2. All living cells are made up of chemical substances
The processes of living involve reactions between the
substances
For example
C + O2 CO2
carbon oxygen carbon dioxide
is an event which
produces a change
in a substance
3. The reaction between carbon and
oxygen also releases energy in the
form of heat and light (flames)
Living organisms get their energy from
reactions like this (but not reactions
which are violent enough to produce
flames)
5. One of the energy-producing reactions is called
respiration
(Respiration is not breathing)
takes place
in allall living cells
The reaction takes place between oxygen and a
substance which contains carbon. The reaction
produces carbon dioxide and water, and releases
energyenergy
6. The carbon-containing substances come from
FOOD (GLUCOSE)
The oxygen comes from the AIR (or water)
The energy is used to drive other chemical
reactions taking place in cells
C6H12O6 + 6O2 6CO2 + 6H2O + energy
sugar
(glucose)
oxygen carbon
dioxide
water
8. The blood stream brings food
and oxygen to the muscle
cells. Respiration occurs in
the cells and releases energy
which……
shoulder blade
upper arm
bone
lower arm bones
Energy use in muscle contraction
10. (a)
(b)
(a) is a section cut through the
length of a maize seedling. Areas
of rapid respiration are stained pink.
(b) and (c) are drawings of the seed
and the seedling that grows from it.
Can you suggest reasons why
respiration should be so rapid in the
stained regions?
embryo
shoot
embryo
root
food store
root
(c)
shoot
root
11. Answer
The most intensely stained areas are in the root tip and the
shoot tip. These are regions where very rapid cell division is
taking place to produce growth. Making new cells and new
cytoplasm takes a great deal of energy.
You might also have noticed that, in the root, there are two
faint streaks of pink. These occur in the conducting tissue of
the seedling. Energy is needed to transport food from the
food store to the growing region.
12. Glucose and
oxygen react to
produce energy for
muscle contraction
4 RESPIRATION
5 Carbon dioxide
is carried to the lungs
by the blood
One example of respiration in ourselvesOne example of respiration in ourselves
1. Air taken in
1.Food taken in
2. The lungs absorb oxygen
from the air
2.The stomach and
intestine digest food.
One of the products
is glucose
3.The blood stream
carries glucose and
oxygen to the muscles
13. RespirationRespiration
The glucose is notnot completely broken down to CO2 and H2O
but to CO2 and alcohol (ethanol).
release of energy when foodstuffs such
as glucose react with oxygenwith oxygen to produce
carbon dioxide and water.
aerobic respiration.
which does not need oxygendoes not need oxygen
and is called anaerobic
respiration
14. C6H12O6 2C2H5OH + 2CO2
glucose alcohol
energy
For example, our own muscles resort to anaerobic
respiration when oxygen is not delivered to them fast
enough.
* LESS energy released
* Anaerobic respiration takes place at some stage in the cells
of most living organisms.
anaerobic respiration
15. sugar is broken down to alcohol and carbon dioxide
* pizza-making* pizza-making
* brewing* brewing
* wine-making* wine-making
fermentation.
One form of anaerobic respiration in bacteria and yeasts
is called
16. AEROBIC
RESPIRATION
SIMILARITIES ANAEROBIC
RESPIRATION
*USES O2 *E released by breakdown
of SUGAR
*Don’t use O2
* always produces
Carbon dioxide
+water
*ATP made *CO2 sometimes
made
*Large amount of EE
released
*Some energy lost as HEATHEAT *Small amount of ee
released
*ALCOHOL or
LACTID ACID made
18. Dough rising
The yeast is mixed
with the dough
After 1 hour in a warm
place the dough has
risen as a result of the
carbon dioxide
produced by the yeast
19. The ‘holes’ in the
bread are made by
the carbon dioxide
bubbles.
This gives the
bread a ‘light’
texture
20. Proteins Carbohydrates Lipids
DIGESTION
AAAA GlucoseGlucose FattyFatty
acids +acids +
glycerolglycerol
BLOOD
GlucoseGlucose
PYRUVIC ACIDPYRUVIC ACID
22
CC
YY
TT
OO
PP
LL
AA
SS
MM
No O2No O2
enzymes
C6H12O6 2C2H5OH+2 CO2+ 118kj/2 ATP
Glucose alcohol carbon E
dioxide
KREBS CYCLEKREBS CYCLE
MITOCHONDRIONMITOCHONDRION AEROBIC RESPIRATIONAEROBIC RESPIRATION
enzymes
C6H12O6 + 6 O 6CO2+6H2O+ 2830kj / 38 ATP (40% is used)
Glucose oxygen carbon water E
Substrates dioxide
GlucoseGlucose
GlucoseGlucose
PYRUVIC ACIDPYRUVIC ACIDLACTICLACTIC
ACIDACID
2 ATP
LACTICLACTIC
ACIDACIDPYRUVIC ACIDPYRUVIC ACID
BLOOD
MUSCLE
LIVER
CORI CYCLECORI CYCLE
Only in EXTREME MUSCULAR
ACTIVITY
6 ATP
FERMENTATIONFERMENTATION
GLUCOGLUCO
NEONEO
GENESISGENESIS
OXYGEN DEBTOXYGEN DEBT
Notes de l'éditeur
It is important to understand that the biological meaning of ‘Respiration’ refers to a chemical process taking place in all living cells. The function of this chemical process is to make energy available for all the cell’s activities which keep it alive. ‘ Breathing’, in some cases, plays a part but ‘respiration’ to a biologist does not mean the same as ‘breathing’.
Some of the energy released in living organisms always appears in the form of heat
Coal and wood are the carbon sources. The carbon dioxide goes up the chimney.
The word ‘respiration’ is used in everyday language to mean breathing; as in,for example, ‘respiration rate’ (breathing rate) or ‘artificial respiration’. In biology, it is best to avoid confusion by using the term ‘respiration’ for the chemical reaction in cells. ‘Artificial respiration’, is better described as ‘resuscitation’.
Organisms living in water absorb oxygen from it. But it is not the O of H 2 O that they use. The oxygen which they can use is dissolved in the water and comes, originally, from the air.
These are only a few examples. Every living process in living organisms needs energy from respiration
The drawing represents the human arm bones with two of the muscles which produce movement (biceps and triceps)
The water produced as a waste product of respiration is picked up by the blood stream and may be lost in sweat, water vapour from the lungs or in urine
The carbon dioxide bubbles plus some of the beer constituents produce a dense froth on top of the beer. The fermentation vessel is an old-fashioned open type.