Comparative Anatomy & Physiology: Circulatory System (W12a)

Question 1

Theories of how Brachiosaurus supplied blood to its head? (3)

Answer 1

• Had a massive & strong heart.
• Had multiple hearts in its neck to reach heights.
• Never lifted its head.

Question 2

Circulatory system functions? (3)

Answer 2

• Provides a rapid mass flow of material from in one part of the body to another over distances with slow diffusion occurring.

• Transport system of many products.

• Immune defence.

Question 3

Products that circulatory system transports? (5)

Answer 3

• O2 & CO2.
• Waste products.
• Nutrients.
• Metabolites.
• Hormones.

Question 4

Circulatory system types? (2)

Answer 4

• Simple circulatory system.
• Complex circulatory system.

Question 5

Egs of oganisms with a simple circulatory system? (3)

Answer 5

• Flatworms.
• Sponges.
• Jellyfish.

Question 6

Simple circulatory system?

Answer 6

= system where diffusion allows for adequate transfer of materials (esp. Sponges).

Question 7

How does diffusion occur in simple circulatory system?

Answer 7

Through the epidermis & gastrovascular compartment (esp. Flatworms & Jellyfish).

Question 8

Circulatory system components? (3)

Answer 8

• Vascular system (blood vessels).
• Circulating fluid (blood/haemolymph).
• Pump to maintain fluid flow (heart).

Question 9

Haemolymph?

Answer 9

= invertebrate blood.

Question 10

Haemolymph constituents? (2)

Answer 10

• Plasma.
• Hemocyte.

Question 11

Hemocyte?

Answer 11

= single type of blood cell found in invertebrate blood.

Question 12

Hemocyte functions? (2)

Answer 12

• Haemostasis (prevention of bleeding).
• Defence against microbes.

Question 13

Vertebrate blood constituents? (3)

Answer 13

• Plasma.
• Cells.
• Cell fragments (platelets).

Question 14

Types of cells found in vertebrate blood? (2)

Answer 14

• Erythrocytes.
• Leukocytes.

Question 15

Erythrocytes is AKA?

Answer 15

Red blood cells.

Question 16

Leukocytes are AKA?

Answer 16

White blood cells.

Question 17

Blood plasma constituents? (5)

Answer 17

• Water.
• Protein.
• Lipids.
• Electrolytes.
• Glucose.

Question 18

Platelets function?

Answer 18

Blood clotting.

Question 19

Erythrocytes functions? (2)

Answer 19

• Transports gases (O2) & nutrients.
• Prevents excretion of haemoglobin (containers of Hb).

Question 19

Leukocytes function?

Answer 19

Immune response.

Question 20

Blood function?

Answer 20

Regulation of the body’s systems & homeostasis.

Question 21

Immunity types? (2)

Answer 21

• Innate immunity.
• Acquired immunity.

Question 22

Innate immunity is AKA?

Answer 22

General immunity.

Question 23

Innate immunity?

Answer 23

= involves certain leukocytes being able to recognize & destroy pathogens.

Question 24

What does Innate immunity involve?

Answer 24

Phagocytosis.

Question 25

Acquired immunity?

Answer 25

= immunity to a disease that isn’t innate but has been acquired/received during life.

Question 26

Acquired immunity involves?

Answer 26

Antibodies.

Question 27

Eg of leukocytes involved in Innate immunity?

Answer 27

Monocytes.

Question 28

Eg of leukocyte involved in Acquired immunity?

Answer 28

Lymphocytes.

Question 29

Erythrocytes attributes? (2)

Answer 29

• Nucleate in all animal groups, except in mammals.
• Fewer & larger in lower vertebrates.

Question 30

Avian rbc attributes? (2)

Answer 30

• Oval.
• Large.

Question 31

Mammalian rbc attribute?

Answer 31

Biconcave disks.

Question 32

Hemoglobin?

Answer 32

= has 4 Fe molecules that bind to 4 O2 molecules.

Question 33

Respiratory pigments?

Answer 33

= proteins specialized for transport of O2.

Question 34

Respiratory pigments function?

