Transcript Chapter 14
Chapter 13
The Endocrine System
Chapter Outcomes
Explain how the endocrine system
contributes to homeostasis
Compare the nervous & endocrine systems
Identify the principal endocrine glands and
the hormones they secrete
Explain how the endocrine system allows
the body to sense and respond to the
internal environment
Chapter Outcomes
Explain the relationship between negative
feedback and hormonal regulation
Explain how the endocrine system is
involved in seasonal affective disorder and
the sleep-wake cycle
Describe the structure of the anterior and
posterior pituitary and explain how they
are regulated
Chapter Outcomes
Explain how human growth hormone
contributes to growth and development
Evaluate the use of hormone therapy
Describe the structure and regulation of
the thyroid gland
Describe the physiological effects of
hormonal imbalances
Chapter Outcomes
Explain how the nervous and endocrine
system act together to regulate stress
response
Identify and describe the actions of
epinephrine and norepinephrine in the
human body
Describe the effects of cortisol and
aldosterone on the body during long term
stress response
Chapter Outcomes
Describe the physiological effects of
chronic stress or an imbalance in the
stress hormones
Describe the structure of the pancreas and
its role in homeostasis
Explain how insulin and glucagon regulate
levels of blood glucose
Describe the physiological effects of
diabetes and how the condition occurs
Nervous vs. Endocrine Systems
Both the nervous and endocrine systems
regulate homeostasis in the body
Endocrine responses are often slower, but
have longer lasting effects than nervous
system responses
Often both the nervous and endocrine
systems work together to regulate
responses
Our Chemical Messengers
Hormones are chemicals that are
produced by cells in one part of the body
and affect other parts of the body
These hormones can be classified as
either steroid or protein hormones
Not all hormones affect all cells – most
cells have special receptor sites for various
types of hormones
Steroid Hormones
Steroid hormones diffuse through the cell
membrane
They attach to receptor sites in the
cytoplasm of cells
This hormone-receptor complex moves
into the nucleus, activating a gene and
producing the required protein
Animation of
Steroid
Hormone
Action
www.rise.duke.edu
Protein Hormones
Protein hormones cannot diffuse through the cell
membrane, but rather attach to receptor sites
on the membrane
This hormone-receptor complex triggers the
production of an enzyme (adenyl catalase)
This enzyme converts ATP to cyclic AMP
The cyclic AMP turns on enzymes in the
cytoplasm so that they carry out their functions
An Animation of Protein Hormone Action
http://users.rcn.com/jkimball.ma.ultranet/BiologyPages/P/ProteinHormoneR.gif
Negative Feedback
We do not want constant hormone
production in the body
Once the hormone produces its desired
effect, hormone production must be
decreased
Ex: Testosterone Feedback
The regulation of hormone levels is
important to the human body
Many different diseases are caused by an
imbalance of hormones
Seasonal Affective Disorder
Melatonin is a hormone that lets the body
know when to sleep or wake up (light
inhibits its secretion)
However, if people do not receive enough
light, too much melatonin is produced –
and the person feels fatigued
Circadian Rhythm
To an extent, melatonin levels regulate our
circadian rhythm (the body’s internal
clock)
In teens, this rhythm shifts by several
hours
As a result, teenagers often feel awake at
night and sleepy in the morning
The Pituitary – The “Master Gland”
The pituitary controls
other glands
It is attached to the
hypothalamus in the
brain
The posterior lobe of
the pituitary stores
and releases
hormones
The anterior lobe produces its own
hormones
The cells of the pituitary react to stimulus
from the hypothalamus
Hormone
Location Target
Function
Thyroidstimulating
hormone (TSH)
Anterior
Thyroid gland
Regulates cell
metabolism
Corticotropin
adrenal steroid
(ACTH)
Anterior
Adrenal cortex
Releases hormones for
stress response
Growth Hormone
(GH)
Anterior
Most cells
Promotes growth
Folliclestimulating
hormone (FSH)
Anterior
Ovaries, testes
Stimulates egg and
sperm development
Lutenizing
hormone (LH)
Anterior
Ovaries, testes
Stimulates ovulation or
testosterone production
Prolactin (PRL)
Anterior
Mammary glands
Stimulates milk
production in females
Oxytocin
Posterior
Uterus, mammary
glands
Initiates contractions &
aids in milk production
Antidiuretic
Hormone (ADH)
Posterior
Kidney
Increases water
reabsorption
Growth Hormone
Regulates human growth
Effects are most pronounced in cartilage
and bone cells
If GH production continues after growth
plates have fused, other bones will grow
This results in acromegaly
Andre Roussimoff
Professional wrestler
Grew to over 7 feet tall and
over 500 lbs.
