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The Muscular System 1.Organ Level Structure & Function 2.System Level Structure & Function 3.Injury to the Musculoskeletal System 4.Muscular Analysis.

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Presentation on theme: "The Muscular System 1.Organ Level Structure & Function 2.System Level Structure & Function 3.Injury to the Musculoskeletal System 4.Muscular Analysis."— Presentation transcript:

1 The Muscular System 1.Organ Level Structure & Function 2.System Level Structure & Function 3.Injury to the Musculoskeletal System 4.Muscular Analysis

2 System Level Structure and Function General Structure & Function Multiarticular Muscles Muscle Actions Muscle Coordination

3 System Level Structure and Function General Structure & Function Multiarticular Muscles Muscle Actions Muscle Coordination

4 Simple Joint System

5 General System Level Function Force & Torque Production (for stabilization and/or movement)

6 Factors that Affect Force Output Physiological factors Cross-sectional area Fiber type Neurological factors Muscle fiber activation Rate of motor unit activation Biomechanical factors Muscle architecture Length-tension relationship Force-velocity relationship CHRONIC ACUTECHRONIC?

7 The Stretch-Shortening Cycle Lengthening-shortening contraction in which the active muscle is stretched before it shortens  Force & work Mechanisms 1.  time to develop force 2.  elastic energy storage in SEC 3.Force potentiation at CB 4.  response of stretch reflex

8 Reflex Control – The Reflex Arc

9 Reflex Control – Stretch Reflex

10 Mobility Determined by Torque Output Factors that Affect Torque Output Force Moment arm Point of force application (attachment site) Angle of force application (muscle insertion angle)

11 Muscle Attachments 1.Further from joint is better (theoretically) 2.Structural constraints negate #1 3.Cannot alter attachment sites 4.Strength differences due, in part, to attachment differences

12 Muscle Insertion Angle 1.90  is better 2.MIA typically < 45 3.MIA not constant through joint ROM, affecting strength through ROM 4.Cannot alter MIA 5.Strength differences due, in part, to MIA differences

13 Understanding Moment Arm Changes Through ROM JA = 150°JA = 120° MIA = 60 ° JA = 90° MIA = 90 ° JA = 45° MIA = 120 ° JA = 30° MIA = 150 ° MIA = 30 °

14 Understanding Moment Arm Changes Through ROM JA = 150° MIA = 30 ° JA = 120° MIA = 60 ° JA = 90° MIA = 90 ° JA = 45° MIA = 120 ° JA = 30° MIA = 150 °

15 Understanding Moment Arm Changes Through ROM JA = 150° MIA = 30 ° JA = 120° MIA = 60 ° JA = 90° MIA = 90 ° JA = 45° MIA = 120 ° JA = 30° MIA = 150 °

16 Biceps Brachii Strength Joint Angle (°) Torque (Nm) 0 90 180 Joint Angle

17 Understanding Rotational Effects Through ROM JA = 150° MIA = 30 ° JA = 120° MIA = 60 ° JA = 90° MIA = 90 °

18 Understanding Rotational Effects Through ROM JA = 45° MIA = 120 ° JA = 30° MIA = 150 °

19 JA = 150° MIA = 20° JA = 120° MIA = 20° JA = 90° MIA = 20° JA = 45° MIA = 20° JA = 30° MIA = 20°

20 Brachioradialis Strength Joint Angle (°) Torque (Nm) 0 90 180 Joint Angle

21 Summary of System Level Rotational Function Torque output varies across ROM Variation depends on: Force-length changes Moment arm changes Variation differs across muscles & joints

22 Muscle Force for Joint Stability Joint stability for injury prevention determined by linear effects of muscle pull.

23 Understanding Linear Effects Through ROM JA = 150° MIA = 30 ° JA = 120° MIA = 60 ° JA = 90° MIA = 90 °

24 Understanding Linear Effects Through ROM JA = 45° MIA = 120 ° JA = 30° MIA = 150 °

25 JA = 150° MIA = 20° JA = 120° MIA = 20° JA = 90° MIA = 20° JA = 45° MIA = 20° JA = 30° MIA = 20°

26 System Level Stabilization Function Stabilization role varies with MIA Bony structure Other muscle forces External forces

27 Effects of Bony Structure Source: Mediclip. (1995). Baltimore: Williams & Wilkins. F tangential F normal F tangential F normal F tangential F normal

28 Effects of Other Muscle Force

29 Effects of External Forces

30

31

32 System Level Function: Key Relationships What is the relationship between MIA & moment arm (MA)? What is the relationship between MIA & JA? What is the relationship between JA & MA? What is the role of the normal component? What is the relationship between the normal component and the MIA? What is the role of the tangential component? What is the relationship between the tangential component and the MIA?

33 General Structure & Function: Summary Torque output of muscle is affected by anything that affects moment arm or force output of muscle organ. Acute changes in torque through ROM dependent on force-length & MIA changes. Chronic changes in muscle torque dependent on training effects on physiological, neural, and biomechanical factors that affect force.