Answer 34

Reversibly bind O2 & increase O2 in blood.

Question 35

Respiratory pigments kinds? (4)

Answer 35

• Red.
• Blue.
• Green.
• Violet.

Question 36

Egs of organisms with Red respiratory pigment? (2)

Answer 36

• Humans.
• Vertebrates.

Question 37

Egs of organisms with Blue respiratory pigment? (3)

Answer 37

• Crustaceans.
• Spiders.
• Octopus.

Question 38

Egs of organisms with Green respiratory pigment? (2)

Answer 38

• Segmented worms.
• Leeches.

Question 39

Eg of organism with Violet respiratory pigment?

Answer 39

Peanut worms.

Question 40

Explain Oxygen-Haemoglobin dissociation curve? (2)

Answer 40

• Shows the relationship between the partial pressure of O2 & the O2 saturation of haemoglobin.

• Describes the saturation percentage of oxyhaemoglobin at various partial pressures of O2.

Question 41

Right shift in Oxygen-Haemoglobin dissociation curve attributes? (7)

Answer 41

• High H+ (acid).
• High temperature.
• High PCO2.
• High 2,3-BPG.
• High altitude.
• Exercise.
• High O2 unloading to tissues (low affinity).

Question 42

Low affinity =…?

Answer 42

High O2 unloading to tissues.

Question 43

Exercise in terms of tissue?

Answer 43

= active respiring tissue.

Question 44

Left shift in Oxygen-Haemoglobin dissociation curve attributes? (6)

Answer 44

• Low H+ (basic).
• Low temperatures.
• Low 2,3-BPG.
• Low PCO2.
• Low O2 unloading to tissues (high affinity).
• Myoglobin.

Question 45

High affinity =…?

Answer 45

Low O2 unloading to tissues.

Question 46

Egs of Right shift? (2)

Answer 46

• Small mammals.
• Small birds.

Question 47

Egs of Left shift? (3)

Answer 47

• Diving animals.
• Lugworms (burrowers).
• Llama (high altitudes).

Question 48

2,3-BPG?

Answer 48

= promotes Hb transition from a high O2 affinity state to a low O2 affinity state.

Question 49

Egs of hypoxic environments? (3)

Answer 49

• Deep depths of the sea.
• Underground.
• High altitudes.

Question 50

Myoglobin attribute?

Answer 50

Abundant in very active & diving animals.

Question 51

Myoglobin?

Answer 51

= intracellular respiratory pigment found in muscle cells.

Question 52

Circulatory system categories? (2)

Answer 52

• Open circulatory system.
• Closed circulatory system.

Question 53

Open circulatory system?

Answer 53

= incomplete system of blood vessels where the circulating fluid isn’t enclosed in vessels.

Question 54

Open circulatory system components? (2)

Answer 54

• Haemocoel.
• Haemolymph.

Question 55

Why is the fluid in open circulatory system called Haemolymph?

Answer 55

It’s because the blood mixes with the interstitial fluid.

Question 56

Egs of organisms with an open circulatory system? (2)

Answer 56

• Arthropods (insects).
• Mollusks.

Question 57

Haemolymph function?

Answer 57

Bathes organs.

Question 58

Closed circulatory system?

Answer 58

= complete system of blood vessels where the circulatory fluid is enclosed in vessels.

Question 59

Closed circulatory system component?

Answer 59

Blood.

Question 60

Explain the flow of Haemolymph in the Open circulatory system?

Answer 60

Haemolymph circulates around the organs within the haemocoel & then re-enters the hearts through ostia.

Question 61

Explain the flow of Blood in the Closed circulatory system?

Answer 61

Blood circulates unidirectionally from the heart around the systemic circulatory route & then returns to the heart again.

Question 62

Egs of organisms with a Closed circulatory system? (2)

Answer 62

• Earthworms.
• Vertebrates.

Question 63

Pro of Closed circulatory system?

Answer 63

Regulates blood pressure.

Question 64

Why is circulatory fluid in Closed circulatory system called Blood?

Answer 64

It’s because blood is enclosed in blood vessels.

