Class 10 Science: Life Processes PDF

Summary

This document is class 10 science notes on life processes, covering topics such as nutrition (autotrophic and heterotrophic), respiration, transportation, and excretion. It includes detailed explanations and diagrams.

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PRASHANT KIRAD

CLASS 10 NOTES

SCIENCE
Life Processes
PRASHANT KIRAD
 PRASHANT KIRAD

Life Processes

What are Life Processes?
Life processes encompass a set of interconnected activities within an organism that
collectively contribute to its repair and maintenance. These crucial processes include
Respiration (R), Excretion (E), Nutrition (N), and Transportation (T), forming the acronym
RENT.
Nutrition is the transformative process by which an organism acquires external sources of
energy, commonly known as food, and transfers it internally for sustenance and vitality.

Respiration: The process of acquiring oxygen from outside the body, and using it in
the process of break-down of food sources for cellular needs, is called respiration.
Transportation refers to the internal mechanism responsible for conveying nutrients and
oxygen from one location to another within the body.

Excretion is the process through which the body eliminates and expels waste by-products,
ensuring their removal from the internal environment and subsequent disposal outside the
organism.

Modes of Nutrition
1. Autotrophic Nutrition.
2. Heterotrophic Nutrition.
Autotrophs are organisms that derive their nutrition from basic food
materials acquired from inorganic sources such as carbon dioxide and
water. Notable examples include green plants and certain bacteria.
Heterotrophs, on the other hand, rely on complex substances for their
nutritional needs. These intricate compounds must undergo breakdown into
simpler forms before being utilized for the maintenance and growth of the
organism. To facilitate this process, organisms employ bio-catalysts known as
enzymes. Animals and fungi are examples of heterotrophs.
E.M.A
Autotrophic Nutrition:
1. Autotrophic organisms fulfill their carbon and energy requirements
through photosynthesis.
2. Photosynthesis is the process whereby autotrophs absorb external
substances and convert them into stored energy. This involves the
conversion of carbon dioxide and water into carbohydrates in the presence
of sunlight and chlorophyll.
3. Surplus carbohydrates produced through photosynthesis are stored in the
form of starch.
4. Similarly, in our bodies, a portion of the energy derived from the food we
eat is stored in the form of glycogen.
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Events Occurring during Photosynthesis:
1. Chlorophyll absorbing light energy.
2. Transformation of light energy into
chemical energy.
3. Separation of water molecules into
hydrogen and oxygen.
4. Conversion of carbon dioxide into
carbohydrates through reduction.

Chlorophyll is a crucial component for the process of photosynthesis.
The iodine test results in a blue-black coloration in the leaf regions where
photosynthesis occurs.

How the plant obtains carbon dioxide?
Massive gaseous exchange occurs in leaves via stomatal pores for
photosynthesis.
Gas exchange extends across the surfaces of stems, roots, and leaves.
Stomatal pores close to prevent excessive water loss when carbon dioxide is
not needed for photosynthesis.
The opening and closing of stomatal pores are regulated by guard cells.
Guard cells swell with water influx, causing stomatal pores to open.
Conversely, the pores close when guard cells shrink.

E.M.A
Stomata
Stomata, pores on leaves, facilitate gas exchange.
Predominantly located on the underside of leaves.
Guard cells, regulating pore opening and closing, safeguard each stoma.
The functionality of guard cells is influenced by their water content.
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Heterotrophic Nutrition: E.M.A
Saprophytic Nutrition
Saprophytic nutrition refers to the feeding behavior of certain
organisms that rely on consuming dead and decomposed organic matter.
The food is partially digested outside the body, and then it is absorbed.
E.g. Fungi are saprophytes.

Parasitic Nutrition
Parasitic nutrition involves organisms feeding at the expense of another,
causing harm.
Parasites live on or within a host organism, extracting nutrients directly
from the host's body.
Examples include leeches as ectoparasites, Ascaris as an endoparasite,
and Cuscuta as a parasitic plant.

