OCR A Level Biology 3.1 Exchange Surfaces PDF

Summary

These notes cover Topic 3.1: Exchange and transport from OCR A Level Biology. The content details mammalian gaseous exchange, ventilation, and spirometry, including the role of structures like the lungs, trachea, and alveoli.

Full Transcript

OCR (A) Biology A-level

Topic 3.1: Exchange and transport
Notes

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The need for specialised exchange surfaces arises as the size of the organism, and its surface
area to volume ratio decreases. In the case of single celled organisms, the substances can
easily enter the cell as the distance that needs to be crossed over is short. However, in
multicellular organisms that distance is much larger due to a lower surface area to
volume ratio. As a result of that, multicellular organisms required specialised exchange
surfaces for efficient gas exchange of carbon dioxide and oxygen.

Features of an efficient exchange surface include large surface area, for instance the root
hair cells or folded membranes, such as those of the mitochondria. An efficient exchange
surface should also be thin to ensure that the distance that needs to be crossed by the
substance is short. The exchange surface also requires a good blood supply/ventilation to
maintain a steep gradient, for example that of the alveoli.

Mammalian gaseous exchange system
The lungs are a pair of structures with a large surface area located in the chest cavity with
the ability to inflate. The lungs are surrounded by the rib cage which serves to protect
them. A lubricating substance is secreted to prevent the friction between rib cage and
lungs during inflation and deflation. External and internal intercostal muscles between the
ribs which contract to raise and lower the ribcage respectively. A structure called the
diaphragm separates the lungs from abdomen area.

The air enters through the nose, along the trachea, bronchi and bronchioles which are
structures well adapted to their role in enabling passage of air into the lungs. The gaseous
exchange takes plance in the walls of alveoli, which are tiny sacs filled with air.

The trachea, bronchi and bronchioles enable the flow of air into and out of the lungs. The
airways are held open with the help of rings of cartilage, incomplete in the trachea to allow
passage of food down the oesophagus behind the trachea.

Trachea and bronchi are similar in structure, with the exception of size – bronchi are
narrower. They are composed of several layers which together make up a thick wall. The
wall is mostly composed of cartilage, in the form of incomplete C rings. Inside surface of
the cartilage is a layer of glandular and connective tissue, elastic fibres, smooth muscle
and blood vessels. This is referred to as the ‘loose tissue’. The inner lining is an epithelial
layer composed of ciliated epithelium and goblet cells.

The bronchioles are narrower than the bronchi. Only the larger bronchioles contain cartilage.
Their wall is made out of smooth muscle and elastic fibres. The smallest of bronchioles have
alveoli clusters at the ends.

Structures and functions of mammalian gaseous exchange system include:

Cartilage- involved in supporting the trachea and bronchi, plays an important role
in preventing the lungs from collapsing in the event of pressure drop during
exhalation

Ciliated epithelium – present in bronchi, bronchioles and trachea, involved in
moving mucus along to prevent lung infection by moving it towards the throat

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 Goblet cells – cells present in the trachea, bronchi and bronchioles involved in mucus
secretion to trap bacteria and dust to reduce the risk of infection with the help of
lysozyme which digests bacteria

Smooth muscle – their ability to contract enables them to play a role in constricting
the airway, thus controlling its diameter as a result and thus controlling the flow of
air to and from alveoli

Elastic fibres – stretch when we inhale and recoil when we exhale thus controlling
the flow of air

Ventilation
The flow of air in and out of the alveoli is referred to as ventilation and is composed of two
stages; inspiration and expiration. This process occurs with the help of two sets of muscles,
the intercostal muscles and diaphragm.

During inspiration, the external intercostal muscles contract whereas the internal ones
relax, as a result cause the ribs to raise upwards. The diaphragm contracts and flattens. In
combination, the intercostal muscles and diaphragm cause the volume inside the thorax to
increase, thus lowering the pressure. The difference between the pressure inside the lungs
and atmospheric pressure creates a gradient, thus causing the air to enter the lungs

During expiration, the internal intercostal muscles contract whereas the external ones relax
therefore lowering the rig cage. The diaphragm relaxes and rises upwards. These actions in
combination decrease the volume inside the thorax, therefore increasing the pressure, forcing
the air out of the lungs.

Spirometer
A spirometer is a device used to measure lung volume. A person using a spirometer
breathes in and out of the airtight chamber, thus causing it to move up and down, leaving a
trace on a graph which can then be interpreted.

Vital capacity – the maximum volume of air that can be inhaled or exhaled in a single
breath. Varies depending on gender, age, size as well as height

Tidal volume – the volume of air we breathe in and out at each breath at rest

Breathing rate – the number of breaths per minute, can be calculated from the spirometer
trace by counting the number of peaks or troughs in a minute

The volume of air which is always present in the lungs is known as the residual volume. The
tidal volume can be exceeded, in cases such as during exercise where the inspiratory reserve
volume is reached in an attempt to increase amount of air breathed in. Similarly, the
expiratory reserve volume is the additional volume of air that can be exhaled on top of the
tidal volume.

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 Ventilation and gas exchange in bony fish and
insects
Fish have a small surface area to volume ratio for gas exchange, apart from this they have
an impermeable membrane so gases can’t diffuse through their skin therefore fish need a
specialised exchange surface. Bony fish have four pairs of gills, each gill supported by an
arch. Along each arch there are multiple projections called gill filaments, with lamellae on
them which participate in gas exchange. Blood and water flow across the lamellae in a
counter current direction meaning they flow in opposite direction.

The projections are held apart by water flow. Therefore, in the absence of water they stick
together, thus meaning fish cannot survive very long out of water.

Ventilation is required to maintain a continuous unidirectional flow. Ventilation begins
with the fish opening its mouth followed by lowering the floor of buccal cavity, thus
enabling water to flow into it. Afterwards, fish closes its mouth, causing the buccal cavity
floor to raise, thus increasing the pressure. The water is forced over the gill filaments by the
difference in pressure between the mouth cavity and opercular cavity. The operculum
acts as a valve and pump and lets water out and pumps it in.

Insects do not possess a transport system therefore oxygen needs to be transported directly
to tissues undergoing respiration. This is achieved with the help of spiracles, small
openings of tubes, either bigger trachea or smaller tracheoles, which run into the body of an
insect and supply it with the required gases. At the end of each tracheole is a small amount of
tracheal fluid which allows gasses to dissolve and then diffuse into the cells.
Spiracles can be opened and closed to avoid excessive water loss

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