Introduction to Biomechanics – MCQs

1. Biomechanics is the study of:

(A) Forces and their effects on living organisms

(B) Chemical reactions in the body

(C) Electrical activity of the heart

(D) Digestive processes

2. Kinematics studies:

(A) Motion without regard to forces

(B) Force production only

(C) Muscle metabolism

(D) Ligament length

3. Kinetics studies:

(A) Forces causing motion

(B) Joint angles only

(C) Muscle endurance only

(D) Ligament stability

4. Displacement refers to:

(A) Change in position

(B) Speed

(C) Mass

(D) Force

5. Velocity is:

(A) Rate of change of displacement

(B) Total distance traveled

(C) Muscle strength

(D) Torque

6. Acceleration is:

(A) Change in velocity over time

(B) Constant speed

(C) Force per unit area

(D) Mass times velocity

7. Force is measured in:

(A) Newtons

(B) Joules

(C) Watts

(D) Meters

8. Torque is defined as:

(A) Rotational force about an axis

(B) Linear displacement

(C) Muscle contraction only

(D) Bone density

9. Moment arm is:

(A) Perpendicular distance from axis of rotation to line of force

(B) Length of a bone

(C) Distance a muscle shortens

(D) Joint angle

10. Mechanical advantage is:

(A) Ratio of output force to input force

(B) Ratio of bone length to ligament length

(C) Muscle contraction velocity

(D) Joint angle

11. First-class lever example in the body:

(A) Neck extension

(B) Elbow flexion

(C) Calf raise

(D) Knee extension

12. Second-class lever example in the body:

(A) Heel raise (plantarflexion)

(B) Biceps curl

(C) Shoulder abduction

(D) Elbow extension

13. Third-class lever example in the body:

(A) Biceps curl

(B) Heel raise

(C) Neck flexion

(D) Jaw closure

14. Newton’s first law states:

(A) Object remains at rest or in uniform motion unless acted upon by a force

(B) Force equals mass times acceleration

(C) Action equals reaction

(D) Work equals force times distance

15. Newton’s second law:

(A) F = ma

(B) F = mv

(C) T = r × F

(D) W = F × d

16. Newton’s third law:

(A) Every action has an equal and opposite reaction

(B) F = ma

(C) Torque equals force times moment arm

(D) Work equals force times distance

17. Center of mass is:

(A) Average location of body mass

(B) Point of joint rotation

(C) Muscle attachment site

(D) Ligament origin

18. Ground reaction force is:

(A) Force exerted by the ground on the body

(B) Muscle contraction only

(C) Joint torque

(D) Bone reaction

19. Work is defined as:

(A) Force applied over a distance

(B) Force per unit area

(C) Mass times acceleration

(D) Torque times angular displacement

20. Power is:

(A) Work done per unit time

(B) Torque only

(C) Force times moment arm only

(D) Mass times velocity

21. Momentum is:

(A) Mass times velocity

(B) Mass times acceleration

(C) Torque times time

(D) Force per unit area

22. Impulse is:

(A) Force multiplied by time

(B) Mass times velocity

(C) Torque times displacement

(D) Work divided by distance

23. Stress on a tissue is:

(A) Force per unit area

(B) Torque applied

(C) Muscle contraction

(D) Joint rotation

24. Strain represents:

(A) Deformation relative to original length

(B) Force applied only

(C) Joint angle only

(D) Torque only

25. Inertia is:

(A) Resistance to change in motion

(B) Force applied

(C) Acceleration

(D) Torque

26. Linear momentum depends on:

(A) Mass and velocity

(B) Muscle strength only

(C) Torque only

(D) Ligament stiffness

27. Angular momentum depends on:

(A) Moment of inertia and angular velocity

(B) Linear velocity only

(C) Force applied only

(D) Muscle length only

28. Mechanical work efficiency is:

(A) Ratio of mechanical work output to energy input

(B) Force per unit area

(C) Torque per second

(D) Mass times acceleration

29. Biomechanical analysis helps in:

(A) Injury prevention and performance optimization

(B) Digestion only

(C) Circulation only

(D) Respiration only

30. Center of pressure represents:

(A) Point of application of ground reaction force

(B) Center of mass

(C) Muscle origin

(D) Torque

31. Force plate analysis measures:

(A) Ground reaction forces

(B) Muscle length

(C) Joint angles only

(D) Ligament stress only

32. EMG measures:

(A) Muscle activation and timing

(B) Torque only

(C) Bone density

(D) Ligament laxity

33. Range of motion analysis is part of:

(A) Kinematics

(B) Kinetics only

(C) Muscle strength only

(D) Balance testing only

34. Open kinetic chain exercises involve:

(A) Distal segment free

(B) Distal segment fixed

(C) Both arms fixed

(D) Whole body stationary

35. Closed kinetic chain exercises involve:

(A) Distal segment fixed

(B) Distal segment free

(C) Isolated joint movement only

(D) No movement

36. Angular velocity is:

(A) Rate of change of joint angle

(B) Linear displacement

(C) Torque only

(D) Mass times acceleration

37. Moment of inertia depends on:

(A) Mass and distribution around axis of rotation

(B) Bone length only

(C) Ligament strength only

(D) Muscle fiber type only

38. Joint reaction force analysis helps:

(A) Determine load transmitted across joint

(B) Measure heart rate

(C) Measure oxygen consumption

(D) Determine ligament elasticity

39. Lever systems in the body include:

(A) Bones, joints, and muscles

(B) Only muscles

(C) Only ligaments

(D) Only tendons

40. Biomechanical efficiency improves:

(A) Performance and reduces injury risk

(B) Only bone density

(C) Ligament length

(D) Tendon elasticity

41. Center of mass shifts during walking:

(A) Forward and upward cyclically

(B) Sideways only

(C) Remains static

(D) Rotates only

42. Stretch-shortening cycle involves:

(A) Eccentric followed by concentric muscle action

(B) Concentric only

(C) Isometric only

(D) Eccentric only

43. Peak torque of a joint is measured during:

(A) Isokinetic testing

(B) Walking only

(C) Stretching only

(D) Postural control only

44. Biomechanics aids in:

(A) Prosthetic design and orthotics

(B) Blood pressure measurement

(C) Lung function testing

(D) Nutritional analysis

45. Angular acceleration is:

(A) Rate of change of angular velocity

(B) Joint torque

(C) Muscle length

(D) Bone density

46. Friction in joints affects:

(A) Smoothness and efficiency of movement

(B) Bone density only

(C) Muscle hypertrophy

(D) Ligament elasticity

47. Viscoelastic tissues show:

(A) Both time- and rate-dependent mechanical behavior

(B) Only elastic behavior

(C) Only viscous behavior

(D) No mechanical behavior

48. Biomechanical modeling helps in:

(A) Predicting movement and joint loading

(B) Measuring blood sugar

(C) Lung capacity testing

(D) Muscle biopsy

49. Work-energy principle in biomechanics states:

(A) Work done equals change in mechanical energy

(B) Torque equals force

(C) Velocity equals acceleration

(D) Force equals mass times acceleration

50. Understanding biomechanics is essential for:

(A) Physiotherapy, sports science, and rehabilitation

(B) Digestion only

(C) Respiratory therapy only

(D) Pharmacology only