Circulatory System Flashcards
What type of organisms require circulatory systems?
large, complex organisms in which diffusion would be far too slow and inefficient = require bulk flow of nutrients
What type of organisms do not require circulatory systems? what do they use instead?
small, unicellular organisms
or simple organisms
What 5 phyla of animals do not require circulatory systems?
Porifera (sponges)
Cnidaria
Echinodermata
Platyhelminthes (flatworms)
Nematoda
What are the major functions of a CS?
to transport O2 to cells
to remove CO2 and other waste
to transport nutrients
to regulate salts and water
to regulate temperature
to transport signaling molecules (ex. hormones)
for immune responses
What are the 3 major components of a CS?
a pump or propulsive structure
a system of tubes, channels or spaces
a circulatory fluid
What is the function of a pump or propeller?
it generates a pressure gradient to move circulatory fluid around the body
What direction does circulatory flow around the body? why?
unidirectionally because of one way valves in the pump
What are the 3 types of pumps?
chambered hearts
skeletal muscles
pulsating blood vessels
Describe chambered hearts as pumps
hearts have contractile chambers which generate pressure to move fluid into and out of the body
How do skeletal muscles act as pumps?
muscle contraction can squeeze vessels to create pressure and move fluid
how can pulsating blood vessels act as pumps?
peristaltic (rhythmic) contractions of vessel walls move fluid
What are the 2 types fo circulatory fluid?
blood (closed)
hemolymph (open)
What are 3 types of tubes/channels that are used in the CS?
arteries to carry fluid away from heart which branch into arterioles which branch into capillaries
capillaries connect to venules which connect to veins which bring fluid back to the heart
What are capillaries for?
they are very fine, delicate and narrow channels where materials are exchanged between CS fluid and tissues
How does CS fluid flow around the body?
through the vascular system along/down the pressure gradient generated by the pump
what is peristalsis?
rhythmic wave-like contractions of vessel walls
Describe a closed CS (fluid, pumps, vessels, mixing with interstitial fluid, contact with tissues, organism types)
fluid: blood
pump: heart
vessels: blood vessels
no mixing with interstitial fluid
no direct contact with tissues
vertebrates
How are materials exchanged between CS fluid and tissues in closed systems?
through diffusion or transporters in vessels (ex. capillaries)
Describe an open CS (fluid, pumps, vessels, mixing with interstitial fluid, contact with tissues, organism types)
fluid: hemolymph
pump: can be heart
vessels:
sinuses
mixing with interstitial fluid and direct contact with tissues for exchange
invertebrates
What are sinuses? what type of CS are they used in?
they are spaces in the body cavity where CS fluid enters and mixes with interstitial fluid
in open systems
What is interstitial fluid? what type of CS is this in?
the extracellular fluid that surrounds tissues
in both open and closed
What are the 3 major components of blood and their proportion in human blood?
plasma (55%)
erythrocytes (45%)
white blood cells and blood clotting cells (< 1%)
Describe blood plasma
it’s the liquid component of blood
it’s mostly water, but contains some dissolved ions, organic solutes (HCO3) and proteins
What is serum?
blood plasma without the clotting factors
What are the proteins in blood plasma?
clotting factors (ex. thrombin, fibrinogen)
carrier proteins (ex. albumin, globulin)
What is HCO3 for in blood plasma?
it’s the form of CO2 that is carried through the blood = buffers blood
Describe erythrocytes
red blood cells
function in storing and transporting O2 in blood
What are the most abundant cell types in vertebrate blood?
red blood cells
What is the hematocrit?
the proportion of blood composed of red blood cells
in humans it’s ~45%
What makes red blood cells/erythrocytes so efficient at storing and transporting O2?
