NCERT Solution for Class 11 Biology Chapter 18 BODY FLUIDS AND CIRCULATION

Welcome to the NCERT Solutions for Class 11 Biology Chapter 18 – Body Fluids and Circulation, provided by Swastik Classes. In this chapter, you will learn about the circulatory system, which plays a crucial role in maintaining homeostasis in the body.

You will explore the different components of blood, the various types of blood vessels, and the function of the heart. Additionally, you will learn about the regulation of blood pressure and the exchange of materials between blood and tissues.

Swastik Classes has created these NCERT Solutions to help you understand the concepts in this chapter effectively. Our solutions are designed to provide you with a thorough understanding of the topics and assist you in preparing for exams. So, let’s dive into the fascinating world of body fluids and circulation!

NCERT Solution for Class 11 Biology Chapter 18 BODY FLUIDS AND CIRCULATION – Exercises

1. Name the components of the formed elements in the blood and mention one major function of each of them.

Sol. Blood corpuscles are the formed ele-ments in the blood, they constitute 45% of the blood. Formed elements are – (erythrocytes, RBCs or red blood corpuscles), (leucocytes, WBCs or white blood corpuscles) and throm¬bocytes or blood platelets. The major function of RBCs is to transport oxygen from lungs to body tissues and COz from body tissues to the lungs. White blood cells provide immunity to the body. Blood platelets play important role in blood clotting.

2. What is the importance of plasma proteins?

Sol. Plasma proteins constitute about 7 to 8% of plasma. These mainly include albumin, globulin, prothrombin and fibrinogen. Prothrombin and fibrinogen are needed for blood clotting. Albumins and globulins retain water in blood plasma and helps in maintain ingosmotic balance. Certain globulins

3. Match Column I with Column II.

Column I                          Column II

(a) Eosinophils               (i) Coagulation

(b) RBC                            (ii) Universal recipient

(c) AB Group                  (iii) Resist infections

(d) Platelets                    (iv) Contraction of heart

(e) Systol                         (v) Gas transport

Sol.(a) – (iii); (b) – (v); (c) – (ii); (d) – (i); (e) – (iv).

4. Why do we consider blood as a connective tissue?

Sol. A connective tissue connects different tissues or organs of the body. It consists of living cells and extracellular matrix. Blood is vascular connective tissue, it is a mobile tissue consisting of fluid matrix and free cells. Blood transports materials from one place to the other and thereby establishes connectivity between different body parts.

5. What is the difference between lymph and blood?

Sol. The differences between blood and lymph are given below:


6. What is meant by double circulation? What is its significance?

Sol. The type of blood circulation in which oxygenated blood and deoxy genated blood do not get mixed is termed double circulation. It includes systemic circulation and pulmonary circulation. The circulatory pathway of double circulation is given in the following flow chart.


Flow chart: Double blood circulation Double circulation or separation of systemic and pulmonary circulations provides a higher metabolic rate to the body and also allows the two circulations to have different blood pressures according to the need of the organs they supply.

7. Write the differences between:

(a) Blood and lymph

(b) Open and closed system of circulation

(c) Systole and diastole

(d) P-wave and T-wave

Solutlion: (a) Refer answer 5.

(b) The differences between open and closed circulatory system are given below:


(c) Systole is contraction of heart chambers in order to pump out blood while diastole is relaxation of heart chambers to receive blood. The contraction of a chamber or systole decreases its volume and forces the blood out of it, whereas its relaxation or diastole brings it back to its original size to receive more blood.

(d) P wave is a small upward wave of elec-trocardiograph that indicates the atrial depolarisation (contraction of atria). It is caused by the activation of SA node. T-wave is a dome shaped wave of electro-cardiograph which represents ventricular repolarisation (ventricular relaxation).

8. Describe the evolutionary change in the pattern of heart among the vertebrates.

Sol. Vertebrates have a single heart. It is a hollow, muscular organ composed of cardiac muscle fibres. Two types of chambers in heart are atria and ventricles. The heart of lower vertebrates have additional chambers, namely sinus venosus and conus arteriosus or bulbus arteriosus or truncus arteriosus. During the course of development, in higher vertebrates, the persistent portions viz, auricles and ventricles are retained. However, these get complicated by incorporating several valves inside them and becoming compartmentali sed.

In fishes, heart is two chambered (1 auricle and 1 ventricle). Both the accessory chambers, sinus venosus and conus arteriosus are present. The heart pumps out deoxygenated blood which is oxygenated by the gills and sent to the body parts from where deoxygenated blood is carried to the heart. It is called single circulation and heart is called venous heart. Lung fish, amphibians and reptiles have three chambered heart, (2 auricles and 1 ventricle). The left atrium gets oxygenated blood from the gills/ lungs /skin/bucco pharyngeal cavity and the right atrium receives the deoxygenated blood from other body parts. But both oxygenated and deoxygenated blood get mixed up in single ventricle which pumps out mixed blood. This is called incomplete double circulation.

Crocodiles, birds and mammals have a complete four chambered heart (right and left auricles; right and left ventricles). Oxygenated and deoxygenated blood never get mixed. Right parts of the heart receive deoxygenated blood from all other body parts and send it to lungs for oxygenation whereas left parts of heart receive oxygenated blood from lungs and send it to other body parts. This mode of circulation is termed as complete double circulation which includes systemic and pulmonary circulation. There are no accessory chambers in heart of birds and mammals.

9. Why do we call our heart myogenic?

Sol. The heart of molluscs and vertebrates including humans is myogenic. It means heart beat is initiated in heart itself by a patch of modified heart muscle called sino-atrial node or pacemaker which lies in the wall of the right atrium near the opening of the superior vena cava.

