Chapter 7 - Human Movement Science

Question 1

Human movement system (HMS)

Answer 1

The collective components and structures that work together to move the body: muscular, skeletal, and nervous systems.

Question 2

Kinetic chain

Answer 2

A concept that describes the human body as a chain of interdependent links that work together to perform movement.

Question 3

Regional interdependence model

Answer 3

The concept describing the integrated functioning of multiple body systems or regions of the body.

Question 4

Biomechanics

Answer 4

The science concerned with the internal and external forces acting on the human body and the effects produced by these forces.

Question 5

Kinesiology

Answer 5

Study of movement as it relates to anatomy and physiology.

Question 6

Anatomic position

Answer 6

The position with the body erect, the arms at the sides, and the palms forward. It is the position of reference for anatomic nomenclature.

Question 7

Osteokinematics

Answer 7

Movement of a limb that is visible.

Question 8

Arthrokinematics

Answer 8

The description of joint surface movement; consists of three major types: roll, slide, and spin.

Question 9

Sagittal plane

Answer 9

An imaginary bisector that divides the body into left and right halves.

Question 10

Flexion

Answer 10

A bending movement in which the relative angle between two adjacent segments decreases.

Question 11

Extension

Answer 11

A straightening movement in which the relative angle between two adjacent segments increases.

Question 12

Hyperextension

Answer 12

Extension of a joint beyond the normal limit or range of motion.

Question 13

Dorsiflexion

Answer 13

Flexion occurring at the ankle.

Question 14

Plantar flexion

Answer 14

Extension occurring at the ankle. Pointing the foot downwards.

Question 15

Frontal plane

Answer 15

An imaginary bisector that divides the body into front and back halves. Movement in the frontal plane includes abduction, adduction, and side-to-side motions.

Question 16

Abduction

Answer 16

A movement in the frontal plane away from the midline of the body.

Question 17

Adduction

Answer 17

Movement in the frontal plane back toward the midline of the body.

Question 18

Lateral flexion

Answer 18

Bending of the spine from side to side.

Question 19

Eversion

Answer 19

A movement in which the inferior calcaneus (heel bone) moves laterally. The bottom of foot faces outward.

Question 20

Inversion

Answer 20

A movement in which the inferior calcaneus (heel bone) moves medially. Bottom of foot faces inward.

Question 21

Transverse plane

Answer 21

An imaginary bisector that divides the body into top and bottom halves.

Question 22

Internal rotation

Answer 22

Rotation of a body segment toward the middle of the body.

Question 23

External rotation

Answer 23

Rotation of a body segment away from the middle of the body.

Question 24

Horizontal abduction

Answer 24

Movement of the arm or thigh in the transverse plane from an anterior position to a lateral position.

Question 25

Horizontal adduction

Answer 25

Movement of the arm or thigh in the transverse plane from a lateral position to an anterior position.

Question 26

Radioulnar pronation

Answer 26

Inward rotation of the forearm from a palm-up position to a palm-down position.

Question 27

Radioulnar supination

Answer 27

Outward rotation of the forearm from a palm-down position to a palm-up position.

Question 28

Pronation of the foot

Answer 28

Multiplanar movement of the foot and ankle complex consisting of eversion, dorsiflexion, and ankle abduction; associated with force reduction.

Question 29

Supination of the foot

Answer 29

Multiplanar movement of the foot and ankle complex consisting of inversion, plantar flexion, and ankle adduction; associated with force production.

Question 30

Gait

Answer 30

Biomechanical motion of the lower extremities during walking, running, and sprinting.

Question 31

Scapular retraction

Answer 31

Adduction of scapulae; shoulder blades move toward the midline.

Question 32

Scapular protraction

Answer 32

Abduction of scapulae; shoulder blades move away from the midline.

Question 33

Scapular depression

Answer 33

Downward (inferior) motion of the scapulae.

Question 34

Scapular elevation

Answer 34

Upward (superior) motion of the scapulae.

Question 35

Elasticity

Answer 35

The ability of soft tissues to return to resting length after being stretched.

Question 36

Ligament

Answer 36

A fibrous connective tissue that connects bone to bone.

Question 37

Flexibility

Answer 37

The normal extensibility of soft tissues that allows for full range of motion of a joint.

Question 38

Hypermobility

Answer 38

A state where a lack of neuromuscular support leads to a joint having more range of motion than it should, greatly increasing the risk of injury at that joint.

Question 39

Hypomobility

Answer 39

When range of motion at a joint is limited.

Question 40

Eccentric muscle action

Answer 40

A muscle action that occurs when a muscle develops tension while lengthening.

Question 40

Motor unit

Answer 40

A motor neuron and all of the muscle fibers that it innervates.

Question 41

Concentric muscle action

Answer 41

A muscle action that occurs when a muscle is exerting force greater than the resistive force, resulting in a shortening of the muscle.

Question 42

Isometric muscle action

Answer 42

When a muscle is exerting force equal to the force being placed on it leading to no visible change in the muscle length.

