3.1.1 Exchange surfaces Flashcards

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1
Q

Why do multicellular organisms require specialised

gas exchange surfaces?

A

Their smaller surface area to volume ratio means the distance that needs to be crossed is larger and substances cannot easily enter the cells as in a single-celled organism.

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2
Q

How is surface area to volume ratio calculated?

A

Ratio = Surface area/Volume

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3
Q

Name three features of an efficient gas exchange

surface

A
  1. Large surface area, e.g. root hair cells.
  2. Thin/short distance, e.g. alveoli.
  3. Steep concentration gradient, maintained by blood supply or ventilation, e.g. gills.
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4
Q

Describe the trachea and its function in the

mammalian gaseous exchange system.

A

● Wide tube supported by C-shaped cartilage to keep the air passage open during pressure changes.
● Lined by ciliated epithelium cells which move mucus, produced by goblet cells, towards the throat to be swallowed, preventing lung infections.
● Carries air to the bronchi.

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5
Q

Describe the bronchi and their function in the mammalian gaseous exchange system

A

● Like the trachea they are supported by rings of cartilage and are lined by ciliated epithelium cells and goblet cells.
● However they are narrower and there are two of them, one for each lung.
● Allow passage of air into the bronchioles.

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6
Q

Describe the bronchioles and their function in the

mammalian gaseous exchange system.

A

● Narrower than the bronchi.
● Do not need to be kept open by cartilage, therefore mostly have only smooth muscle and elastic fibres so that they can contract and relax easily during ventilation.
● Allow passage of air into the alveoli

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7
Q

Describe the alveoli and their function in the

mammalian gaseous exchange system.

A

● Mini air sacs, lined with epithelium cells, site of gas exchange.
● Walls only one cell thick, covered with a network of capillaries, 300 million in each lung, all of which facilitates gas diffusion.

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8
Q

Explain the process of inspiration and the changes

that occur throughout the thorax

A

● External intercostal muscles contract (while internal relax), pulling the ribs up and out.
● Diaphragm contracts and flattens.
● Volume of the thorax increases.
● Air pressure outside the lungs is therefore higher than the air pressure inside, so air moves in to rebalance.

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9
Q

Explain the process of expiration and the changes

that occur throughout the thorax.

A

● External intercostal muscles relax (while internal contract), bringing the ribs down and in.
● Diaphragm relaxes and domes upwards.
● Volume of the thorax decreases.
● Air pressure inside the lungs is therefore higher than the air pressure outside, so air moves out to rebalance.

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10
Q

Explain how a spirometer works.

A

Used to measure lung volume. A person breathes into an airtight chamber which leaves a trace on a graph which shows the volume of the breaths.

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11
Q

Define vital capacity.

A

The maximum volume of air that can be taken in or expelled from the lungs in one breath. Can be calculated from the spirometer graph by finding the maximum amplitude.

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12
Q

Define tidal volume.

A

The volume of air we breathe in and out during each breath at rest. Can be calculated from the spirometer graph by finding the amplitude at rest.

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13
Q

Define breathing rate.

A

The number of breaths we take per minute.
Can be calculated from the spirometer
graph by counting the number of peaks in
one minute.

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14
Q

Name and describe the two main features of a fish’s

gas transport system

A

Gills = located within the body, supported by arches, along which are multiple projections of gill filaments, which are stacked up in piles.
Lamellae = at right angles to the gill filaments, give an
increased surface area. Blood and water flow across them in opposite directions (countercurrent exchange system)

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15
Q

Explain the process of gas exchange in fish.

A

● Buccal cavity volume increased to enable water to flow in, reduced to increase pressure.
● Water is pumped over the lamellae by the operculum, oxygen diffuses into the bloodstream.
● Waste carbon dioxide diffuses into the water and flows back out of the gills

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16
Q

How does the countercurrent exchange system

maximise oxygen absorbed by the fish?

A

Maintains a steep concentration gradient, as water is always next to blood of a lower oxygen concentration. Keeps rate of diffusion constant and enables 80% of
available oxygen to be absorbed.

17
Q

Name and describe the three main features of an

insect’s gas transport system.

A

● Spiracles = holes on the body’s surface which may be
opened or closed by a valve for gas or water exchange.
● Tracheae = large tubes extending through all body
tissues, supported by rings to prevent collapse.
● Tracheoles = smaller branches dividing off the tracheae.

18
Q

Explain the process of gas exchange in insects.

A

● Gases move in and out of the tracheae through the spiracles.
● A diffusion gradient allows oxygen to diffuse into the body tissue while waste CO2 diffuses out.
● Contraction of muscles in the tracheae allows mass movement of air in and out.