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Biology
LIFE PROCESSES
 Introduction
Life processes – The processes that are necessary for an organism to stay alive.
Eg. Nutrition, respiration, etc.

Criteria of life-
Metabolism
Response to stimulus
Growth
Reproduction
 Nutrition
The process in which an organism takes in food, utilizes it
to get energy, for growth, repair and maintenance, etc.
and excretes the waste materials from the body
Types of nutrition
1. Autotrophic nutrition – Autotrophic (self-sufficient for food) E.g.
Plants, Algae, blue green Algae( cyanobacteria).
2.Heterotrophic nutrition -Heterotrophic (dependent on others for
food).
Eg. Animals,fungi.
Autotrophic nutrition.
Process – Photosynthesis (Photo=light; Synthesis= to combine)
Raw materials- (i) Carbon dioxide (ii)Water
Energy conversion- Light/Solar energy to Chemical energy
Role off Chlorophyll- To trap the sun‘s energy for photosynthesis
Chemical equation for photosynthesis
 Events/ Steps of photosynthesis-
(i) Absorption of light energy by chlorophyll
(ii) Conversion of light energy to chemical energy & Splitting of water molecule
into Hydrogen & oxygen
(iii) Reduction of Carbon dioxide to Carbohydrate
Gaseous exchange-
(i) Gas used- Carbon dioxide
(ii) By product – Oxygen
Source of raw materials-
(i) Carbon dioxide –Land plants- Air, Aquatic plants- Water
(ii) Water & Minerals - Soil
Photosynthesis
Photosynthesis is a Photochemical Reaction and Anabolic Process
Photosynthesis is divided into two parts:
1. Light-dependent reactions (Light Reactions)
2. Light-independent reactions (Dark Reactions).
Light Reactions
Light reactions need light to produce organic energy molecules (ATP and
NADPH).
They are initiated by colored pigments, mainly green colored
chlorophylls.
It occurs in Grana.
(NADPH stands for Nicotinamide Adenine Dinucleotide Phosphate
Hydrogen. This molecule plays a crucial role in some of the chemical
reactions that make up the process of photosynthesis.)
 Dark Reactions
Dark reactions make use of these organic energy
molecules (ATP and NADPH). This reaction cycle is also
called Calvin Cycle.
ATP provides the energy while NADPH provides the
electrons required to fix the CO2 (carbon dioxide) into
carbohydrates.
Occurs in Stroma.
Structure of Chloroplast
Gaseous Exchange
 Factors for Autotrophic nutrition -
(i) Carbon dioxide
(ii) Water
(iii) Light
(iv) Temperature
 Heterotrophic nutrition
Generally take up energy from plants and animals by using them as food.
Mostly of three Types—Saprophytic, Holozoic and Parasitic
 (a) Saprophytic nutrition: Organisms feeds on dead decaying plants or
animals material.
E.g. Fungi, Bacteria
(b) Parasitic nutrition: Organisms obtain food from the body of another
living (host)
Endoparasite : Parasite lives inside the body of the host e.g. tapeworm,
roundworm.
Exoparasite : Parasite lives on the body of the host. E.g. lice, leech.
The parasite benefits while the host is usually harmed
e.g. Cuscutta-plant parasite, plasmodium –animal parasite (malarial
parasite).
(c) Holozoic nutrition: Organism (mostly animals) take in whole food and
then digest it into smaller particles with enzyme.
Eg.Amoeba, Paramoecium. Animals, human beings.
Steps in Holozoic nutrition
(i) Ingestion: taking in of food.
(ii) Digestion: breaking down of complex food into simpler, absorbable
form.
(iii) Absorption: the process by which the digestive contents are
absorbed by the blood and distributed to the rest of the body.
(iv) Assimilation: Utilization of digested food from the body.
(v) Egestion: Removing undigested food from the body.
Nutrition In Amoeba
Nutrition in Human Beings
Alimentary Canal- Parts
Mouth, Esophagus, Stomach, Small Intestine Large Intestine, Rectum,
Anus
Associated Glands – Salivary Glands, Liver, Gallbladder And Pancreas
Digestive Enzymes And Their Functions
Small Intestine
The small intestine has three parts: the duodenum, jejunum, and
ileum.
Large Intestine
Different sections of the
large intestine are –
Cecum
Colon
Rectum
Anal canal
Anus
The large intestine comprises
the cecum (appendix
included), the colon, the
rectum and the anal canal.
Respiration-the process in which nutrients are converted into useful
energy in a cells.
Respiration
Adenosine TriPhosphate (ATP)
ATP is the energy currency for most cellular processes. The energy
released during the process of respiration is used to make an ATP
molecule from ADP and inorganic phosphate.
ADP +Pi-----> ATP
Gaseous exchange in plants-
Process – Diffusion
Direction of diffusion depends on-
(i) Environmental conditions
(ii) Requirement of the plant.

