Chapter 9: Cardiac Muscle

Question 1

Cardiac muscle is under the control by the ___ nervous system

Answer 1

autonomic nervous system

Question 2

Is cardiac muscle neurogenic or myogenic

Answer 2

myogenic through pace maker potentials.

Question 3

If cardiac muscle is myogenic, what is the role of the autonomic nervous system then?

Answer 3

although cardiac muscle can contract on its own, the nervous system modifies contraction, can excite or inhibit, and can contribute to gradation

Question 4

What is the general speed of myosin ATPases in cardiac muscle? (and thus speed of contraction)

Answer 4

slow

Question 5

What is the means by which cardiac gradation is accomplished`

Answer 5

varying length of fibers (depending on extent of the filling of the heart chambers) and varying cytosolic Ca2+ concentration through autonomic, hormonal and local metabolite influence.

Question 6

2 Unique characteristics of cardiac muscle

Answer 6

1) cardiac fibers are joined together in a branching network 2) action potentials have a much longer duration before repolarizing due to calcium influx while K+ is effluxing, prevents the cell from going back to negative polarization as fast.

Question 7

cardiac muscle fibers branch adn are interconnected by ___ ___

Answer 7

intercalated disks

Question 8

Why do we need circulatory systems?

Answer 8

1) simple diffusion takes too long 2) larger animals have thicker bodies and higher metabolic rates 3) circulatory systems overcome the slowness of diffusion and allow for much faster bulk transport.

Question 9

3 distinct components of a circulatory system

Answer 9

1) fluid: blood or hemolymph, which carries the molecules and cells than need to be transported 2) pump: dedicated pumps are called hearts; moves the fluid 3) vessels: vascular components that carry the fluid between the pump and body tissue.

Question 10

2 broad categories of circulatory systems

Answer 10

1) open systems 2) closed system

Question 11

explain an open system. What organisms use them?

Answer 11

a circulatory system in which HEMOLYMPH moves vvia pumping through vessels that open into an extracellular space among the tissues. Tissues are bathed in fluid and directly exchange molecules with cells. The fluid may be moved by cilia or hearts around the tissue, and vessels (arteries) typically drain the hemolymph back to starting point Found in most mollusks and all arthropods.

Question 12

What is a hemocoel? what can it be divided into?

Answer 12

a hemocoel is used in an open circulatory system and is the entire space that is filled with hemolymph. It may be subdivided into sinuses.

Question 13

In an open system, hemolymph flows from the pump through an ___ into the ___ (a space among the tissues), and drain from the _____ through a ___ back to the pump.

Answer 13

In an open system, hemolymph flows from the pump through an ARTERY into the HEMOCOEL (a space among the tissues), and drain from the HEMOCOEL through a VEIN back to the pump.

Question 14

explain a closed circulatory system

Answer 14

BLOOD (rather than hemolymph) exits a heart throguh vessels that are continuous all the way back to the heart. -vessels branch and become smaller until they become tiny leaking capillaries and molecules can be directly exchanged with cells - vessel s that merge and become larger before going back to the heart.

Question 15

2 primary components of a circulatory fluid (either blood or hemolymph)

Answer 15

1)plasma: mostly water containing dissolved and dispersed plasma proteins 2) cellular elements: hemolymph/blood cells, leukocytes etc.

Question 16

Outline the four different types of pumping mechanisms

Answer 16

1) flagella 2) extrinsic/ skeletal muscle pumps 3) peristaltic musclar pumps 4) chamber muscle pumps.

Question 17

How do flagella act as a pump

Answer 17

they portrude out of epithelial cells and beat slowly to create a slow current. seen in sponges.

Question 18

How does extrinsic skeletal muscle act as a pump? Give an example. What must the animal be doing in order for skeletal muscle to act as a pump?

Answer 18

because motion of muscles or skeletal elements which are NOT apart of the normal circulatory system can move fluids. This can usually only occur during locomotion. Therefor, the animal usually needs to be moving. Seen in legs of tall animals: blood flow is aided by active skeletal muscles squeezing blood through one-way valves in veins, and by the action of the respiratory muscles in breathing.

Question 19

How do peristaltic muscle pumps function? what is the other name for this type of pump?

Answer 19

perstaltic aka TUBULAR muscle pumps. Occurs when muscles in the WALLS of vessels contract in a moving wave that pushes fluid in FRONT of it. Allows for unidirectional fluid flow.

Question 20

At what point are peristaltic muscle pumps called hearts?

Answer 20

they are called hearts if they occur in specialized sections of vessels.

Question 21

compared to peristaltic muscle pumps, how to chambered muscle pumps prevent backflow?

Answer 21

peristaltic muscle pumps can contract in such a way that the fluid only moves one way. However, chambered pumps need VALVES to create flow in one direction to prevent back flow when the pump relaxes.