Question 65

Blood vessel types? (3)

Answer 65

• Arteries.
• Veins.
• Capillaries.

Question 66

Arteries?

Answer 66

= blood vessels that carry blood away from the heart.

Question 67

What are arteries made up of? (2)

Answer 67

• Smooth muscles (vasoconstriction).
• Elastic walls (withstand high pressure).

Question 68

Veins?

Answer 68

= blood vessels that carry blood towards the heart.

Question 69

What are veins made up of? (2)

Answer 69

• Smooth muscles.
• Valves.

Question 70

Valves functions? (2)

Answer 70

• Prevent backflow of blood.
• Ensure unidirectional blood flow.

Question 71

Capillaries?

Answer 71

= narrow-diameter tubes that are the sites for the exchange of nutrients, wastes & O2.

Question 72

Layout how blood vessels convert/converge/branch? (7)

Answer 72

Major arteries
|
Minor arteries
|
Arterioles
|
Capillaries/Capillary beds
|
Venules
|
Minor veins
|
Major veins

Question 73

What are Capillaries made up of? (2)

Answer 73

• Endothelium.
• Basement membrane.

Question 74

Fluid exchange between Capillaries & interstitial fluid / Capillary exchange? (3)

Answer 74

● Start of blood vessel
- Hydrostatic pressure > Osmotic pressure.

● Middle of blood vessel
- Hydrostatic pressure = Osmotic pressure.

● End of blood vessel
- Hydrostatic pressure < Osmotic pressure.

Question 75

At start of blood vessel attribute?

Answer 75

• Hydrostatic pressure > Osmotic pressure.

Question 76

At Middle of blood vessel attributes? (2)

Answer 76

• Hydrostatic pressure = Osmotic pressure.

• No net movement.

Question 77

At End of blood vessel attributes? (2)

Answer 77

• Hydrostatic pressure < Osmotic pressure.

• Reabsorption.

Question 78

Hydrostatic pressure?

Answer 78

= the pressure that any fluid in a confined space exerts.

Question 79

Osmotic pressure?

Answer 79

= the pressure needed to stop the flow of water or osmosis.

Question 80

Muscular pump types found in different organisms? (3)

Answer 80

• Extrinsic muscle pump.
• Pulsatile abdominal bulbs.
• Accessory pumps.

Question 81

Extrinsic muscular pump?

Answer 81

= contraction of skeletal muscle.

Question 82

Pulsatile abdominal bulbs?

Answer 82

= structures with ostia along the dorsal vessel that “suck” haemolymph from the haemocoel then propel it towards the head for distribution throughout the body.

Question 83

Accessory pumps of invertebrates?

Answer 83

= extra hearts that supplement the action of systemic hearts.

Question 84

Egs of invertebrates with accessory pumps? (2)

Answer 84

• Branchial heart of cephalopods.
• Caudal heart of hagfish.

Question 85

Chambered hearts of vertebrates attributes? (3)

Answer 85

• Propel blood by co-ordinated contraction of the muscular wall.
• Have atria.
• Have ventricles.

Question 86

System circuit types? (2)

Answer 86

• Single system circuit.
• Double system circuit.

Question 87

Single system circuit?

Answer 87

= system where blood flows through the heart once per cycle.

Question 88

Single system circuit attributes? (3)

Answer 88

• Have respiratory & systemic circulation in series.
• Must pass through 2 systems of the capillaries.
• Functions at relatively low blood pressure.

Question 89

Why is Hydrostatic pressure > Osmotic pressure at start of blood vessel?

Answer 89

To ensure that fluid in plasma is pushed out of the capillaries into the interstitial fluid that bathes the tissues.

Question 90

Why is Hydrostatic pressure < Osmotic pressure at the end of blood vessel?

Answer 90

It’s because of the loss of the watery plasma from the capillaries that creates a hyper-osmotic solution.

Question 91

Con of Single system circuit?

Answer 91

Limited efficacy of O2 delivery.

Question 92

Egs of organisms with a Single system circuit? (3)

Answer 92

• Teleost fish systemic circuit.
• Elasmobranch heart.
• Lungfish circulation.

