Size & Scaling (W2)

Question 1

Scaling?

Answer 1

= the structural & functional consequences that occur due to changes in size.

Question 2

Who is the person behind the scaling theory and what year?

Answer 2

• Galileo Galilei.
• 1638.

Question 3

3 Engineering Principles of Scaling to maintain performance of a structure?

Answer 3

• Change dimensions.
• Change materials.
• Change architecture/anatomy.

Question 4

Change dimensions?

Answer 4

= states that as the structure scales, the proportional dimensions might change as well.

Question 5

Changing materials?

Answer 5

= states that materials and their properties directly affect scaling.

Question 6

Changing architecture/anatomy?

Answer 6

= states that as the structure scales, the architecture changes.

Question 7

Why doesn’t the T-rex catch the Jeep?

Answer 7

• As muscle strength increases, cross-sectional area increases &
• As body mass increases, volume increases.

Therefore, because muscle strength doesn’t scale as fast as muscle mass the T-rex doesn’t have the strength to move the muscle gained through increased body mass.

Question 8

Explain the relationship between scaling, metabolism & endurance. (2)

Answer 8

• Since small animals like shrews and hummingbirds burn through their fat reserves very quickly (high metabolism), they tend to turn to torpor in order to reserve more energy (endurance).

• On the other hand, because large animals like bears burn through their fat reserves at much slower rates (low metabolism) they tend to turn to hibernation (endurance).

Question 9

Explain the relationship between scaling and time.(2)

Answer 9

• The bigger you are (increased body mass), the slower your heartbeat, the slower your respiration rate and the longer your lifespan.
[Eg. Mice & Elephants].

• Physiological time scales differentially with clock time.
[Eg. Tortoise].

Question 10

Explain relationship between scaling and skeleton mass in mammals & birds.

Answer 10

At any given body mass, it turns out that the skeleton mass of birds is the same as the skeleton mass of mammals but:

• Birds have denser skeletons (in some areas).
• Birds have bone geometry that increases stiffness & strength at smaller sizes.

Question 11

Allometry?

Answer 11

= where scaling changes are not proportional across measured variables.

Question 12

Isometry?

Answer 12

= where scaling changes are proportional across measured variables.

Question 13

State Kleiber’s Law

Answer 13

= states that our metabolism does not grow proportionally with our body weight.

Question 14

State the Surface rule?

Answer 14

= states metabolism is predicted to scale to the ⅔power relative to body mass.

Question 15

What is ontogeny?

Answer 15

= involves organism development.

Question 16

Allometry & Ontogeny?

Answer 16

Because an organism’s development occurs, body proportions may change allometrically. Therefore, this poses a problem for paleontologists as they may mistake such an occurrence for species-level distinction & confuse the different developmental stages for different species.

Question 17

Paedomorphosis?

Answer 17

= an occurrence where an organism retains its juvenile proportions into adulthood.

Question 18

Simpler way of defining scaling?

Answer 18

= as animals get bigger, their anatomical & physiological features differ.

Question 19

Explain Galileo’s theory?

Answer 19

Noticed that animals don’t scale proportionally as they go and that scaling often applied in Engineering could be applied to biology as well.

Question 20

How do engineers & animals overcome problems due to scaling?

Answer 20

They use the 3 Engineering principles.

Question 21

Eg of Changing dimensions in Engineering?

Answer 21

Irish wall & Great wall of China
= the taller the wall, the thicker the base should be to maintain structure stability.

Question 22

Eg of Changing dimensions in Biology?

Answer 22

Tetrapods
= as an animal gets bigger, the thickness of the skeleton may increase.

Question 23

Eg of Changing materials in Engineering?

Answer 23

Philadelphia city wall & Burj Khalifa
= tallest masonry building (167m) vs tallest steel building (829.8m).

Question 24

Eg of Changing materials in Biology? (2)

Answer 24

• Evolution of bone from cartilage/poor ossification to bone.

• Tetrapods
= alter bone density & cross-sectional geometry to shift to new material properties (Kestrel vs Penguin).