RBC have high concentrations of hemoglobin (respiratory pigments) which can each bind 4 O2 molecules
a single red blood cells has extremely high capacity to bind O2
What respiratory pigment is involved in binding O2 in red blood cells? how many O2 molecules can one bind?
hemoglobin can bind 4 O2 molecules at a time
What are examples of white blood cells and clotting cells in blood?
leukocytes and thrombocytes (platelets)
What is the open circulatory fluid?
hemolymph
What is lymph?
fluid in the vertebral lymphatic system involved in immune responses
which phyla have open circulatory systems?
urochordata
cephalochordata
annelids (tube worms only)
arthropods
molluscs (only bivalves and gastropods)
Which phyla have closed circulatory systems?
vertebrates
molluscs (cephalopods)
annelids (earth worms)
How do Porifera obtain nutrients?
ciliated cells lining their body cavity move water for diffusion
How do Cnidarian obtain nutrients?
muscle contractions of body wall move water for diffusion
How do flat worms obtain nutrients?
pharynx contractions bring water into body cavity for diffusion
What type of circulatory systems do Annelids have?
both
Polychaete (tube worms) = open
Oligochaete (earth worms) = closed
what are the pumps in annelids?
heart(s)
What system of tubes, channels, or spaces do Annelids use?
tubeworms = hemolymph vessels and sinuses
earthworms = blood vessels
What type of circulatory systems do Molluscs have?
both
bivalves + gastropods = open
cephalopods = closed
what type of pumps are used in molluscs?
hearts
what type of vascular system is used in molluscs?
vessels
What type of circulatory systems do Arthropods have?
open
How does the CS of crustaceans differ from insects?
they’re both open, but insects do not use their CS to transport O2, they have a separate tracheal system
What are ostia?
pores in the heart(s) of open CS animals that allow hemolymph to enter body cavity
What is unique to the insect CS?
CS is used only for delivering nutrients and immune cells, not for O2
Tracheal system used for O2
Describe the basic pathway of blood movement in vertebrates
aorta pumps blood out of heart
arteries carry blood away from heart and branch into smaller
arterioles which branch into smaller
capillaries which conduct material exchange between blood and tissues and coalesce into
venules which coalesce into
veins which carry blood toward the
ventricle of the heart
What are the 4 major layers of the walls of vertebrate blood vessels?
outermost:
tunica externa
tunica media
tunica intima
endothelium
What does the wall of vertebrate blood vessels surround?
a lumen (space) where blood flows
Describe the tunica externa
the outermost layer of the blood vessel wall
composed of collagen and some elastic fibers, but mostly very rigid
Describe the tunica media
the middle layer of blood vessel wall
composed of smooth muscle cells and elastic connective tissue
Describe the tunica intima
the internal lining of the blood vessel wall
made of smooth endothelial cells
How does the thickness of the blood vessel wall layers differ in veins compared to arteries?
veins have much thinner layers compared to arteries which have very thick tunica externa and tunica media (and thicker intima)
How does the lumen differ in size between major veins and arteries?
the lumen is much larger in veins than arteries
What layers of blood vessel walls do venules have? how does this affect the structure?
only tunica externa and endothelium lining
venules are very rigid
What layers of blood vessel walls do arterioles have? how does this affect the structure?
only tunica media and endothelium lining
more elastic
What layers of blood vessel walls do capillaries have? how does this affect the structure?
only has endothelial cells
capillaries are VERY fine and delicate
Which blood vessel types have one way valves? which do not?
only veins do
arteries and capillaries do not
What are the 3 types of capillaries?
Continuous
fenestrated
sinusoidal
Which capillary type is most abundant?
continuous
Describe continuous capillaries (tissues they’re found in, type of communication, etc)
most abundant type
found in skin and muscle tissues
found in the CNS-blood brain barrier
endothelial cells connected by tight junctions
Describe fenestrated capillaries (tissues they’re found in, type of communication, etc)
endothelial cells have pores (fenestrae)
found in kidneys, endocrine organs, intestine
very efficient in exchange
Describe sinusoidal capillaries (tissues they’re found in, type of communication, etc)
very few tight junctions, much more gaps
found in liver and bone marrow
very porous = key for large protein exchange
T or F: all capillary endothelial cells are linked by tight junctions
true
T or F: all capillaries leak very little fluid because of tight junctions
false, only continuous capillaries
fenestrated and sinusoidal capillaries have pores for exchanging more
order capillary types from least to most porous/good at exchanging
least: continuous (tight junctions only)
mid: fenestrated (pores)
most: sinusoidal (large gaps and fenestrae)
which vertebrates have single circuit CS?
water-breathing fish
which vertebrates have double circuit CS?
air-breathing tetrapods (amphibians, birds, reptiles, mammals)
What does it mean for the structure of the heart if there’s only one CS circuit?
