
Physiological/Biological Psychology
Week 10 Handout

Homeostasis
 Homeostasis refers to the body's need to reach and maintain a certain state of
equilibrium.
 Homeostasis is the body's tendency to monitor and maintain internal states, such as
temperature and blood sugar, at fairly constant and stable levels.
 These processes take place mostly without our conscious awareness.

How Is Homeostasis Maintained?
Your body has set points for a variety of states—including temperature, weight, sleep, thirst,
and hunger. When the level is off (in either direction, too much or too little), homeostasis will
work to correct it. For example, to regulate temperature, you will sweat when you get too hot
or shiver when you get too cold.

If something is out of balance in your body, a physiological reaction will kick in until the set
point is once again reached. Here's how the primary components of homeostasis work:

1. Stimulus: A stimulus from a change in the environment kicks something out of balance
in the body.
2. Receptor: The receptor reacts to the change by informing the control unit.
3. Control unit: The control unit then communicates the change needed to bring the body
back into balance.
4. Effector: The effector receives this information and acts on the change that is needed.

A negative feedback loop will work to decrease the effect of the stimulus, whereas a positive
feedback loop will increase it. In homeostasis, negative feedback loops are most common, as
the body is typically attempting to decrease the effect of the stimulus to get the body back to
equilibrium.

Types of Homeostatic Regulation
There are three main types of homeostatic regulation that happen in the body. Though their
names might be unfamiliar, you probably experience them every day.

Thermoregulation
Regulating body temperature is called thermoregulation.
It is one of the most important and obvious homeostatic systems.
All organisms, from large mammals to tiny bacteria, must maintain an ideal temperature in
order to survive. Some factors that influence this ability to maintain a stable body temperature
include how these systems are regulated as well as the overall size of the organism.
 Endotherms: Some creatures, known as endotherms or "warm-blooded" animals,
accomplish this via internal physiological processes. Birds and mammals (including
humans) are endotherms.
 Ectotherms: Other creatures are ectotherms (aka "cold-blooded") and rely on external
sources to regulate their body temperature. Reptiles and amphibians are both
ectotherms.
 Note: The colloquial terms "warm-blooded" and "cold-blooded" do not actually mean
that these organisms have different blood temperatures. These terms simply refer
to how these creatures maintain their internal body temperatures.

Thermoregulation is also influenced by an organism's size, or more specifically, the surface-to-
volume ratio.
 Large organisms: Larger creatures have
a much greater body volume, which
causes them to produce more body
heat
 Small organisms: Smaller animals, on
the other hand, produce less body heat
but also have a higher surface-to-
volume ratio. They lose more body heat

than they produce, so their internal systems must
work much harder to maintain steady body
temperature. This is even true of babies,
especially those born prematurely.

Osmoregulation
Osmoregulation strives to maintain the right amount of water and electrolytes inside and
outside cells in the body.
The balance of salt and water across membranes plays an important role, as in osmosis, which
explains the name "osmoregulation." In this process, the kidneys are responsible for getting rid
of any excess fluid, waste, or electrolytes. Osmoregulation also affects blood pressure.

Chemical Regulation
Your body regulates other chemical mechanisms as well to keep systems in balance. These use
hormones as chemical signals—for example, in the case of blood sugar levels. In this situation,
the pancreas would release either insulin, when blood sugar levels are high, or glucagon, when
blood sugars are low, to maintain homeostasis.

Impact of Homeostasis
Homeostasis involves both physiological and behavioral responses. In terms of behavior, you
might seek out warm clothes or a patch of sunlight if you start to feel chilly. You might also curl
your body inward and keep your arms tucked in close to your body to keep in the heat.

As endotherms, people also have a number of internal systems that help regulate body
temperature. When your body temperature dips below normal, a number of physiological
reactions respond to help restore balance. Blood vessels in the body's extremities constrict in
order to prevent heat loss. Shivering also helps the body produce more heat.

The body also responds when temperatures go above normal. Have you ever noticed how your
skin becomes flushed when you are very warm? This is your body trying to restore temperature
balance. When you are too warm, your blood vessels dilate in order to give off more body heat.
Perspiration is another common way to reduce body heat, which is why you often end up
flushed and sweaty on a very hot day.
Application to Psychology
Homeostasis and Mental Health
Like the body, the mind seeks its own type of homeostasis and attempts to compensate when
out of balance. For example, one prominent theory of human motivation, known as drive-
reduction theory, suggests that homeostatic imbalances create needs. These needs, in turn,
motivate behavior in an attempt to restore homeostasis.