30301408
Description
Mind Map by Flo Sumpter, updated more than 1 year ago
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Created by Flo Sumpter
about 3 years ago
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B1 Cells - Active transport
- root hairs take in minerals and water
- the cells on the plant roots grow
into 'hairs' which stick into the soil
- each branch if a root will be
covered in millions of these
microscopic hairs
- this gives the plant a large
surface area for absorbing
water and mineral ions from
the soil.
- this gives the plant a large
surface area for absorbing
water and mineral ions from
the soil.
- plants need these mineral ions for healthy growth
- the concentration of minerals is usually
higher in the root hair cells than in the soil
around them.
- so the root hair cells can't use diffusion
to take up minerals from the soil.
- so the root hair cells can't use diffusion
to take up minerals from the soil.
- the cells on the plant roots grow
into 'hairs' which stick into the soil
- root hairs take in minerals using active transport
- minerals should move out of the root hairs if
they followed the rules of diffusion. the cells
must use another method to draw them in.
- this method is a conveniently mysterious process called active transport.
- this method is a conveniently mysterious process called active transport.
- active transport allows the plant to absorb minerals from
very dilute solution, against a concentration gradient
- this is essential for its growth
- this is essential for its growth
- active transport needs energy from respiration to work
- active transport also happens in humans, e.g
taking in glucose from the gut and from the
kidney tubules
- minerals should move out of the root hairs if
they followed the rules of diffusion. the cells
must use another method to draw them in.
- we need active transport to stop us starving
- active transport is used in the gut when there's a lower
concentration of nutrients in the gut but a higher concentration of
nutrients in the blood
- when there's a higher concentration of glucose and amino
acids in the gut they diffuse naturally into the blood
- but sometimes there's a lower concentration of
nutrients in the gut than there's in the blood
- this means that the concentration gradient is the wrong way
- this means that the concentration gradient is the wrong way
- but sometimes there's a lower concentration of
nutrients in the gut than there's in the blood
- active transport allows nutrients to be taken into the blood,
despite the fact that the concentration gradient is the wrong
way
- this means that glucose can be taken into the blood stream when its
concentration in the blood is already higher than in the gut, it can be
transported to cells, where it's used for respiration
- this means that glucose can be taken into the blood stream when its
concentration in the blood is already higher than in the gut, it can be
transported to cells, where it's used for respiration
- active transport is used in the gut when there's a lower
concentration of nutrients in the gut but a higher concentration of
nutrients in the blood
- organisms exchange substances with their environment
- cells can use diffusion to take in substances they need and get rid of
waste products.
- EXAMPLE: oxygen and carbon
dioxide are transferred between cells
and the environment during gas
exchange
- EXAMPLE: in humans. urea diffuses from cells into
the blood plasma for removal from the body by
the kidneys
- EXAMPLE: oxygen and carbon
dioxide are transferred between cells
and the environment during gas
exchange
- how easy it's for a organism to exchange substances with its
environment depends on the organisms surface area to volume ratio
(SA : V)
- cells can use diffusion to take in substances they need and get rid of
waste products.
- you can compare surface area to volume ratio
- a ratio shows how big one value is compared to another. The larger the
organism is, the smaller its surface area is compared to its volume. You
can show this by calculating surface area to volume ratio
- A hippo can be represented by a 2cm x 4cm x 4cm block
- the area of the surface is found by the equation LENGTH x WIDTH
- so the hippo's total surface area is
- top and bottom surfaces of the block = (4 x 4) x 2
- 4 sides of the block = (4 x 2) x 4
- total surface area = 64 cm2
- top and bottom surfaces of the block = (4 x 4) x 2
- the volume if a block is found by the equation LENGTH x WIDTH x HEIGHT
- the hippo's volume is 4 x 4 x 2 - 32 cm3
- the surface area to volume ratio of the hippo can be written as 64 : 32
to simplify the ratio, divide both sides of the ratio by the volume so the
surface area to volume ratio of the hippo is 2 : 1
- the hippo's volume is 4 x 4 x 2 - 32 cm3
- so the hippo's total surface area is
- the area of the surface is found by the equation LENGTH x WIDTH
- a ratio shows how big one value is compared to another. The larger the
organism is, the smaller its surface area is compared to its volume. You
can show this by calculating surface area to volume ratio
- multicellular organisms need exchange surfaces
- in single cell organisms, gases and dissolved substances can diffuse
directly into or out of the cell across the cell membrane
- it's because they have a large surface area compared to
their volume, so enough substances can be exchanged
across the membrane to supply the volume of the cell
- it's because they have a large surface area compared to
their volume, so enough substances can be exchanged
across the membrane to supply the volume of the cell
- multicellular organisms have a smaller surface area compared to
their volume - not enough substances can diffuse from their outside
surface to supply their entire volume
- this means they need some sort of exchange surface for efficient diffusion.
- the exchange surface structures have to allow enough of the
necessary substances to pass through
- this means they need some sort of exchange surface for efficient diffusion.
- exchange surfaces are adapted to maximise effectiveness
- they have a thin membrane, so substances
only have a short distance to diffuse
- they have a large surface area so lots of
substance can diffuse at once
- exchange surfaces in animals have lots
of blood vessels, to get stuff into and
out of the blood quickly
- gas exchange surfaces in animals are often
ventilated too - air moves in and out
- they have a thin membrane, so substances
only have a short distance to diffuse
- in single cell organisms, gases and dissolved substances can diffuse
directly into or out of the cell across the cell membrane
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