NCERT Class 10 Science Chapter 6 Question Answer
Q 1:Why is diffusion insufficient to meet the oxygen requirements of multi-cellular organisms like humans?
Ans- Multicellular organisms such as humans possess complex body designs. They have specialised cells and tissues for performing various necessary functions of the body such as intake of food and
oxygen. Unlike unicellular organisms, multicellular cells are not in direct contact with the outside
environment. Therefore, diffusion cannot meet their oxygen requirements.
Q 2:What criteria do we use to decide whether something is alive?
Ans- Any visible movement such as walking, breathing, or growing is generally used to decide whether something is alive or not. However, a living organism can also have movements, which are not visible to the naked eye. Therefore, the presence of life processes is a fundamental criterion that can be used to decide whether something is alive or not.
Q 3:What are outside raw materials used for by an organism?
Ans- An organism uses outside raw materials mostly in the form of food and oxygen. The raw materials required by an organism can be quite varied depending on the complexity of the organism and its environment.
Q 4:What processes would you consider essential for maintaining life?
Ans- Life processes such as nutrition, respiration, transportation, excretion, etc. are essential for
maintaining life.
Long--
Q 1 -What are the differences between autotrophic nutrition and heterotrophic nutrition?
Answer-. Rotation on for better experience
Q 2:Where do plants get each of the raw materials required for photosynthesis?
Ans-The following raw materials are required for photosynthesis:
• The raw material CO2 enters from the atmosphere through stomata.
• Water is absorbed from the soil by the plant roots.
• Sunlight, an important component to manufacture food, is absorbed by the chlorophyll and other green parts of the plants.
Q 3:What is the role of the acid in our stomach?
Ans- The hydrochloric acid present in our stomach dissolves bits of food and creates an acidic medium. In this acidic medium, enzyme pepsinogen is converted to pepsin, which is a protein-digesting enzyme.
Q 4:What is the function of digestive enzymes?
Ans- Digestive enzymes such as amylase, lipase, pepsin, trypsin, etc. help in the breaking down of complex food particles into simple ones. These simple particles can be easily absorbed by the blood and thus transported to all the cells of the body.
Q 5: How is the small intestine designed to absorb digested food?
Ans- The small intestine has millions of tiny finger-like projections called villi. These villi increase the surface area for more efficient food absorption. Within these villi, many blood vessels are present that absorb the digested food and carry it to the bloodstream. From the bloodstream, the absorbed food is delivered to each and every cell of the body.
Q 6:What advantage over an aquatic organism does a terrestrial organism have with regard to
obtaining oxygen for respiration?
Ans-Terrestrial organisms take up oxygen from the atmosphere whereas aquatic animals need to utilize oxygen present in the water. Air contains more O2 as compared to water. Since the content of O2 in air is high, the terrestrial animals do not have to breathe faster to get more oxygen. Therefore, unlike aquatic animals, terrestrial animals do not have to show various adaptations for better gaseous exchange.
Q 7: What are the different ways in which glucose is oxidized to provide energy in various organisms?
Ans- Glucose is first broken down in the cell cytoplasm into a three carbon molecule called pyruvate.Pyruvate is further broken down by different ways to provide energy. The breakdown of glucose by different pathways can be illustrated as In yeast and human muscle cells, the breakdown of pyruvate occurs in the absence of oxygen whereas in mitochondria, the breakdown of pyruvate occurs in the presence of oxygen.
Q 8:How is oxygen and carbon dioxide transported in human beings?
Ans- Haemoglobin transports oxygen molecules to all the body cells for cellular respiration. The
haemoglobin pigment present in the blood gets attached to four O2 molecules that are obtained
from breathing. It thus forms oxyhaemoglobin and the blood becomes oxygenated. This
oxygenated blood is then distributed to all the body cells by the heart. After giving away O2 to the body cells, blood takes away CO2 which is the end product of cellular respiration. Now the blood becomes de-oxygenated. Since haemoglobin pigment has less affinity for CO2, CO2 is mainly transported in the dissolved form. This de-oxygenated blood gives CO2 to lung alveoli and takes O2 in return.
Q 9:How are the lungs designed in human beings to maximize the area for exchange of gases?