Question 93

Teleost fish systemic circuit is AKA?

Answer 93

Myogenic heart.

Question 94

Gill circulation?

Answer 94

= circulation where the heart pumps the blood to the gills where gas exchange occurs & the blood is re-oxygenated.

Question 95

Systemic circulation?

Answer 95

= circulation the the blood continues to the rest of the body before arriving back at the heart.

Question 96

Muscular pump function?

Answer 96

To generate a pressure gradient to propel blood/haemolymph around the body.

Question 97

Why do some invertebrates depend on Extrinsic muscular pumps?

Answer 97

It’s because they don’t have a heart to propel haemolymph.

Question 98

Egs of organisms using extrinsic pumps? (2)

Answer 98

• Nematodes.
• Leeches.

Question 99

Teleost fish systemic circuit attributes? (7)

Answer 99

• Modulates heart beat.
• 2 chambered heart.
• 1 atrium & 1 ventricle.
• Has spongy myocardium.
• Has valves.
• Contains a sinus venosus.
• Contains a bulbous arteriosus.

Question 100

Sinus venosus function?

Answer 100

Provides a continuous flow of blood to the heart.

Question 101

Sinus venosus attributes? (3)

Answer 101

• Enlarged chamber in venous side of the heart.
• Receives deoxygenated blood.
• Has a pacemaker.

Question 102

Bulbus arteriosus?

Answer 102

= thickened muscular part on the arterial side of the teleost heart.

Question 103

Elasmobranch heart attributes? (6)

Answer 103

• 2 chambered heart.
• 1 atrium & 1 ventricle.
• Enclosed in a rigid pericardium to facilitate venous return.
• Contains sinus venosus.
• Contains conus arteriosus.
• Has cornal valves in arterial side of heart.

Question 104

Sinus venosus attributes in Elasmobranch hearts? (3)

Answer 104

Same as in Teleost fish systemic circuit.

Question 105

Conus arteriosus attributes? (3)

Answer 105

• On the arterial side of the heart.
• Composed of cardiac muscle.
• Has cornal valve internally.

Question 106

Cornal valves function?

Answer 106

Prevent blood backflow into the ventricle.

Question 107

Lungfish circulation attributes? (3)

Answer 107

• Bimodal respiratory system.
• Maintain a functional separation of oxygenated & deoxygenated blood.
• Partially divided atrium.

Question 108

How do Lungfish maintain a functional separation of oxygenated & deoxygenated blood?

Answer 108

Through the spiral folds found in the bulbus arteriosus.

Question 109

What do we mean when we say “Bimodal respiratory system”?

Answer 109

We mean that Lungfish are able to switch from a gill circuit when submerged in water to a pulmonary circuit when out of water.

Question 110

Double system circuit?

Answer 110

= circuit where blood flows through the heart twice per cycle.

Question 111

Egs of organisms with a Double system circuit? (3)

Answer 111

• Amphibian hearts.
• Reptilian hearts.
• Bird & Mammal hearts.

Question 112

Amphibian hearts attributes? (5)

Answer 112

• 3 chambered heart.
• 2 atria & 1 ventricle.
• Double circulatory system but heart is not completely separated.
• Trabeculae (divider).
• Diversity of respiratory exchange organs (O2 via lungs & skin).

Question 113

Trabeculae?

Answer 113

= muscle within the ventricle that functionally subdivides the spongy myocardium.

Question 114

Reptilian hearts attributes? (4)

Answer 114

• 3 chambered heart (interconnected).
• 2 atria & 1 ventricle.
• Lacks a conus arteriosus.
• Partial septum in ventricle.

Question 115

Partial septum function?

Answer 115

Prevents the mixing of oxygenated & deoxygenated blood.

Question 116

Pro of partial septum in reptilian hearts?

Answer 116

Supports the high metabolic rates required for their active terrestrial lifestyles.

Question 117

Result of lack of conus arteriosus in reptilian hearts?

Answer 117

Aortic arches & pulmonary arteries arise directly from the ventricle.

Question 118

Basic reptilian heart patterns recognized? (2)

Answer 118

• Chelonian hearts.
• Squamate hearts.