Holozoic Nutrition:
In holozoic nutrition, the digestion happens inside the body of the organism.
i.e., after the food is ingested. Most of the animals follow this mode of
nutrition.

How do Organisms obtain their Nutrition?

Single-celled organisms
E.M.A Amoeba engulfs food through temporary
extensions of its cell surface, creating a food-
vacuole as these extensions merge over the food
particle.
Within the food-vacuole, complex substances
undergo breakdown into simpler ones, facilitating
their diffusion into the cytoplasm.
Undigested material is transported to the cell
surface and expelled by Amoeba.

Paramoecium, a unicellular organism, maintains a distinct shape and
ingests food at a designated location.
The entire cell surface, covered with cilia, facilitates the movement of
food to the specified intake spot.
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Nutrition in Human Beings:
The alimentary canal is a lengthy
tube running from the mouth to
the anus.
Salivary glands secrete saliva,
which contains the enzyme
salivary amylase, breaking down
complex starch into simple
sugars.
Muscles lining the canal contract
rhythmically, facilitating
peristaltic movements that push
food forward throughout the
digestive system.

Digestion in the stomach:
Gastric glands within the stomach wall secrete hydrochloric acid,
the enzyme pepsin, and mucus.
Hydrochloric acid establishes an acidic environment, enhancing the
effectiveness of the protein-digesting enzyme, pepsin.
Under normal conditions, mucus shields the stomach's inner lining
from the corrosive effects of the acid.
Pepsin functions as a protein-digesting enzyme.
The release of food from the stomach into the small intestine is
regulated by a sphincter muscle, allowing controlled passage in small
amounts.

Length of small intestine:
Herbivores, such as those consuming grass, require an elongated small
intestine to facilitate the digestion of cellulose.
Carnivores, like tigers, with a diet of easily digestible meat, possess shorter
small intestines.
The small intestine serves as the location for the thorough digestion of
carbohydrates, proteins, and fats.
Secretions from the liver and pancreas contribute to the digestive
processes occurring in the small intestine.
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Bile juice from the liver:
Bile salts play a role in emulsifying fats, breaking large fat globules into
smaller ones, thereby enhancing the efficiency of pancreatic enzymes.
The initially acidic food entering the small intestine undergoes alkalization
through the action of bile juice, promoting the effectiveness of pancreatic
enzymes.

pancreatic juice from the pancreas:
Pancreatic juice includes enzymes such as trypsin, responsible
for protein digestion, and lipase, which is involved in breaking
down emulsified fats.
The small intestine walls house glands producing intestinal
juice.
Enzymes in the intestinal juice convert proteins to amino acids,
complex carbohydrates to glucose, and fats to fatty acids and
glycerol.
The inner lining of the small intestine has numerous finger-like
projections called villi.

Functions of Villi:
Enhances the surface area available for absorption.
Villi are abundantly supplied with blood vessels, facilitating the
distribution of absorbed nutrients to every cell in the body.
Unabsorbed food is directed to the large intestine, where its
walls extract additional water from the material.

Respiration:
The process by which a living being utilises the food to get energy, is
called respiration. Respiration is an oxidation reaction in which
carbohydrate is oxidized to produce energy. Mitochondria is the site
of respiration and the energy released is stored in the form of ATP
(adenosine triphosphate). ATP is stored in mitochondria and is released
as per need.

Steps of respiration:
The breakdown of glucose into pyruvate occurs in the cytoplasm.
During this process, a glucose molecule, with 6 carbon atoms, is
transformed into pyruvic acid, which consists of 3 carbon atoms.
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Fate of Pyruvic Acid in Mitochondria: Pyruvic acid undergoes further
breakdown within the mitochondria, and the resulting molecules vary
based on the type of respiration specific to the organism. Respiration is
categorized into two types: aerobic respiration and anaerobic
respiration.
Respiration involves
Gaseous exchange: Intake of oxygen from the atmosphere and release
of CO2 → Breathing.
Breakdown of simple food in order to release energy inside the cell →
Cellular respiration
Types of Respiration
Aerobic Respiration: Aerobic respiration occurs in the presence of
oxygen. Pyruvic acid undergoes conversion into carbon dioxide, releasing
energy, and culminating in the formation of water molecules.
Anaerobic Respiration: Anaerobic respiration occurs in the absence of
oxygen. Pyruvic acid is converted into either ethyl alcohol or lactic acid.
Ethyl alcohol typically forms in microbes such as yeast or bacteria
during anaerobic respiration. Lactic acid is produced in certain microbes
and muscle cells during this process.