Ans- The exchange of gases takes place between the blood of the capillaries that surround the alveoli and the gases present in the alveoli. Thus, alveoli are the site for exchange of gases. The lungs get filled up with air during the process of inhalation as ribs are lifted up and diaphragm is flattened. The air that is rushed inside the lungs fills the numerous alveoli present in the lungs. Each lung contains 300-350 million alveoli. These numerous alveoli increase the surface area for gaseous exchange making the process of respiration more efficient.
Q 10:What are the components of the transport system in human beings? What are the functions of these components?
Ans- The main components of the transport system in human beings are the heart, blood, and blood vessels.
• Heart pumps oxygenated blood throughout the body. It receives deoxygenated blood from
the various body parts and sends this impure blood to the lungs for oxygenation.
• Being a fluid connective tissue, blood helps in the transport of oxygen, nutrients, CO2, and
nitrogenous wastes.
• The blood vessels (arteries, veins, and capillaries) carry blood either away from the heart
to various organs or from various organs back to the heart.
Q 11:Why is it necessary to separate oxygenated and deoxygenated blood in mammals and birds?
Ans- Warm-blooded animals such as birds and mammals maintain a constant body temperature by cooling themselves when they are in a hotter environment and by warming their bodies when they are in a cooler environment. Hence, these animals require more oxygen (O2) for more cellular respiration so that they can produce more energy to maintain their body temperature.
Thus, it is necessary for them to separate oxygenated and de-oxygenated blood, so that their
the circulatory system is more efficient and can maintain their constant body temperature.
Q 12:What are the components of the transport system in highly organised plants?
Ans- In highly organised plants, there are two different types of conducting tissues − xylem and
phloem. Xylem conducts water and minerals obtained from the soil (via roots) to the rest of the
plant. Phloem transports food materials from the leaves to different parts of the plant body.
Q 13:How are water and minerals transported in plants?
Ans- The components of xylem tissue (tracheids and vessels) of roots, stems, and leaves are
interconnected to form a continuous system of water-conducting channels that reaches all parts of the plant. Transpiration creates a suction pressure, as a result of which water is forced into the xylem cells of the roots. Then there is a steady movement of water from the root xylem to all the plant parts through the interconnected water-conducting channels.
Q 14:How is food transported in plants?
Ans- Phloem transports food materials from the leaves to different parts of the plant body. The
transportation of food in phloem is achieved by utilizing energy from ATP. As a result of this, the
osmotic pressure in the tissue increases causing water to move into it. This pressure moves the
material in the phloem to the tissues which have less pressure. This is helpful in moving materials according to the needs of the plant. For example, the food material, such as sucrose, is transported into the phloem tissue using ATP energy.
Q 15:Describe the structure and functioning of nephrons?
Ans- Nephrons are the basic filtering units of kidneys. Each kidney possesses a large number of nephrons, approximately 1-1.5 million. The main components of the nephron are glomerulus, Bowman’s capsule, and a long renal tubule.
The blood enters the kidney through the renal artery, which branches into many capillaries
associated with glomerulus.
The water and solute are transferred to the nephron at Bowman’s capsule.
In the proximal tubule, some substances such as amino acids, glucose, and salts are
selectively reabsorbed and unwanted molecules are added in the urine.
The filtrate then moves down into the loop of Henle, where more water is absorbed.
From here, the filtrate moves upwards into the distal tubule and finally to the collecting
duct. Collecting duct collects urine from many nephrons.
The urine formed in each kidney enters a long tube called ureter. From ureter, it gets
transported to the urinary bladder and then into the urethra.
Q 16:What are the methods used by plants to get rid of excretory products?
Ans- Plants can get rid of excess of water by transpiration. Waste materials may be stored in the cell vacuoles or as gum and resin, especially in old xylem. It is also stored in the leaves that later fall off.
Q 17:How is the amount of urine produced regulated?
Ans- The amount of urine produced depends on the amount of excess water and dissolved wastes present in the body. Some other factors such as habitat of an organism and hormone such as Anti- diuretic hormone (ADH) also regulates the amount of urine produced
.
Objective type questions--
Question 1:
The kidneys in human beings are a part of the system for
(a) nutrition.
(b) respiration.
(c) excretion.
(d) transportation.
Answer
(c) In human beings, the kidneys are a part of the system for excretion.
Question 2:
The xylem in plants are responsible for
(a) transport of water.
(b) transport of food.
(c) transport of amino acids.
(d) transport of oxygen.
Answer
(a) In a plant, the xylem is responsible for transport of water.
Question 3:
The autotrophic mode of nutrition requires
(a) carbon dioxide and water.