Question 43

Core

Answer 43

The structures that make up the lumbo-pelvic-hip complex (LPHC), including the lumbar spine, pelvic girdle, abdomen, and hip joint.

Question 44

Muscle action spectrum

Answer 44

The full range of eccentric, isometric, and concentric muscle contractions required to perform a movement.

Question 45

Agonists

Answer 45

The primary muscles providing force for a movement.

Question 46

Synergists

Answer 46

Muscles that assist agonists to produce a movement.

Question 47

Stabilizers

Answer 47

Muscles that contract isometrically to stabilize the trunk and joints as the body moves.

Question 48

Feed-forward activation

Answer 48

When a muscle is automatically activated in anticipation of a movement.

Question 49

Antagonists

Answer 49

Muscles on the opposite side of a joint that are in direct opposition of agonist muscles.

Question 50

Force

Answer 50

An influence applied by one object to another, which results in an acceleration or deceleration of the second object.

Question 51

Length-tension relationship

Answer 51

The resting length of a muscle and the tension the muscle can produce at this resting length.

Question 52

Resting length

Answer 52

The length of a muscle when it is not actively contracting or being stretched.

Question 52

Actin

Answer 52

The thin, stringlike, myofilament that acts along with myosin to produce muscular contraction.

Question 53

Myosin

Answer 53

The thick myofilament that acts along with actin to produce muscular contraction.

Question 54

Sarcomere

Answer 54

The structural unit of a myofibril composed of actin and myosin filaments between two Z-lines.

Question 55

Muscle balance

Answer 55

When all muscles surrounding a joint have optimal length-tension relationships, allowing the joint to rest in a neutral position.

Question 56

Altered length-tension relationship

Answer 56

When a muscle’s resting length is too short or too long, reducing the amount of force it can produce.

Question 57

Reciprocal inhibition

Answer 57

When an agonist receives a signal to contract, its functional antagonist also receives an inhibitory signal allowing it to lengthen.

Question 58

Altered reciprocal inhibition

Answer 58

Occurs when an overactive agonist muscle decreases the neural drive to its functional antagonist.

Question 59

Muscle imbalance

Answer 59

When muscles on each side of a joint have altered length-tension relationships.

Question 60

Neutral position

Answer 60

The optimal resting position of a joint that allows it to function efficiently through its entire normal range of motion.

Question 61

Stretch-shortening cycle

Answer 61

Loading of a muscle eccentrically to prepare it for a rapid concentric contraction.

Question 62

Series elastic component

Answer 62

Springlike noncontractile component of muscle and tendon that stores elastic energy.

Question 63

Amortization phase

Answer 63

The transition from eccentric loading to concentric unloading during the stretch-shortening cycle.

Question 64

Stretch reflex

Answer 64

Neurological signal from the muscle spindle that causes a muscle to contract to prevent excessive lengthening.

Question 65

Integrated performance paradigm

Answer 65

To move with efficiency, forces must be dampened (eccentrically), stabilized (isometrically), and then accelerated (concentrically).

Question 66

Tendon

Answer 66

A fibrous connective tissue that connects muscle to bone.

Question 67

Force-couple relationship

Answer 67

The synergistic action of multiple muscles working together to produce movement around a joint.

Question 68

Joint support systems

Answer 68

Muscular stabilization systems located in joints distal of the spine.

Question 69

Rotary motion

Answer 69

Movement of the bones around the joints.

Question 70

Torque

Answer 70

A force that produces rotation; common unit of measurement is the Newton meter (Nm).

Question 71

Motor behavior

Answer 71

Motor response to internal and external environmental stimuli.

Question 72

Motor control

Answer 72

How the central nervous system integrates internal and external sensory information with previous experiences to produce a motor response.

Question 73

Motor learning

Answer 73

Integration of motor control processes through practice and experience, leading to a relatively permanent change in the capacity to produce skilled motor behavior.

Question 74

Motor development

Answer 74

Change in skilled motor behavior over time throughout the life span.

Question 75

Muscle synergies

Answer 75

Groups of muscles that are recruited simultaneously by the central nervous system to provide movement.

Question 76

Mechanoreceptors

Answer 76

Specialized structures that respond to mechanical forces (touch and pressure) within tissues and then transmit signals through sensory nerves.

Question 77

Proprioception

Answer 77

The body’s ability to naturally sense its general orientation and relative position of its parts.

Question 78

Sensorimotor integration

Answer 78

Cooperation of the nervous and muscular system in gathering and interpreting information and executing movement.

Question 79

Feedback

Answer 79

Use of sensory information and sensorimotor integration to help the human movement system in motor learning.

Question 80

Internal feedback

Answer 80

Process whereby sensory information is used by the body to reactively monitor movement and the environment.

Question 81

External feedback

Answer 81

Information provided by some external source, such as a fitness professional, video, mirror, or heart rate monitor, to supplement the internal environment.

Question 82

Neuromuscular efficiency

Answer 82

The ability of the nervous system to recruit the correct muscles to produce force, reduce force, and dynamically stabilize the body’s structure in all three planes of motion.