Pain in leg muscles while running:
Intense running triggers anaerobic respiration in muscle cells,
driven by an increased demand for energy.
The process of anaerobic respiration produces lactic acid,
contributing to a throbbing pain in the leg muscles.
Resting after the activity helps alleviate the pain caused by the
deposition of lactic acid in the muscles.
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ATP
ATP serves as the energy currency within cells.
ATP is an acronym for Adenosine Tri-Phosphate.
This molecule is generated as a byproduct of reactions such as
photosynthesis and respiration.
The three phosphate bonds in ATP are high-energy bonds, and their
breaking releases a substantial amount of energy.
The released energy is subsequently utilized for various metabolic
reactions.

Respiration in Humans
The human respiratory system is a complex network crucial for
breathing, gas exchange, and cellular respiration.
A well-organized respiratory system is essential for efficient
breathing and gas exchange.
Breathing involves inhaling oxygen and exhaling carbon dioxide.
Gas exchange occurs in the lungs, where oxygen is supplied to all
cells in the body.
Cellular respiration takes place in every cell, contributing to overall
energy production and cellular function.

Respiratory System
The human respiratory system involves the nose, nasal cavities,
pharynx, larynx, trachea/windpipe, bronchi, bronchioles and alveoli.
Bronchioles and alveoli are enclosed in a pair of lungs.
The rib cage, muscles associated with the rib cage and diaphragm all
help in the inhalation and exhalation of gases.
The exchange of gases takes place between an alveolar surface and
surrounding blood vessels.
Alveoli provide a large surface area for the exchange of gases.
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SECRET QUESTIONS

1. Why do we feel pain or cramps in muscles after vigorous exercise?

Actively metabolizing cells of an extremely active skeletal muscle,
during heavy exercise, carry oxidation in the anaerobic condition inside
the muscle cell, we feel pain after a vigorous exercise because of
production of ATP by anaerobic respiration in leg muscles

2. Describe the structure of the human heart briefly

Human heart is four chambered. The two upper chambers are called
atria and they receive blood from large veins while the two lower
chambers are called ventricles. Between left atrium and left ventricle as
well as between right atrium and right ventricle are valve which allow
blood to flow only from atrium to ventricle.

3. What is sequence of steps in photosynthesis? How is it
different in desert plants and those in temperate regions?

Chloroplast (chlorophyll), on exposure to light energy, becomes activated by
absorbing light energy, and splits water (photolysis of water) to oxygen and
hydrogen. Hydrogen reduces CO2
, and synthesizes glucose. In plants of temperate regions, stomata open during
day to take in CO2
and release O2 Desert plants open stomata at night to check excessive loss of
water hence sequence of steps of photosynthesis are slightly different. These
plants take up carbon dioxide at night and prepare an intermediate which is
acted upon by the energy absorbed by the chlorophyll during the day

4.Give schematic representation of different pathways of
breakdown of glucose molecule.
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Inhalation and Exhalation
Inhalation is the process of taking in air rich in oxygen.
Exhalation is the process of expelling air rich in carbon dioxide.
A single breath involves both inhalation and exhalation.
Individuals breathe multiple times throughout the day.
The frequency of breaths in one minute is referred to as the
breathing rate.

Cellular Respiration
Cellular respiration involves a series of metabolic reactions within cells,
transforming the biochemical energy derived from food into a chemical
compound known as adenosine triphosphate (ATP).