34 General Structure & Function: Summary Muscle force for stabilization function determined by physiological, neural, and biomechanical factors that affect force as well as MIA. Stabilization function defined by presence of Bony structure Other muscle forces External forces

35 System Level Structure and Function General Structure & Function Multiarticular Muscles Muscle Actions Muscle Coordination

36 Multiarticular Muscles Advantages 1.Couples the motion at multiple joints 2.  shortening velocity as compared to one- joint 3.Redistributes power & torque throughout limb Disadvantages 1.Active insufficiency 2.Passive insufficiency

37 Active insufficiency

38 Active Insufficiency

39

40 Passive Insufficiency

41 System Level Structure and Function General Structure & Function Multiarticular Muscles Muscle Actions Muscle Coordination

42 Related Terminology  muscle action – the development of tension (force) by a muscle  functional muscle group – a group of muscles that are capable of causing a specific joint action (e.g., wrist radial deviators)  motive force (or torque) – force causing the observed movement  resistive force (or torque) – force opposing the observed movement

43 Types of Muscle Actions Concentric Eccentric Isometric

44 Concentric Shortens to cause movement Rotational movement Mechanically: Net Muscle (Motive) Torque > Net Resistive Torque

45 Eccentric Lengthens to resist, control, or slow down movement Rotational movement Mechanically: Net Muscle (Resistive) Torque < Net Motive Torque

46 Isometric Stays the same so that bone will stay fixed No movement Mechanically: Net Muscle Torque = Other Torque Total Net Torque = 0

47 System Level: Muscle Actions Resulting motion dependent on all torques acting about the joint (net torque) Isometric?Eccentric?Conditions for concentric?

48 Influence of Gravity & Speed Downward (with gravity) Upward (opposing gravity) Horizontal (perpendicular to gravity) Consider direction & speed of movement relative to gravity

49 System Level Structure and Function General Structure & Function Multiarticular Muscles Muscle Actions Muscle Coordination

50 Muscle Coordination: Roles that Muscles Play Agonists Antagonists Stabilizers Neutralizers

51 Agonist (Mover)  The role played by a muscle acting to cause a movement  Prime movers  Assistant movers Arbitrary distinction  Force development during concentric action  Relaxation during eccentric action

52 Antagonist The role played by a muscle acting to control movement of a body segment against some other non-muscle force to slow or stop a movement  Force development during eccentric action  Check ballistic movements  Relaxation during concentric action

53 Stabilizer  The role played by a muscle to stabilize (fixate) a body part against some other force  rotary (joint) stabilizer  linear (bone) stabilizer  Isometric muscle action

54 Neutralizer  The role played by a muscle to eliminate an unwanted action produced by an agonist Scapular or pelvic stabilization Multijoint muscles Elevation of the humerus  Muscle action varies

55 Cocontraction The simultaneous contraction of movers and antagonists

56 The Muscular System 1.Organ Level Structure & Function 2.System Level Structure & Function 3.Injury to the Musculoskeletal System 4.Muscular Analysis

57 To perform a muscular analysis: 1. Break the skill into phases. 2. Determine the joint action. 3. Determine the motive force – muscle or some other force? 4. Determine the resistive force – muscle or some other force?

58 To perform a muscular analysis (ID muscle actions and responsible groups): 5. Identify whether there are joints/bones that must be stabilized. 6. Identify z the FMG(s) that is(are) developing force. z the type of muscle action of the FMG(s). z the roles played by the FMG(s). 7. Identify neutralization.

59 Example 1: Biceps Curl Up PhaseDown Phase Joint Action Motive Force Resistive Force FMG Developing Force Muscle Action Flexion Muscle Weight/Gravity Concentric Elbow Flexors

60 Example 1: Biceps Curl Up PhaseDown Phase Joint Action Motive Force Resistive Force FMG Developing Force Muscle Action Flexion Muscle Weight/Gravity Concentric Extension Muscle Weight/Gravity Eccentric Elbow Flexors

61 Example 1: Biceps Curl Up PhaseDown Phase Joint Action Motive Force Resistive Force FMG Developing Force Muscle Action Flexion Muscle Weight/Gravity Concentric Extension Muscle Weight/Gravity Eccentric Elbow Flexors Agonists:FlexorsExtensors

62 Example 1: Biceps Curl Up PhaseDown Phase Joint Action Motive Force Resistive Force FMG Developing Force Muscle Action Flexion Muscle Weight/Gravity Concentric Extension Muscle Weight/Gravity Eccentric Elbow Flexors Antagonists:ExtensorsFlexors

63 Stabilization? 1. Rotary stabilization z Wrist flexors 2. Linear stabilization

64 Neutralization? 1. To prevent scapular or pelvic movement when moving humerus or femur z Shoulder girdle retractors z Shoulder girdle elevators 2. To prevent unwanted motion caused by multijoint muscles z Shoulder extensors z Forearm pronators

65 Neutralization 3. To prevent scapular movement during elevation of the humerus 4. Other? Biceps brachii – shoulder flexion, RU supination Brachialis – none Brachioradialis – RU motion Pronator teres – RU pronation

66 Summary Movement at a single joint is possible because of the complex coordination that occurs between numerous muscles. Therefore, all those muscles must have adequate strength to accomplish its task in a given movement. Injury to or lack of strength in any of those muscles can result in the inability to perform the movement.

67 Summary A muscular analysis allows us to identify the muscles that contribute to a movement and how they contribute to the movement. We can then prepare conditioning & rehabilitation programs that target utilized muscles appropriately.


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