Day time- Carbon dioxide given out during respiration is used for
photosynthesis.
Therefore only Oxygen is released, which is a major activity during the day.
Night time – Only respiration takes place.
Therefore only Carbon dioxide is released, which is a major activity during
the night.
 Gaseous exchange in animals-
Terrestrial animals- take Oxygen from the atmosphere.
Aquatic animals- take Oxygen dissolved in water.
(Oxygen content is low in water, therefore they breath
faster.
Human Respiratory System
 Human Respiratory Pathway
External nostrils → Nasal cavity → Trachea→ Bronchi →
Bronchioles →Alveoli
Rings of cartilage present in the throat ensure that the
trachea (air passage) does not collapse when there is
less air in it.
Lungs –
(i) Present in the thoracic cavity.
(ii) They are spongy, elastic bags consisting of Bronchi,
Bronchioles and Alveoli
Mechanism of breathing
It includes :
(i)Inhalation
(ii) Exhalation
Gaseous Exchange In Alveoli
 Some common features of Respiratory organs-
(i) Large surface area- for greater rate of diffusion of
respiratory gases.
(ii) Thin permeable walls – to ensure easy diffusion &
exchange of gases.
(iii) Extensive blood supply- Respiratory organs are
richly supplied with blood vessels for quick transport of
gases.
Transport In Human Beings-
The transport of materials in humans is done by Circulatory System.
Parts of circulatory system
Heart, Blood, blood vessels
Blood-
(i) It is a fluid connective tissue.
(ii) Components-
(1) Fluid medium- Plasma
(2) Red blood corpuscles (RBC) or erythrocytes
(3) White blood corpuscles (WBC) or leukocytes
(4) Platelets or thrombocytes
Composition Of Blood
Plasma:
Plasma is slightly alkaline non-living intercellular substance. It is pale yellow but transparent and clear
fluid. It constitutes about 55% of blood.
Constituents of plasma and their functions:
Water (90-92%): It is a good solvent. It transports vitamins, hormones, enzymes, nutrients etc.
Plasma proteins (6-8 %): It includes:
Fibrinogen: It is a plasma glycoprotein synthesised by the liver. It plays a role in the clotting of blood.
Globulin: It is the major protein of the plasma. It protects the body against foreign bodies. It acts as
antibodies.
Albumin: It is the major protein of the plasma. It helps in maintaining the fluid volume within the
vascular space. It also regulates the blood pressure.
Glucose, amino acids, lipids and cholesterol: It is meant for energy production and growth.
Inorganic constituents: Na+, K+, Mg2+, Cl–, HCO32– regulates osmosis etc. Ca2+ ions help in blood clotting
and muscle contraction. Gases like CO2, O2, N2 etc. for transport.
Plasma without clotting factors is known as Serum. Serum = Plasma − Clotting factor
 Composition Of Blood
Formed elements (RBC, WBC and platelets)
It constitutes about 45% of blood.
(i) Erythrocytes or Red Blood Cells (RBC): Red blood
cells are the most abundant cells in the blood.
Average lifespan: 120 days
Count: 5 − 5.5 million/ mm3 of blood.
Formed in: Bone marrow.
Other features: Biconcave and devoid of nucleus.
These cells contain a red colour pigment called
haemoglobin.
Normal Hb level: 12-16 gm/ 100 ml of blood
Worn-out RBCs are destroyed in spleen, hence spleen
is called the graveyard of RBCs.
Function: Involved in transport of respiratory gases.
 Composition Of Blood
(ii) Leucocytes or White Blood Cells (WBC):
White blood cells are colourless cells without haemoglobin. They are the
largest cell of the blood.
Count: 6000 − 8000/ mm3 of blood
Average lifespan: Generally short lived (1- 15 days).
Formed in: Bone marrow, lymph glands, spleen.
Other features: Colourless.,Nucleated,Different types
Function: They have a major role to play in defence system of body.
Types Of WBC
(iii)Platelets (Thrombocytes):
Platelets are small irregular bodies present in the blood.
Count: 1.5 − 3.5 × 105/ mm3 of blood
Average lifespan: 7 days.
Formed in: bone marrow.
Function: Blood clotting.
Types of Leucocytes (WBCs):
Granulocytes and Agranulocytes
Functions Of Blood-
(i) Transport of respiratory gases.
(ii) Transport of nutrients.
(iii) Transport of waste products.
(iv) Defence against infection
Structure Of Human Heart
Blood Flow Through the Heart
Blood vessels-
Types Of Blood Vessels
(i) Arteries
(ii) Veins
(iii) Capillaries
Difference Between Artery, Vein And Capillary
The Human Circulatory System
The human circulatory system is a double circulatory system.
It has two separate circulations and blood passes through the
heart twice: the pulmonary circulation is between the heart and
lungs. the systemic circulation is between the heart and the other
organs.
Types Of Circulatory System
Pulmonary circulation
Systemic circulation
 Pulmonary Circulation
The circulatory system which transports deoxygenated blood away from
the heart, through the pulmonary artery, to the lungs and returned,
oxygenated, to the heart through the pulmonary vein.
 Systemic Circulation
The circulatory system which transports oxygenated blood away from the
heart through the aorta from the left ventricle to the rest of the body,
and returns oxygen-depleted blood back to the heart through vena cava.
Circulatory System
Blood Pressure (BP)
Blood pressure is the pressure of circulating blood on
the walls of blood vessels. Most of this pressure is due
to work done by the heart by pumping blood through
the circulatory system.
The systolic pressure is the pressure in the arteries as
the heart contracts pushing the blood forward.
The diastolic pressure is the pressure in the arteries as
the heart relaxes.
Blood Pressure (BP)
Normal blood pressure is 120/80 mm of Hg.
Increased blood pressure- Hypertension
Decreased blood pressure- Hypotension
A Sphygmomanometer is a device used to
measure blood pressure.
Transportation In Plants
Plants need less energy - because they do not move and therefore
have a slow
transport system.
Transport is done in plants by xylem and phloem.
Difference Between Xylem And Phloem
 Excretion