10. Sino-atrial node is called the pacemaker of our heart. Why?

Sol. Sino-atrial node (SAN) is a mass of neuromuscular tissue which lies in the wall of right atrium. It is responsible for initiating and maintaining the rhythmic contractile activity of the heart. Therefore, it is called the pacemaker.

11. What is the significance of atrio-ventricular node and atrio-ventricular bundle in the functioning of heart?

Sol. Atrio-ventricular node (AVN) is a mass of neuromuscular tissue, which is situated in wall of. right atrium, near the base of inter-atrial septum. AV node is the pacesetter of the heart,- as it transmits the impulses initiated by SA node to all parts of ventricles. Atrio-ventricular bundle (A-V bundle) or bundle of His is a mass of specialised fibres which originates from the AVN. Within the myocardium of the ventricles the branches of bundle of His divide into a network of fine fibres called Purkinje fibres. The bundle of His and the Purkinje fibres convey impulse of contraction from the AVN to the myocardium of the ventricles.

12. Define a cardiac cycle and the cardiac output.

Sol. The sequential events in the heart which are repeated cyclically is called cardiac cycle and it consists of systole (contraction) and diastole (relaxation) of both the atria and ventricles. The duration of a cardiac cycle is 0.8 seconds. Periods of cardiac cycle are atrial systole (0.1 second), ventricular systole (0.3 second) and complete cardiac diastole (0.4 second).

The amount of blood pumped by heart per minute is called cardiac output. It is calculated by multiplying stroke volume (volume of blood pumped by each ventricle per minute) with heart rate (number of beats per minute). The heart of normal person beats 72 times per minute and pumps out about 70 mL of blood per beat. Therefore, cardiac output averages 5000 mL or 5 litres.

13. Explain heart sounds.

Sol. The beating of heart produces characteristic sounds which can be heard by using stethoscope. In a normal person, two sounds are produced per heart beat. The first heart sound Tubb’ is low pitched, not very loud and of long duration. It is caused partly by the closure of the bicuspid and tricuspid valves and partly by the contraction of muscles in the ventricles.

The second heart sound ‘dubb’ is high pitched, louder, sharper and shorter in duration. It is caused by the closure of the semilunar valves and marks the end of ventricular systole.

14. Draw a standard ECG and explain the different segments in it.

Sol. ECG is graphic record of the electric current produced by the excitation of the cardiac muscles. The instrument used to record the changes is an electrocardiograph. A normal electrogram (ECG) is composed of a P wave, a QRS wave (complex) and a T wave. The P Wave is a small upward wave that represents electrical excitation or the atrial depolarisation which leads to contraction of both the atria (atrial contraction). It is caused by the activation of SA node. The impulses of contraction start from the SAnode and spread throughout the artia.

The QRS Wave (complex) represents ventricular depolarisation (ventricular contraction). It is caused by the impulses of the contraction from AV node through the bundle of His and Purkinje fibres and the contraction of the ventricular muscles. Thus this wave is due to the spread of electrical impulse through the ventricles.

The T Wave represents ventricular repolarisation (ventricular relaxation). The potential generated by the recovery of the ventricle from the depolarisation state is called the repolarisation wave. The end of the T-wave marks the end of systole.

ECG gives accurate information about the heart. Therefore, ECG is of great diagnostic value in cardiac diseases.


Conclusions for NCERT Solution for Class 11 Biology Chapter 18 BODY FLUIDS AND CIRCULATION

the NCERT Solutions for Class 11 Biology Chapter 18 – Body Fluids and Circulation, provided by Swastik Classes, have offered a comprehensive and detailed understanding of the circulatory system in the human body.

Through these solutions, you have learned about the composition and functions of blood, the different types of blood vessels, and the role of the heart in pumping blood throughout the body. You have also explored the regulation of blood pressure, the exchange of materials between blood and tissues, and the transport of respiratory gases such as oxygen and carbon dioxide.

Furthermore, these solutions provide you with a thorough understanding of the various topics covered in the chapter, making it easier for you to prepare for exams and score good marks.

Swastik Classes hopes that these NCERT Solutions have been helpful in enhancing your knowledge of body fluids and circulation. We encourage you to keep exploring the fascinating world of biology and stay curious.

What is the function of the circulatory system? 

The circulatory system functions to transport blood, nutrients, oxygen, carbon dioxide, hormones, and waste products throughout the body. It also plays a vital role in maintaining homeostasis by regulating body temperature and pH levels.

What are the components of blood? 

Blood is composed of three main components: red blood cells, white blood cells, and plasma. Red blood cells contain hemoglobin and transport oxygen from the lungs to the tissues. White blood cells help defend the body against infection and disease. Plasma is a yellowish liquid that carries nutrients, hormones, and waste products.

What is the difference between arteries and veins?

Arteries carry oxygenated blood away from the heart to the rest of the body, while veins carry deoxygenated blood back to the heart. Arteries have thicker walls and smaller lumens, while veins have thinner walls and larger lumens. Additionally, arteries have a pulse due to the pressure of blood being forced through them, while veins do not.

How does the heart regulate blood pressure? 

The heart regulates blood pressure through a combination of factors, including heart rate, stroke volume, and the diameter of blood vessels. The heart rate and stroke volume determine the amount of blood pumped out of the heart with each beat, while the diameter of blood vessels controls the resistance to blood flow. Hormones such as adrenaline and aldosterone also play a role in regulating blood pressure.

What is the role of the lymphatic system in circulation?

The lymphatic system functions to collect excess fluid and proteins that have leaked from blood vessels and return them to the circulatory system. It also helps defend the body against infection by producing and transporting white blood cells called lymphocytes.

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