(b) chlorophyll.
(c) sunlight.
(d) all of the above.
Answer
(d) The autotrophic mode of nutrition requires carbon dioxide, water, chlorophyll and sunlight.
Question 4:
The breakdown of pyruvate to give carbon dioxide, water and energy takes place in
(a) cytoplasm.
(b) mitochondria.
(c) chloroplast.
(d) nucleus.
Answer
(b) The breakdown of pyruvate to give carbon dioxide, water and energy takes place in
Mitochondria.
Question 5:
How are fats digested in our bodies? Where does this process take place?
Answer-
Fats are present in the form of large globules in the small intestine. The small intestine gets the secretions in the form of bile juice and pancreatic juice respectively from the liver and the pancreas. The bile salts (from the liver) break down the large fat globules into smaller globules so that the pancreatic enzymes can easily act on them. This is referred to as emulsification of fats. It takes place in the small intestine.
Question 6:
What is the role of saliva in the digestion of food?
Ans- Saliva is secreted by the salivary glands, located under the tongue. It moistens the food for easy swallowing. It contains a digestive enzyme called salivary amylase, which breaks down starch into sugar.
Q 7:What are the necessary conditions for autotrophic nutrition and what are its by-products?
Ans- Autotrophic nutrition takes place through the process of photosynthesis. Carbon dioxide, water,
chlorophyll pigment, and sunlight are the necessary conditions required for autotrophic nutrition.
Carbohydrates (food) and O2 are the by-products of photosynthesis.
sunlight
6CO2 + 6H2O --------------------> C6H12O6 + 6O2
Chlorophyll
Q 8:What are the differences between aerobic and anaerobic respiration? Name some organisms that use the anaerobic mode of respiration.
Answer
Anaerobic respiration occurs in the roots of some waterlogged plants, some parasitic worms,
animal muscles, and some micro-organisms such as yeasts.
Q 9:How are the alveoli designed to maximise the exchange of gases?
Ans- The alveoli are the small balloon-like structures present in the lungs. The walls of the alveoli consist of an extensive network of blood vessels. Each lung contains 300−350 million alveoli, making it is a total of approximately 700 million in both the lungs. The alveolar surface when spread out covers about 80m2area. This large surface area makes the gaseous exchange more efficient.
Q 10:What would be the consequences of a deficiency of haemoglobin in our bodies?
Ans- Haemoglobin is the respiratory pigment that transports oxygen to the body cells for cellular
respiration. Therefore, deficiency of haemoglobin in blood can affect the oxygen supplying capacity of blood. This can lead to deficiency of oxygen in the body cells. It can also lead to a disease called anaemia.
Q 11:Describe double circulation in human beings. Why is it necessary?
Ans- The human heart is divided into four chambers − the right atrium, the right ventricle, the left
atrium, and the left ventricle.
Flow of blood in the heart:
• The heart has superior and inferior vena cava, which carries deoxygenated blood from the
upper and lower regions of the body respectively and supplies this de-oxygenated blood to
the right atrium of the heart.
The right atrium then contracts and passes the de-oxygenated blood to the right ventricle, through an auriculo-ventricular aperture.
Then the right ventricle contracts and passes the de-oxygenated blood into the two pulmonary arteries, which pumps it to the lungs where the blood becomes oxygenated.
From the lungs, the pulmonary veins transport the oxygenated blood to the left atrium of the heart. Then the left atrium contracts and through the auriculo-ventricular aperture, the oxygenated blood enters the left ventricle.
The blood passes to the aorta from the left ventricle. The aorta gives rise to many arteries that distribute the oxygenated blood to all the regions of the body.
Therefore, the blood goes twice through the heart. This is known as double circulation.
Importance of double circulation:
The separation of oxygenated and de-oxygenated blood allows a more efficient supply of oxygen to the body cells. This efficient system of oxygen supply is very useful in warm-blooded animals such as human beings.
As we know, warm-blooded animals have to maintain a constant body temperature by cooling
themselves when they are in a hotter environment and by warming their bodies when they are in a cooler environment. Hence, they require more O2 for more respiration so that they can produce more energy to maintain their body temperature. Thus, the circulatory system of humans is more efficient because of the double circulatory heart.
Q 12:What are the differences between the transport of materials in xylem and phloem?
Ans-
Q 13:Compare the functioning of alveoli in the lungs and nephrons in the kidneys with respect to their structure and functioning.
Ans-
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