Question 25

Eg of Changing architecture in Engineering?

Answer 25

Danhe bridge & Golden gate bridge
= compression bridge vs tension bridge (better).

Question 26

Eg of Changing architecture in Biology? (2)

Answer 26

Tetrapods
= either means this or that:

• Change in posture (eg Kangaroo).
OR
• A novel adaptation.

Question 27

Novel adaptation?

Answer 27

= a feature that enables thicker & bigger animals to exist.

Question 28

Running?

Answer 28

= moving your body mass using your muscle strength.

Question 29

Do birds have proportionally lighter skeletons than mammals?

Answer 29

No, birds have the same skeletal mass as that of mammals but birds have denser skeletons on some areas & have bone geometry that increases stiffness & strength at smaller sizes.

Question 30

Eg of answer to bird & mammal skeleton mass?

Answer 30

Seen in a comparison between Kestrel & Penguin.

Question 31

Torpor?

Answer 31

= involuntary state that an animal enters into when conditions dictate as a survival tactic to survive winter conditions & occurs over short periods of time (several times a day).

Question 32

Hibernation?

Answer 32

= voluntary state that an animal enters into to (i) conserve energy, (ii) survive through food scarcity & (iii) minimize their need to face elements in cold, winter months & it occurs over long periods of time (days, weeks, months).

Question 33

Main take-home principle for scaling?

Answer 33

Size has effects for the functional, physiological (behaviour) & temporal aspects of living organisms like lifespan.

Question 34

Why do animals lose they’re limbs as they go & reside in the water?

Answer 34

As they reside in the water, animals get bigger and heavier which results in them nolonger needing limb support (heavy upper body), losing their limbs & a change in their architecture.

Question 35

Why is there a thicker bone cortex in penguins than Kestrel even though they’re both birds?

Answer 35

Penguins have a thinner bone Cortex than Kestrel because they don’t fly and mostly go into the water. Therefore, they don’t need “light” bones/less dense bones as they don’t fly.

Question 36

Allometry is AKA?

Answer 36

Different measurement after scaling changes.

Question 37

Isometry is AKA?

Answer 37

Equal measurement after scaling changes.

Question 38

Explain the graph of: Relationship of length, surface area & volume? (3)

Answer 38

• As the sides of a cube increase in length, the length relationship maintains the exact same scale and thus scales isometrically with the sides.

• SA with regards to length increases rapidly while volume with respect to length increases even more rapidly.

• One thing to note is that interpretation of the graph is a bit difficult due to the curves.

Question 39

Solution to difficult interpretation of graphs with curved lines?

Answer 39

Logging.

Question 40

Uses of logging? (3)

Answer 40

• Straightens curves into a linear plot.
• Makes it easier to interpret/read graphs.
• Useful when there’s a large range of values.

Question 41

Explain graph of: Logarithmic relationship of length, surface area & volume of a cube?

Answer 41

From slopes, we see that volume increases at a much faster rate than SA.

Question 42

Allometric equation?

Answer 42

y = ax^b

Question 43

What does each symbol in equation mean? (3)

Answer 43

• x, y = measurement variables (SA, volume).
• a = proportionality coefficient (y-intercept).
• b = scaling factor.

Question 44

Why is b important?

Answer 44

Dictates how fast a measurement variable changes.

Question 45

Name the 4 scenarios/egs of the scaling factor, b?

Answer 45

• Skeletal mass vs Body mass.
• Metabolic rate vs Body mass.
• Heart rate vs Body mass.
• Hematocrit vs Body mass.

Question 46

Value of b in Scenario 1?

Answer 46

b=1.

Question 47

Value of b in Scenario 2?

Answer 47

0 < b < 1.

Question 48

Value of b in Scenario 3?

Answer 48

b<0.

Question 49

Value of b in Scenario 4?

Answer 49

b=0.

Question 50

Scenario 1? (2)

Answer 50

• Skeletal mass is relatively isometric with regards to body mass.
• Graph is slightly positively allometric.