Question 22

2 primary chambers in a chambered pump system

Answer 22

1) atrium: collects returning fluid 2) ventricle: provides the primary force for outgoing fluid.

Question 23

most animals have a primary ____ heart that provides the initial force, and an auxillary pump, that does what?

Answer 23

most animals have a primary SYSTEMIC heart that provides the initial force, and an auxillary pump that AIDS FLOW RETURNING TO THE PRIMARY HEART OR FLOW GOING TO CRITICAL ORGANS.

Question 24

Example of an auxillary pump

Answer 24

in bees, they have a PULSATILE ORGAN that boosts flow to their wings.

Question 25

comparative heart anatomy: crustaceans, insects, and arachnids have hearts that are located in the ___ region of the body.

Answer 25

DORSAL.

Question 26

In major arthropod groups, each hear has a porelike opening called an ____ that usually has a one way valve. What is its function?

Answer 26

They usually have OSTIUM, allows hemolymph to reenter the heart after passing through the body.

Question 27

Comparative heart anatomy: Heart differences between major arthropod groups?

Answer 27

• larger crustaceans have a SINGLE chamber pump, whereas insects and arachnid hearts are TUBULAR (basically are just modified vessels) and can use peristaltic pumping.

Question 28

Basic structure of a primitive systemic vertebrate heart

Answer 28

a 2 chambered heart: one atrium and one ventricle.

Question 29

In fish, there are ____ primary chambers, and ___ auxillary chambers.

Answer 29

2 primary chambers (Atrium and ventricle) , 2 auxillary chambers (sinus venosus and bulbis/conus arteriosis).

Question 30

In fish, blood enters a chambered extension of the atrium called the ___ ___. Whats its function?

Answer 30

blood enters a chambered extension of the atrium called the SINUS VENOSUS; collects blood from the veins before entering the atrium.

Question 31

In fish, blood leaving the VENTRICLE first enters a chambered extension called the ___ ___ in CARTILAGINOUS FISH, or ___ ____ in BONY FISH.

Answer 31

In fish, blood leaving the VENTRICLE first enters a chambered extension called the CONUS ARTERIOUS in CARTILAGINOUS FISH, or BULBUS ARTERIOSUS in BONY FISH.

Question 32

Purpose of the conus arterious or bulbus arteriosus ?

Answer 32

these areas a fourth chambers in fish that extend from the ventricle. They help to dampen the pulsatile pressure output of the ventricle (a function taken over by the aorta in reptiles)

Question 33

See notebook for a diagram of fish (ELASMOBRANCH) heart. What is the direction of venous blood flow?

Answer 33

Venous blood enters the sinus venosus, and is then pumped by the atrium, ventricle, and bulbis cordis into the aorta.

Question 34

In air-breathing vertebrates, evolution of a separate circuit called the ___ ___ ___ occurred.

Answer 34

Pulmonary Circulation System.

Question 35

Describe the newly evolved pulmonary circulation system in air breathing vertebrates. How are the chambers for the two circulation systems separated?

Answer 35

there is a separate part of the chambered heart to move fluid (blood) from the heart to the lungs, and then from the heart to the body. There are now two primary chambers subdivided with SEPTA to support separate circulation.

Question 36

Avian and mammal hearts are ____ pumps

Answer 36

dual pumps. One is a circulatory pump to body and the other is a pump to the lungs.

Question 37

In dual pump systems, atria RECEIVE blood from ___ and ___, and ventricles PUMP blood to ___ and ____

Answer 37

In dual pump systems, atria RECEIVE blood from LUNGS and BODY, and ventricles PUMP blood to BODY and LUNGS

Question 38

___ prevents the mixing of oxygenated blood with unoxygenated blood

Answer 38

SEPTA

Question 39

blood returning from the systemic circulation enters the ___ atrium via the ___ ___ This partially deoxygenated blood flows from the ____ atrium to the ventricle, which pumps it out through the ___ ___ to the LUNGS.

Answer 39

blood returning from the systemic (BODIL) circulation enters the RIGHT atrium via the VENA CAVAE. This partially deoxygenated blood flows from the RIGHT atrium to the ventricle, which pumps it out through the PULMONARY ARTERY to the LUNGS.

Question 40

The right side of the heart pumps blood into the ____ circulation

Answer 40

pulmonary

Question 41

After being oxygenated in the lungs, the blood returns to the ___ atrium via the ____ ___. The ___ atrium pumps the oxygenated blood to the ventricle and then exits thorugh the ____ to propel the blood to all body systems.

Answer 41

After being oxygenated in the lungs, the blood returns to the LEDT atrium via the PULMONARY VEINS The LEFT atrium pumps the oxygenated blood to the ventricle and then exits thorugh the AORTA to propel the blood to all body systems.