Died of congestive heart
failure
en.wikipedia.org/wiki/Andr%C3%A9_the_Giant
Other growth hormone disorders include
dwarfism (where insufficient GH is
produced) and gigantism (where excess
levels of GH are present in childhood, but
drop off when bone growth is complete)
The Thyroid Gland
The primary
function of the
thyroid gland is to
regulate
metabolism
It produces a
hormone called
thyroxine
www.revolutionhealth.com
Thyroxine
Thyroxine accelerates the rate of sugar
oxidation in cells
Thyroxine production is regulated in a
feedback loop which includes the pituitary
hormone TSH
Thyroxine Feedback Loop
Iodine and Thyroxine
Iodine is an important component of the
thyroxine molecule
Without iodine, the thyroid cannot
produce thyroxine
This means that the production of TSH
cannot be turned off
Continual stimulation of the thyroid by
TSH causes the thyroid to become
enlarged
Goitre
The enlargement of
the thyroid is known
as goitre
This condition can be
treated through the
intake of iodine in
the diet
http://www.thachers.org/images/endemic_goiter.jpg
The Thyroid and Blood Calcium
Calcium ions play a role in teeth and
skeletal development
It also plays a role in blood clotting, nerve
conduction, and muscle contraction
Blood Ca2+ levels are regulated by two
hormones – PTH and calcitonin
Calcitonin is produced in the thyroid gland,
while PTH is produced in the parathyroid
glands (embedded within the thyroid)
PTH – Calcitonin Loop
High Ca2+ Level
Low Ca2+ Level
Adrenal Glands
The adrenal glands
are located on top of
the kidneys
They actually consist
of two glands in one
shell
http://cal.man.ac.uk/student_projects/2002/MNBY9APB/wpe1.gif
Adrenal Medulla
The medulla regulates short-term stress
responses
Produces two hormones: Epinephrine
(adrenaline) and norepinephrine (noradrenaline)
The medulla is controlled by the nervous system
When released into the blood, epinephrine and
norepinephrine cause a rise in blood sugar levels
They also increase heart rate, breathing rate,
and cell metabolism
Adrenal Cortex
1.
The adrenal cortex produces sustained
responses that make up long-term stress
response
This part of the gland produces three hormone
types:
Glucocorticoids (cortisol): Increases levels of
amino acids in blood. These are converted to
glucose by the liver. The release of these
hormones are controlled by ACTH release from
the pituitary. Excess levels of cortisol can
damage the heart, impair thinking, and cause
high blood pressure and diabetes
2.
3.
Mineralcortocoids (aldosterone): These
help to regulate the level of water in the
body by regulating water absorption in
the kidneys.
Sex hormones: Small amounts of sex
hormones are released by the adrenal
cortex.
Regulation of Blood Sugar
The pancreas contains two types of cells
One set of cells produces digestive
enzymes
The other cells, known as the Islets of
Langerhans, regulate blood sugar levels
through the release of hormones
Insulin
Insulin is produced by beta cells
Insulin is released when blood sugar is
high
The insulin makes body cells more
permeable to glucose
This allows the liver to convert glucose to
glycogen for storage
Glucagon
Glucagon works in a complementary
fashion to insulin
Alpha cells release glucagon when the
blood glucose level is too low
Glucagon promotes the conversion of
glycogen to glucose
Blood Sugar Regulation Feedback
Loop
Diabetes Mellitus
This is a genetic disorder where the body’s
islet cells are damaged and cannot
produce enough insulin
Without enough insulin, the blood sugar
level in the body rises
Symptoms of Diabetes Mellitus
Dehydration associated with excess urine
production
Low energy levels
Types of Diabetes
Diabetes can be classified as juvenile
diabetes or maturity-onset diabetes
Juvenile diabetes (Type 1) is a genetic
condition which results in damaged islet
cells
Maturity-onset diabetes (Type 2) is due to
decreased production of insulin by the
islet cells as the body ages, and as a
result of the body’s cells receptors refusal
to respond to insulin
Management of Diabetes
Diabetes can be managed through the
intake of drugs, such as insulin
Insulin may be taken via subcutaneous
injections, or an automated insulin pump
may be used
Originally, insulin from pigs and cattle was
used for injections
Currently, biologically engineered bacteria
can produce human insulin for use
Adam Morrison
Suffers from juvenile
diabetes
Played three seasons for
Gonzaga University
Voted NCAA co-player of
the year in 2005-2006
Drafted by NBA’s Charlotte
Bobcats (3rd Overall in
2006)
sportsillustrated.cnn.com
Adam manages his
diabetes through the
use of an insulin pump
when off the court
He also uses a very
strict diet to manage
his blood sugar levels
on game days (he
always eats the same
meals at the same
time)
www.deadspin.com
The Discovery of Insulin
Doctors Frederick
Banting and Charles
Best tested a theory
that diabetes resulted
from a deficiency of
hormones in the
pancreas
They tied the
pancreatic duct of
dogs and noted that
they began to show
symptoms of diabetes
www.library.utoronto.ca
Banting and Best then extracted the
hormone from the islet cells and injected it
into the dogs
The dogs recovered, indicating that this
hormone was responsible for controlling
blood sugar levels
Banting was awarded the Nobel Prize in
Medicine in 1923, but Best was not
included
Future Possibilities
Islet transplant surgery is becoming a
more viable solution for treatment of
diabetes
In this surgery, the islet cells are replaced
with healthy donor cells, which produce
insulin
Currently, this surgery has about a 50%
success rate 1 year after the surgery
Stem cell research could also lead to new
treatments for diabetes
These stem cells could possibly be used to
help the body develop functioning islet
cells by removing the damaged genes
Prostaglandins
A number of different types of cells
produce prostaglandins
These hormones are released by cells in
response to changes in the immediate
environment of the cells
Prostaglandins alter the activity of cells to
maintain homeostasis
END OF CHAPTER