only 2 chambers = 1 atrium, 1 ventricle
Describe the single circuit in water-breathing fish
heart pumps out deoxygenated blood via arteries over the gills which have capillaries to exchange O2 in water to oxygenate blood
oxygenated blood is carried through venules and veins throughout the body to exchange O2 with tissues
deoxygenated blood is carried back through veins to the heart
continue
What are the 2 circuits in double CS systems?
pulmonary circuit
systemic circuit
Why do water-breathing fish only have one circuit?
because they have a low metabolic rate = low O2 consumption, they do not require blood to be pumped out of the heart at super fast speed/high pressure
systolic pressure = 3045 mm Hg
Why do mammals require double circuits?
higher metabolic rate and O2 consumption requires heart to pump out blood faster and at higher pressures to move further distances quicker
need a mechanism to decrease pressure coming out of heart to avoid exploding blood vessels = 2 systems
systolic pressure = 120-180 mmHg
How does the systolic pressure of mammals compare to water breathing fish?
mammals = 120-180 mmHg
fish = 30-45 mm Hg
What side of the heart is the pulmonary circuit controlled by?
the right side
What is the function of the pulmonary circuit?
the right side of the heart pumps deoxygenated blood to the capillaries at respiratory tissues to pick up O2 and brings oxygenated blood back to the heart
What side of the heart is the systemic circuit controlled by?
the left side of the heart
What is the function of the systemic circuit?
the left side of the heart pumps oxygenated blood from the pulmonary system into the rest of the body
the veins bring back deoxygenated blood into the right side of the heart to enter the pulmonary system
Does the pulmonary system have high or low systolic pressure?
low
Does the systemic system have high or low pressure?
high
How many chambers do amphibian and non-bird reptilian hearts have? how is it divided?
only partially
into 2 atria and 1 ventricle
frogs have 3 chambered hearts
non-crocodilian lizards have 5 chambered hearts
How many chambers do frog hearts have?
3
How many chambers do non-crocodilian reptiles have?
5
Describe the pattern of blood flow in frog hearts
both atria pump blood into the ventricle and the ventricle pumps blood into pulmonary and systemic circuits
ventricle pumps deoxygenated blood into pulmonary circuit for lungs and skin capillaries
oxygenated blood returns to the heart
ventricle pumps oxygenated blood into systemic circuit to tissues in body and deoxygenated blood returns to heart
the return of deoxygenated blood to the heart from the systemic system and the oxygenated blood entering from the pulmonary system is where deox and ox blood mix
In amphibians and non-crocodilian reptiles, explain how the heart is only partially divided
oxygenated and deoxygenated blood are mostly separate but can mix and blood can be diverted between pulmonary and systemic circuits
Describe fluid flow in the decapod crustacean (arthropod) heart
open CS - fluid is hemolymph
heart pumps hemolymph out through arteries
hemolymph returns to heart via ostia during diastole (relaxation of heart)
What regulates the flow of hemolymph in crustacean hearts?
the opening and closing of ostia during systole and diastole (contraction and relaxation of the heart)
closed during systole
open during diastole
Where do signals for the crustacean heart to contract originate from (ie., neuro or myogenic)?
neurogenic
How is the crustacean heart situated within the body?
its suspended by ligaments
Describe the cardiac cycle steps in arthropods
spontaneous rhythmic depolarization of cardiac ganglia neurons causes
cardiomyocetes (cardiac muscles) to contract which
decreases volume of heart to increase pressure
increase in pressure closes ostia
hemolymph is pushed out of heart via arteries
ligaments suspending heart stretch - expanding walls of the heart
heart volume increases to decrease pressure
ostia open
hemolymph is sucked into the heart
(just follow pressure gradient - increased pressure in heart will push hemolymph out, decreased pressure in heart will pull hemolymph in)
What are the 4 layers of vertebrate heart walls?
pericardium
epicardium
myocardium
endocardium
What is the pericardium in vertebrate heart walls?
the outermost tissue composed of connective tissues that surround the heart
it includes the epicardium because the pericardium has 2 parts the parietal and visceral layers and the epicardium is the visceral pericardium
between the parietal and visceral layers there’s the pericardial fluid for protection
What is the epicardium in vertebrate heart walls?
aka the visceral pericardium - the inner layer of the pericardium
it is continuous with connective tissue on the heart and contains the nerves that mediate heart and coronary arteries