Question 42

the left side of the heart pumps blood into the ____ circulation

Answer 42

systemic

Question 43

the pulmonary circulation is a ___-pressure, ___-resistance system, whereas the systemic circulation is a ___-pressure, ___-resistance system.

Answer 43

the pulmonary circulation is a LOW-pressure, LOW-resistance system, whereas the systemic circulation is a HIGH-pressure, HIGH-resistance system.

Question 44

Mechanism by which heart valves close

Answer 44

due to pressure differences. A forward pressure gradient (greater pressure behind the vlave) forces the valve open, whereas backward pressure gradient (greater pressure in front of the valve once all the blood has flown past the valve) forces the valve closed.

Question 45

The AV vales are located between the ___ and ___

Answer 45

between teh atrium and ventricle.

Question 46

The aortic (between left ventricle and aorta) and pulmonary valve (between right ventricle and pulmonary artery to lung) are known as ____ valves.

Answer 46

semilunar valves

Question 47

the semilunar valves are forced open when :

Answer 47

the left and right ventricular pressures EXCEED the pressure in the aorta and pulmonary ARTERIES respectively.

Question 48

closure of semilunar valves happen when the ventricles ____, resulting in a falling of ventricular ____

Answer 48

closure of semilunar valves happen when the ventricles RELAX, resulting in a falling of ventricular PRESSURE (below the aortic and pulmonary artery pressures)

Question 49

the right AV valve is aka ____, and the left AV valve is aka____, and the aortic/pulmonary valves are aka ____

Answer 49

the right AV valve is aka TRICUSPID, and the left AV valve is aka MITRAL, and the aortic/pulmonary valves are aka SEMILUNAR

Question 50

Why are there no valves between the atria and the veins (ex/ venae cava that drains de oxy blood into right atrium?)

Answer 50

1) atrial pressures are not much higher than venous pressures, resulting in insignificant backflow 2) the junctions of the veins and atria are partially compressed during atrial contraction.

Question 51

Most of the heart wall is the ____. this layer lies between the ___ and the ____.

Answer 51

Most of the heart wall is the MYOCARDIUM. this layer lies between the ENDOCARDIUM and the EPICARDIUM (outer sheath).

Question 52

the myocardium consists of interlacing bundles of ____ ___ ___

Answer 52

cardiac muscle fibers.

Question 53

individual cardiac muscle cells that interconnect to form branching fibers of the myocardium are joined to each other via specialized structures known as ___ ___

Answer 53

intercalated disks

Question 54

two types of membrane junctions in the intercalated disks

Answer 54

1) desosomes: an adhering junction that mechanically holds cells together under high mechanical struss 2) gap junctions : channels that allow action potenitals to spread from one cardiac cell to the next.

Question 55

when an AP impulse is initiated, the impulse spreads to all the other cells that are joined by gap junctions so that they can:

Answer 55

contract together as a single FUNCTIONAL SYNCYTIUM.

Question 56

what is a functional syncytium

Answer 56

a group of joined cells that act as one functional unit.

Question 57

In skeletal muscles, graded contractions can be produced by :_______. can this happen in cardiac muscle?

Answer 57

In skeletal muscles, graded contractions can be produced by VARYING THE NUMBER OF MUSCLE CELLS THAT ARE CONTRACTING WITHIN THE MUSCLE (RECRUITMENT OF MOTOR UNITS) This does not happen in cardiac muscle fibers because the muscle cells are all grouped together in a functional synctium and thus the contraction onf one cell leads to the cotnraction of others. therefore, either all cardiac muscle fibers contract or none do. You cannot have a partial contraction unless there is liek some sort of problem in the gap junction.

Question 58

a heart beat is caused by an ___ ___ that sweeps across the cardiac muscle cell membrane

Answer 58

ACTION POTENTIAL

Question 59

cardiac action potentials are generated by _____ ____ ____

Answer 59

MYOGENIC PACEMAKER CELLS (they are auto-rhthmic)

Question 60

T/F: the pacemaker cells are contractile

Answer 60

false

Question 61

What is the resting potential of the pacemaker cells?

Answer 61

they do not have a constant resting potential. the cell polarizes and depolarizes in a cyclical fashion. membrane potential slowly depolarizes until threshold potential is reached and an action potential occurs.

Question 62

What gives rise to pacemaker potentials in terms of ion movement?

Answer 62

1) an increased inward Na+ current 2) a decreased K+ efflux 3) an increased inward Ca2+ current.

Question 63

In a graphical form, outline the ion movement during a pacemaker potential.

Answer 63

During the first part of the potenital, there is Na+ influx, followed by K+ efflux reduction, resulting in a growing of positive potential in the cell. Once at threshold, voltage gated Ca2+ channels open and Ca2+ moves into the cells, causing an action potential.