B2.2 The Challenges of Size - Animal Transport Systems Flashcards

1
Q

What is surface area to volume ratio?

A

The surface of an area per unit volume of an object.

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2
Q

In what format should surface area to volume ratio be presented?

A
  • It should be calculated as a ratio
  • It should be simplified so volume = 1cm3
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3
Q

Why can a tapeworm rely upon diffusion alone to provide nutrients, where as multicellular organisms can not?

A

The larger the surface area to volume ratio the more easily and quickly nutrients can diffuse, as diffusion ratio’s are small e.g the tape worm.

Increase size of organism = decrease surface area to volume ratio, therefore diffusion distance becomes to great to allow an organism to meet the cells’ demands.

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4
Q

State three examples of adaptations to animal cells to improve surface area to volume ratio.

A

Villi - intestines

Microvilli - Cilliated epithelial cells lungs

Alveoli - spherical shape

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5
Q

State adaptations to plants to increase surface area to volume ratio.

A

Broad flat leaves - increase SA for capturing light & gaseous exchange via the stomata

Root hair cells

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6
Q

Explain the adaptations of the lungs to maximise the rate at which oxygen enters the body.

A
  • Single cell wall
  • Ventilation moves air in and out of lungs to maintain concentration gradient
  • Capillary network means good blood supply, which maintains concentration gradient
  • Spherical shape increases surface area
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7
Q

Explain the adaptations of the villi to maximise the rate of diffusion and active transport in the small intestine.

A
  • Single cell wall
  • Capillary network means good blood supply, which maintains concentration gradient
  • Fingerlike shape increases surface area
  • Microvilli increases surface area further
  • Many mitochondria to provide energy for active transport
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8
Q

Why are transport systems needed?

A

To transport a substance to where it is needed once it has diffused.

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9
Q

Name four transport systems in humans.

A

Respiratory

Circulatory

Digestive

Endocrinology

Nervous

Urinary

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10
Q

What is the circulatory system?

A

Heart and blood vessels

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11
Q

How does the circulatory system of a fish compare to the human circulatory system?

A

The fish has a single circulatory system, humans have a double circulatory system.

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12
Q

State the difference between oxygenated and deoxygenated blood.

A
  • Oxygenated = high levels of oxygen
  • Deoxygenated = low levels of oxygen
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13
Q

Name the the three types of blood vessel shown below.

A
  • A = vein
  • B = capillary
  • C = artery
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14
Q

Name the adaptations of the three blood vessels below.

A
  • A = vein, thin outer wall, thin layer of muscle and elestic fibres, large lumen
  • B = capillary, very small lumen, single cell wall
  • C = artery, thick outer wall, thick layer of muscle and elestic fibres, small lumen
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15
Q

Explain why humans are said to have a double circulatory system.

A

Blood is pumped out of the heart twice, once to the lungs and once to the rest of the body

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16
Q

What are the benefits of having a double circulatory system?

A
  • Deoxygenated and oxygenated blood does not mix
  • Blood is under higher pressure as it does not have to travel as far
  • High pressure means the materials are transported around the body more quickly
17
Q

State the difference between cardiac muscle and the muscles in the rest of your body?

A
  • Heart is made of cardiac muscle that contracts without recieving nerve impulses from our brain
  • Muscle in the rest of your body (e.g in your arm) require a nervous signal to stimulate contraction
18
Q

Label the heart below

A
19
Q

Describe the pathway through the human circulatory system.

A
  1. Deoxygenated blood enters the lungs.
  2. Oxygen enters the blood. CO2 leaves.
  3. Blood enters the heart through the pulmonary vein, into the left atria.
  4. Blood is pumped through the heart from the left artria to the left ventricle, via the bicuspid valve.
  5. Blood is pumped out of the left ventricle through the Aorta and goes to the rest of the body.
  6. Oxygen diffuses out of the blood and CO2 diffuses in.
  7. Blood enters the right atria of the heart through the vena cava.
  8. Blood is pumped through the heart from the right artria to the right ventricle, via the tricuspid valve.
  9. Blood is pumped out of the right ventricle, to return to the lungs via the pulmonary artery.
20
Q

Name the four key components of blood and their function.

A
  1. Red blood cells - small biconcave cells that contain haemoglobin and have no nucleus to enable and maximise oxygen transport.
  2. White blood cells - large cells fight disease by making antibodies, or changing their shape to engulf pathogens.
  3. Platelets - tiny structures/fragments of cells that help blood to clot
  4. Plasma - Made up of 90% water, straw coloured fluid in which the other components of blood float within. Acts as a transport emdium for digested food, wast products, hormones and antibodies.
21
Q

State the type of blood cell which is most common in the blood.

A

Red blod cells