The biological process of removal of harmful metabolic wastes in living
organisms.
Excretion In Human Beings

Organs of excretory system-

(i)A pair of Kidneys (iii) Urinary bladder
(ii)A pair of Ureters (iv) Urethra
Human Excretory System
 Kidneys-
(i) Two in number
(ii) Bean shaped
(iii)Present in abdomen on either side of the backbone
(iv)Basic unit is nephron.
KIDNEY AND NEPHRON
Structure Of Nephron
Structure Of Nephron
a) Glomerulus- Group of capillaries (cluster) present in Bowman‘s
capsule to receive blood from renal artery and filters it.
b) Bowman‘s capsule- Cup shaped structure, which contains
glomerulus.
c) Convoluted tubule- is long and reabsorbs vital nutrients like glucose,
amino acids, salts, urea and water.
Structure Of Nephron
Function Of The Glomerulus
The main function of the glomerulus is to filter blood to produce
glomerular filtrate, which passes down the length of the nephron tubule
to form urine.
Mechanism of Urine Formation
Urine is formed in three main
steps-
glomerular filtration,
reabsorption, and secretion.
It comprises 95 % water and
5% wastes such as ions of
sodium, potassium, and
calcium, and nitrogenous
wastes such as creatinine,
urea, and ammonia.
Mechanism Of Urine Formation
 Anti Diuretic Hormone (ADH)
ADH is also called Vasopressin.
It's a hormone made by the hypothalamus in the
brain and stored in the pituitary gland.
It tells your kidneys how much water to conserve.
ADH constantly regulates and balances the amount of
water in your blood.
Regulation Of Urine Formation
 Dialysis
Dialysis is the process of removing excess water, solutes and toxins from
the blood in people whose kidneys can no longer perform these
functions naturally.
Excretion in Plants
Plants have no special organs for the removal of waste.
The excretory products in plants are eliminated from the plant body by different
mechanisms.
The waste products of respiration and photosynthesis are used as raw materials for each
other.
Oxygen gas produced as a by-product of photosynthesis is used up during respiration and
carbon dioxide produced during respiration is used up during photosynthesis.
Excretion is carried out in the plants in the following ways:
The gaseous wastes, oxygen, carbon dioxide, and water vapor are removed through the
stomata of leaves and lenticels of stems.
Some waste products collect in the leaves and bark of trees. When the leaves and bark
are shed, the wastes are eliminated.
Some waste products are rendered harmless and then stored in the plant body as solid
bodies. tannins, resins, gum, rubber, and essential oils are some such wastes
The oil produced from orange, eucalyptus, and jasmine, latex from the rubber tree,
papaya tree, and gums from acacia, are different forms of stored waste products.
Sometimes waste products are excreted into the soil.
Excretion in plants
Oxygen, a waste product of photosynthesis is released.
Excess water is removed by transpiration.
Some waste products may get stored in the leaves which fall off.
Many waste products are stored in vacuoles.
Some waste products are stored as resins and gums in old
xylem.
Plants excrete some waste materials into the soil around them.
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