Question 51

Scenario 2? (2)

Answer 51

• Metabolic rate is negatively allometric with respect to body mass.
• The larger you are, the proportionally lower your metabolic rate.

Question 52

Scenario 3? (2)

Answer 52

• Heart rate decreases as the body mass increases.
• Relationship is inversely allometric.

Question 53

Scenario 4? (3)

Answer 53

• No allometric relationship exists between Hematocrit & body mass.
• Graph shows that small & large animals have the same amount of blood volume in their bodies.
• Tells us that scaling doesn’t affect everything.

Question 54

Inverse allometry?

Answer 54

= where one variable increases as the other decreases.

Question 55

Positive allometry?

Answer 55

= where one variable increases faster than the other.

Question 56

b>1 ?

Answer 56

= positive allometry.

Question 57

0<b<1 ?

Answer 57

= negatively allometry.

Question 58

b=1 ?

Answer 58

= isometry.

Question 59

b=0 ?

Answer 59

= no relationship.

Question 60

b<0 ?

Answer 60

= inverse allometry.

Question 61

Eg of 0<b<1?

Answer 61

Metabolic rate vs Body mass.

Question 62

Eg of b=1?

Answer 62

Skeletal mass vs Body mass.

Question 63

Eg of b=0 ?

Answer 63

Hematocrit vs Body mass.

Question 64

Eg of b<0 ?

Answer 64

Heart rate vs Body mass.

Question 65

Eg of b>1 ?

Answer 65

Limb length vs Body mass of monitor lizards.

= Limbs are relatively longer in larger-bodied monitor lizards.

Question 66

Allometry & “Surface rule”? (4)

Answer 66

• Metabolic rate scales to the 2/3.
• Larger you are, less SA and less heat loss.
• true, to some extent, because of torpor & hibernation.
• FALSE.

Question 67

Kleiber’s law? (4)

Answer 67

• Metabolism actually scales to the 3/4 power.
• Negative allometric relationship between metabolism & body mass.
• Larger you are, more SA, more heat loss.
• Exceptions exist at high and low body masses.

Question 68

Why doesn’t metabolic rate scale to the 2/3 power? (2)

Answer 68

• Constraints might exist on small & large animals.
• Extinct animals have different metabolic scaling properties.

Question 69

Categories under Allometry & Flight? (2)

Answer 69

• Metabolism vs Pectoral muscle mass.
• Flapping frequency vs Body mass.

Question 70

Metabolism vs Pectoral muscle mass?

Answer 70

As birds get larger, Metabolic rate decreases & birds may eventually not be able to produce the metabolic activity needed to fly.

Question 71

Limit of Metabolism vs Pectoral muscle mass?

Answer 71

10kg-20kg.

Question 72

Metabolism vs Pectoral muscle mass relationship?

Answer 72

Pectoral muscle mass scales isometrically in birds while MR scales with negative allometry.

Question 73

Flapping frequency vs Body mass?

Answer 73

As birds get heavier, flapping frequency decreases. Therefore, if wings can’t flap fast enough, bird cannot take off.

Question 74

Flapping frequency vs Body mass relationship?

Answer 74

Inverse allometry.

Question 75

Limit for flapping frequency vs body mass?

Answer 75

41kg.

Question 76

Egs of heaviest flying birds? (2)

Answer 76

• Kori bustard (17kg) = extant.
• Argentaris (70kg) = extinct.

Question 77

Eg of Allometry & Ontogeny?

Answer 77

Human development
= as humans develop from an infant to an adult, the proportions of the head decrease while that of the legs increase.

Question 78

Eg of paedomorphosis? (2)

Answer 78

• Humans (retained juvenile facial features).
• Birds (dinosaur skulls).

Question 79

2 things to note regarding paedomorphosis?

Answer 79

• form of allometry.
• pathway to macroevolution.

Question 80

Why is Micky Mouse so popular?

Answer 80

= Micky Mouse has become more paedomorphic over time & thus cuter.

Question 81

Take-home principle of Allometry?

Answer 81

Allometry controls anatomy & physiology.