Respiration in Plants
In contrast to animals and humans, plants lack specialized
structures for gaseous exchange.
Gaseous exchange in plants occurs through stomata in leaves and
lenticels in stems.
Plant roots, stems, and leaves exhibit a considerably lower
respiratory rate compared to animals.

Transportation:
All living organisms, including animals, rely on essential
components like air, water, and food for survival, obtained
through processes such as breathing, drinking, and eating.
Transportation systems, like vascular tissue in plants and
specialized circulatory systems in animals, facilitate the
distribution of necessary substances to cells and tissues.
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Transportation in Humans
The circulatory system in humans serves as the primary
transportation mechanism.
Comprising blood, blood vessels, and the heart, it facilitates the
supply of oxygen and nutrients while eliminating carbon dioxide and
other excretory products.
Additionally, the circulatory system plays a vital role in the body's
immune response, aiding in the fight against infections.

HEART is a muscular organ, which is composed of cardiac muscles.
The heart, compact enough to fit within an adult's wrist, serves as a vital
pumping organ for blood circulation.
Comprising four chambers—right atrium, right ventricle, left ventricle,
and left atrium—the human heart orchestrates the rhythmic processes of
systole (contraction of cardiac muscles) and diastole (relaxation of
cardiac muscles).
Through systole and diastole, the heart efficiently propels and circulates
blood, ensuring essential oxygen and nutrients reach the body's tissues
and organs.

ARTERIES
Thick-walled blood vessels transport oxygenated blood from the
heart to various organs, with the exception of pulmonary arteries.
Pulmonary arteries deviate from the norm by carrying
deoxygenated blood from the heart to the lungs, where the blood
undergoes oxygenation.

VEINS
These are thin-walled blood vessels which carry deoxygenated blood
from different organs to the heart, pulmonary veins are exceptions
because they carry oxygenated blood from lungs to the heart.
Valves are present in veins to prevent back flow of blood.
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Capillaries: are blood vessels distinguished by their single-cell walls.
Blood, a connective tissue, functions as the carrier for various
substances in the body and is comprised of three main components:
1. Plasma, 2. Blood cells, and 3. Platelets.
Blood Plasma: This is a light-colored fluid primarily composed of
water, constituting the matrix of blood.
Blood Cells: There are two main types of blood cells: Red Blood Cells
(RBCs) and White Blood Cells (WBCs).
Red Blood Cells (RBCs): These cells are red due to the presence of the
pigment hemoglobin. Hemoglobin readily binds with oxygen and carbon
dioxide, facilitating the transport of oxygen. Additionally, a portion of
carbon dioxide is transported through hemoglobin.
White Blood Cells (WBCs): These cells are pale white and play a crucial
role in the immune system.
Platelets: Responsible for blood coagulation, platelets serve as a
defense mechanism preventing excessive blood loss in the event of an
injury.

LYMPH
Lymph resembles blood but lacks red blood cells (RBCs).
Formed from leaked fluid in tissues, lymph is collected by lymph
vessels and returns to blood capillaries.
Lymph, a yellowish fluid with fewer proteins than blood, plays a
vital role in the immune system.
It flows from tissues to the heart, assisting in transportation and
germ destruction.

Double circulation:
The heart receives oxygenated blood
from the lungs, pumps it to various
parts of the body, and then receives
it back for another circulation.
Consequently, the blood completes a
full round through the body, passing
once through the right half as
deoxygenated blood and once through
the left half as oxygenated blood.
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Transportation in Plants
Transportation is a crucial process in plants.
It encompasses the movement of water and essential nutrients
throughout the plant to support its survival.
Plants conduct the transportation of food and water through
distinct pathways.
Xylem is responsible for transporting water.
Phloem, on the other hand, is dedicated to the transportation
of food.
Transport of water
Root cells in contact with the soil actively absorb ions, establishing
a concentration difference between the root and the soil.
Water moves into the root from the soil to equalize this ion
concentration difference. Additionally, the evaporation of water
molecules from leaf cells generates suction, drawing water from the
xylem cells in the roots.
Transpiration
Transpiration refers to the loss of water in vapor form from the
plant's aerial parts.
This process aids in the absorption and upward transport of water
and dissolved minerals from the roots to the leaves, contributing to
temperature regulation.
Transport of food and other substances
The movement of soluble products resulting from photosynthesis is
termed translocation, and it takes place within the vascular tissue
section called the phloem.
Energy is harnessed to accomplish translocation in the phloem.
Substances such as sucrose are actively transferred into phloem
tissue, utilizing energy derived from ATP.

