Transcript Chapter 17

Chapter 17
Anatomy & Physiology
Fifth Edition
Seeley/Stephens/Tate
(c) The McGraw-Hill Companies, Inc.
FUNCTIONAL ORGANIZATION OF THE
ENDOCRINE SYSTEM
– There are two major means of communication in the
body: the neuronal system and the endocrine system.
– The neuronal system – has clear pathways which are
connected with neurons. Thus it is reasonably clear
for each neuron where it starts and where it ends.
(reflex --- cerebral cortex ---- targets)
– At the end knob, neurotransmitters are released.
– Its complexity makes it possible to stimulate more
than one tissue and organ simultaneously.
– The effect is relatively short lived.
• The endocrine system – the active substances,
hormones, are made in specific organs.
• The glands may be stimulated with neurons.
• Hormones have target tissue and organs.
• Long distance transport of its active substance is done
by the circulatory system.
• Local effect is also possible.
• Again, one hormone may effect more than one target
organs.
• The effects are usually slow and relatively long lasting.
• An overview
• The word endocrine is in contrast with exocrine. Thus
we are concerned with internal secretion.
• Endocrine glands secrete specific hormones.
• The strength of a hormone is determined by its
concentration, while the strength for neurons is often the
frequency of the action potential.
• Also recall the neurohormones may be released by
neurons into the circulatory system.
• Functional classification of chemical signals is shown in
Fig. 17.1
• Review Table 17.1
• Autocrine chemical signals – released by cells and
have a local effect of the same cell type. Example are
prostaglandins and platelets.
• Paracrine chemical signals – released by cells and
effect local other cell types. Somatostatin from
pancreas.
• Pheromones – hormones secreted into environment.
Structure of hormone – there are type major types.
1. Amino acid derivates: epinephrine, norepinephrine,
the thyroid hormones, pineal hormone (melatonin)
2. Peptide/protein hormone: antidiuretic hormone,
glucagon, oxytocin, growth hormone, prolactin,
insulin.
3. Lipid derivatives:
1. Steroid hormones – estrogens, testosterone
2. Prostaglandins – derived from arachidonic acid.
• Control of secretion rate
•
In essence the control is in a form of negative
feedback.
• Three major patterns:
1. By other substance; such as sugar controls the
regulation of insulin release.
– Increased blood sugar
– Stimulates insulin release from the pancreas
– Insulin stimulates glucose uptake by tissues
– Decrease in blood sugar
2.
Neuronal control of endocrine glands
– Stress or exercise stimulates sympathetic division of ANS.
– Release of epinephrine or smaller amounts of norepinephrine
from the adrenal medulla. (Fig.17.5)
3. Regulation of hormone secretion by another hormone
– Thyroid-releasing hormone (TRH) is released from neurons in the
hypothalamus.
– TRH stimulates the release of thyroid stimulating hormone (TSH)
from the anterior pituitary gland.
– TSH stimulates the secretion of thyroid hormones from the
thyroid gland.
– Thyroid hormone stimulates tissues
– That includes the hypothalamus and the anterior pituitary
(negative-feedback) to inhibit both TRH and TSH.(fig.17.6)
Regulation is usually complex and more than one factor could affect
organs. For example, the level of insulin may be regulated by
blood glucose and ANS., Ex: of positive feedback. (fig 17.7)
• The level of hormone in the blood steam may:
– Maybe relatively short
– May respond in a matter of hours
– May respond in a matter of days
•
Transport
–
–
–
Hormones are transported through the circulatory system
dissolved in plasma.
At the target sites they diffuse out from the capillaries.
Some hormones such as, steroids and thyroid hormones, are
bound to specific plasma proteins reversibly.
hormone + plasma protein = = hormone-protein
–
–
While this equilibrium is held in plasma, there are free
hormones and proteins bound hormones.
Free hormones may diffuse out through the walls of capillary
pores at the target sites, while proteins bound hormones
remain within the capillaries. But eventually they will
establish a new equilibrium (carry more hormone) and make
more free hormones available (sustained release).
Metabolism and Excretion
• Once hormones are poured into the blood steam, it is
equally important to excrete them from the circulation
to avoid excessively long effects of hormones.
• The lengths of time it takes for elimination by half is
called “half-life” time.
• The half-life time of water soluble hormones, such as
proteins, glycoproteins, epinephrine and norepinephrine,
is relatively short.
• The half-life time of lipid soluble hormones, such as
steroid and thyroid hormones, is longer.
• As shown in Table 17.3 hormones are eliminated from the
circulatory system in four ways:
– Excretion
• Kidneys-urine; the liver-bile
– Metabolism
• Enzymatic digestion
– Active transport
• Recycling (neurotransmitters)
– Conjugation
• Sulfate and glucuronic acid groups bind to hormones and they
are released into urine or bile.
• Interaction of hormones with their target tissues
• At their designated sites hormones interact with the target cells and
active their intrinsic function, usually stimulating specific
enzymes.
– Hormone receptors: protein or glycoprotein.
– Each target cell has a specific binding site for the specific
hormone.
– However, a hormone may bind to the/ other target receptor
which are similar.
– After prolonged exposure to a hormone, the tagged cells may
reduce the number of hormone receptors called, down
regulation.
– On the other hand, exposure to stimulation may increase the
number of hormone receptors called, up-regulation. Example is
LH receptors are up regulated by FSH.
The End.