Question 119

Chelonians include? (2)

Answer 119

• Turtles.
• Tortoises.

Question 120

Squamates include? (2)

Answer 120

• Snakes.
• Lizards.

Question 121

Eg of organism with the most peculiar reptilian heart?

Answer 121

Crocodiles.

Question 122

Crocodilian hearts attributes? (4)

Answer 122

• 4 chambered heart.
• Completely divided ventricle.
• Right-to-left cardiac shunting.
• Foramen of Panizza.

Question 123

Foramen of Panizza?

Answer 123

= a hole that connects the left & right aortic arches after they leave the ventricles.

Question 124

Cardiac shunt kinds? (2)

Answer 124

• Right-to-left shunt.
• Left-to-right shunt.

Question 125

Right-to-left shunt attributes? (3)

Answer 125

• Low lung ventilation (apnea).
• High gastric acid secretion.
• Hypercapnic blood.

Question 126

Left-to-right shunt attributes? (3)

Answer 126

• High lung ventilation.
• Low gastric acid secretion.
• Hypocapnic blood.

Question 127

Apnea?

Answer 127

= ceased breathing/breathlessness.

Question 128

Hypercapnic blood?

Answer 128

= blood having a high level of carbon dioxide.

Question 129

Instances of Right-to-left shunt? (2)

Answer 129

• Diving animals.
• Foetal circulatory system.

Question 130

Pro of Left-to-right shunt?

Answer 130

Promotes myocardial oxygenation.

Question 131

Right-to-left shunt?

Answer 131

= systemic venous blood bypassing the pulmonary circulation.

Question 132

Left-to-right shunt?

Answer 132

= pulmonary venous blood bypassing the systemic circulation.

Question 133

Bird & Mammal hearts attributes? (6)

Answer 133

• 4 chambered heart.
• 2 atria & 2 ventricles.
• Completely separated double circulatory system.
• Compact myocardium with coronary circulation.
• No cardiac shunting.
• Arose independently (convergent evolution).

Question 134

Bird hearts attributes in addition to previously mentioned? (2)

Answer 134

• Right aortic arch.
• Reduced sinus venosus.

Question 135

Mammal hearts attributes? (2)

Answer 135

• Left aortic arch.
• Sinus venosus reduced to Purkinje fibres or pacemaker (sinoatrial node).

Question 136

Sinus venosus is reduced to what in Mammal hearts? (2)

Answer 136

• Purkinje fibres.
• Pacemaker (sinoatrial node).

Question 137

Contributors of the emergence of a 4 chambered heart in Bird & Mammal hearts? (3)

Answer 137

• Endothermy.
• Flight (high altitude).
• Large body mass.

Question 138

MR associations in circulatory system? (3)

Answer 138

• Cardiac output.
• Heart mass.
• Arterial blood pressure.

Question 139

Cardiovascular allometry relationships? (3)

Answer 139

High MR = High Cardiac output = need Large hearts.

Question 140

Body mass (BM) relationships relating to Cardiovascular allometry (elaborate)? (3)

Answer 140

• Bigger animals, Bigger hearts (Heart mass vs BM).

• Smaller animals, High msMR, High heart rates (msMR & Heart rate vs BM).

• Bigger animals, High mean arterial pressure (MAP vs BM).

Question 141

BM relationships relating to Cardiovascular allometry (list)? (3)

Answer 141

• Heart mass vs BM.
• msMR & Heart rate vs BM.
• MAP vs BM.

Question 142

Giraffe blood pressure effects? (4)

Answer 142

• High MAP due to thick left ventricle walls in a hypertensive giraffe.
• Reduced radius of left ventricular cavity.
• Reduced stroke volume & cardiac output.
• Constrained aerobic performance

Question 143

Answer Mystery question:

How did Brachiosaurus supply blood to its head?

Answer 143

Brachiosaurus didn’t lift its head and it’s assumed that it could be reaching for aquatic vegetation.

Question 144

What does the systolic blood pressure question mostly apply to?

Answer 144

Animals with long necks that have to pump blood against gravity.