Xylem Phloem
Transports water and Transports the products of
minerals from the roots to photosynthesis from the leaves
various parts of the plant. to other parts of the plant.
No energy is used. Energy is used from ATP
(adenosine triphosphate).
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Excretion
The human excretory system comprises two kidneys, two ureters, a
urinary bladder, and a urethra.
Animals exhibit an advanced and specialized excretory system.
In contrast, plants lack a well-developed excretory system similar
to that of animals.
Plants do not possess specialized organs for excretion.
Consequently, excretion in plants is not as complex as it is in
animals.

Human Excretory System
The human excretory system consists of a pair of kidneys.
Each kidney is connected to the urinary bladder by a tube called
the ureter.
Urine is gathered in the urinary bladder and expelled through the
urethra as needed

Excretory system of human beings includes
A pair of kidneys, A urinary bladder, A pair of the ureter, A urethra.

Kidney:
The kidney, a bean-shaped organ, is situated near the vertebral
column in the abdominal cavity.
Comprising numerous filtering units known as nephrons.
The nephron is recognized as the functional unit of the kidney.
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Nephron Nephrons are the structural and functional unit of kidney.

Each kidney comprises millions of nephrons, serving as the
fundamental structural and functional unit.
A nephron consists of two parts: the Malpighian body and
the renal tubule.
The Malpighian body includes Bowman's capsule, a cup-like
structure, and the glomerulus, a cluster of capillaries.
Working collaboratively, they filter waste materials and
various useful substances.
The renal tubule features three regions: proximal
convoluted tubule, Loop of Henle, and distal convoluted
tubule.
These regions absorb useful substances back into the
blood and filter the remaining waste substances.
The collective output from nephrons is termed urine.
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Haemodialysis
Kidney failure leads to complications, and to address this, the
technology of dialysis has been developed.
Dialysis employs a machine filter known as a dialyzer or artificial
kidney.
The purpose is to eliminate excess water and salt, balance
electrolytes, and remove metabolic waste products.
Blood is extracted from the body and passes through tubes with
a semipermeable membrane.
On the other side of the membrane, a dialysate flows, drawing
impurities through the membrane.

Excretion in Plants
Cellular respiration, photosynthesis, and metabolic reactions in
plants result in the production of various excretory products.
Major plant excretory products include carbon dioxide, excess
water from respiration, and nitrogenous compounds from protein
metabolism.
Plants release two gaseous waste products: oxygen during
photosynthesis and carbon dioxide during respiration.
Gaseous waste excretion in plants occurs through stomatal pores on
leaves.
Oxygen released during photosynthesis is utilized for respiration,
while carbon dioxide from respiration is used for photosynthesis.
Excess water is excreted through transpiration.
Plants store organic by-products in different forms in various parts,
including gums, oils, latex, and resins.
These waste products are stored in plant parts like bark, stems,
leaves, etc., and are eventually shed off.
Examples of plant excretory products include orange oil, eucalyptus
oil, jasmine oil, latex from rubber trees, papaya trees, and gums
from acacia.
At times, plants release excretory substances into the soil.
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Top 7 questions

1.Differentiate between Photosynthesis and Respiration.

Respiration Photosynthesis

It occurs in all living cells. It occurs in only
autotrophs.
O2 reacts with food and CO2 and H2O combine to
energy is released. form starch and water in
the presence of light.
It occurs in cytoplasm and
Occur in plastidchloroplast
mitochondria.

2. a. How is oxygen and carbon dioxide exchanged between blood
and tissue? How are the gases transported in human being?
b. What is haemoglobin?

a. Exchange of gases in tissues occurs through
diffusion. Oxygen is carried as oxyhaemoglobin from lungs to tissues. It
dissociates and carbon dioxide diffuses out into blood from tissues. It is
transported in dissolved form and reaches lungs where again it diffuses to
alveoli.
b. Respiratory pigment: Haemoglobin is a red coloured protein present in
red blood cells. Haemoglobin has affinity for O2.

3. What is excretion? Name some parts in our body involved in this
life process?

Excretion means throwing out metabolic waste from living body. Many
organs perform this process such as
a. Kidneys remove nitrogenous wastes like urea and uric acid in urine.
b. Sweat and oil by glands in skin.
c. Carbon dioxide and water vapor by lungs.
d. Faces or undigested food by large intestine.
e. Bile pigments by liver. It also converts toxic ammonia to urea.
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4.Explain how the air is inhaled during breathing in humans.

Mechanism of inhalation:
a. The diaphragm and rib muscles contract which make the throat
move upwards and outwards.
b. The volume inside the thoracic cavity increases i.e., it expands.
c. Air pressure inside the thoracic cavity decreases. Thus, air from
outside rushes into the lungs /
alveoli through nostrils, trachea and bronchi.

5.Leaves of a healthy potted plant were coated with Vaseline to
block the stomata. Will this plant remain healthy for long? Stage
three reasons for your answer.

No, the plant will not stay healthy for a long time. The reasons are:
a. It will not be able to exchange O2 and CO2, hence respiration will be
affected adversely.
b. Photosynthesis will also be affected as CO2 will not be available.
c. Transpiration will not take place hence there will
be no ascent of sap, hence no water absorption from the soil.

6.Draw neat and labeled diagram of nephron and describe
the process of urine formation.

Within the kidney are small functional units
called nephrons, which are made up of glomeruli,
Bowman’s capsule, proximal convoluted tubule,
loop of Henley1s loop, distal convoluted loop, and
collecting duct. Steps of urine formation: Each
kidney is made of millions of nephron. Each
nephron has a hollow cup like Bowman’s capsule
and a long tubule system following it. Arteriole
branching from renal artery make bunches of
capillaries, one of which is called a Glomerulus.
The first step in the filtration process is when
the blood enters the Glomerulus, where it is
then pumped through the porous walls into the
Bowman’s space. This filtered plasma is mainly
water, various salts, urea and glucose. The
“glomerular filtrate” then
passes through the proximal convoluted tubule ,
Loop of Henle, the distal convoluted tubule so
that useful substances are re-absorbed by blood
present in the capillaries around them.
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7.Describe double circulation in human beings. Name the group of
animal with double circulation? How is it important for them?

Such a flow in which blood enters the heart
twice is called double circulation. It helps in
keeping the oxygenated and deoxygenated
blood separate. The right atrium receives
blood from the vena cava and pumps the
blood into the right ventricle. Blood is sent
to lungs, where it is oxygenated. Then, it is
sent through the right and left pulmonary
veins to the left atrium where it is pumped
to the left ventricle. The blood then travels
to the ascending aorta where it leaves the
heart and delivers oxygen to different parts
of the body.

Competency-Based Questions:
1. The green plants make their food, through photosynthesis and are therefore
called autotrophs. All other organisms depend upon green plants for food and are
referred to as heterotrophs. Green plants carry out photosynthesis by using
light energy of sun. The first phase of reactions are directly light driven
therefore called light reactions. The second phase of reactions are not directly
light driven but are dependent on the products of light reactions and are called
dark reactions.
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2.The small intestine is a tubular structure within the abdominal cavity that
carries the food in continuation with the stomach up to the colon from where the
large intestine carries it to the rectum and out of the body. The main function of
this organ is to aid in digestion. All nutrients are usually absorbed into blood across
the mucosa of the small intestine. In addition, the small intestine absorbs water
and electrolytes, thus playing critical role in and acid-base balance.
maintenance of body water