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Agonist and Antagonist Relationship. Agonist – is a muscle described as being primarily responsible for a specific joint movement while contracting Antagonist – is a muscle that counteracts or opposes the contraction of another muscle Simply, these are relative terms describing “opposites” .
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Agonist and Antagonist Relationship • Agonist – is a muscle described as being primarily responsible for a specific joint movement while contracting • Antagonist – is a muscle that counteracts or opposes the contraction of another muscle • Simply, these are relative terms describing “opposites”
If an agonist muscle is considered a concentric contractor for a movement then the antagonist muscle is the eccentric contractor for the same movement. • Generally, concentric and eccentric contractions do not occur at the same time for a given movement.
What determines which one is working is the purpose of movement, acceleration (speeding-up) or deceleration (slowing-down). • Examples
Steps to determine contraction type • Identify the joint movement • Identify the agonist (concentric contractor) and antagonist (eccentric contractor) for the joint movement • Determine if the movement is speeding-up (accelerating) or slowing-down (decelerating) • If speeding-up then agonist working concentrically • If slowing-down then antagonist working eccentrically
Elbow and Radioulnar Joint Movements • elbow - flexion and extension • Radioulnar (forearm) - pronation and supination
Biceps Brachii*O: Long Head – supraglenoid tubercle above the superior lip of glenoid fossaShort Head – coracoid process and upper lip of glenoid fossaI: Tuberosity of radius and bicipital aponeurosisA: Flexion of elbow, supination of forearm (radioulnar), weak flexion of shoulder, and weak abduction of shoulder
BrachialisO: Distal ½ anterior shaft of humerusI: Coronoid process of ulnaA: True flexion of the elbow
BrachioradialisO: Distal 2/3 of lateral condyloid (supracondyloid) ridge of humerusI: Lateral surface distal end of radius at the styloid processA: Flexion of elbow, pronation from supinated position to neutral (thumb up), supination from pronated position to neutral
Triceps brachiiO: Long head – infraglenoid tubercle below inferior lip of glenoid fossa of scapulaLateral head – upper ½ posterior surface of humerusMedial head – distal 2/3 of posterior surface of humerusI: Olecranon process of ulnaA: All heads: extension of elbow Long head: extension, adduction, and horizontal abduction of shoulder
AnconeusO: Posterior surface of lateral condyle of humerusI: Posterior surface of olecranon process and proximal ¼ of ulnaA: extension of elbow
Pronator teresO: Distal part of medial condyloid ridge of humerus and medial side of proximal ulnaI: Middle third of lateral surface of radiusA: Pronation of forearm (radioulnar) and weak flexion of elbow
Pronator quadratusO: Distal fourth anterior side of ulnaI: Distal fourth anterior side of radiusA: Pronation of forearm
SupinatorO: Lateral epicondyle of humerus and neighboring posterior part of ulnaI: Lateral surface of proximal radius just below the headA: Supination of forearm
Ligaments of the Elbow • Radial collateral ligament – provides lateral stability of the elbow; resists lateral displacement of elbow • Ulnar collateral ligament – provides medial stability of the elbow; resists medial displacement of elbow • Annular ligament – stabilizes the head of radius to the ulna and allows smooth articulation with the ulna
Introduction to Linear Kinetics • Linear Kinetics – the study of linear forces associated with motion (ex. force, momentum, inertia). • Linear Kinematics – the study of linear motion. • Force = mass x acceleration Force → Acceleration → Velocity → Displacement
Vector – is a quantity that has both magnitude (how much) and direction. • Used as a measuring tool for linear variables which have both magnitude and direction. • Illustrated by an arrow where the tip represents direction and the length representing magnitude.
Muscle Force – can be measured with vectors, since muscle force pulls on bone in a linear fashion. • Vector composition – is a process of determining a single vector (usually called resultant) from two or more vectors.
Vectors can typically be analyzed as having horizontal (x) and vertical (y) components. • In this case, these perpendicular component vectors can be used to form a right triangle. • A common trigonometric principle used is the Pythagorean theorem, where A2 + B2 = C2. C θ A θ B
Furthermore, the following equations are derived from the Pythagorean theorem: sin θ = opposite / hypotenuse cos θ = adjacent / hypotenuse tan θ = opposite / adjacent C θ A θ B
Sample Problem If the muscle force generated by the biceps brachii is 20 lbs, how much rotary (y) force is generated by the muscle? How much dislocating (x) force?
Known: angle of pull = 45 degrees Muscle force (resultant) = 20 lbs Unknown: rotary (y) force dislocating (x) force
Rotary force (y) calculation: sin θ = opposite / hypotenuse sin 45 = rotary (y) / 20 lbs sin 45 x 20 lbs = rotary (y) rotary (y) = 14.14 lbs
Dislocating force calculation: cos θ = adjacent / hypotenuse cos 45 = dislocating (x) / 20 lbs cos 45 x 20 lbs = dislocating (x) dislocating = 14.14 lbs
Pythagorean Check A2 + B2 = C2 (rotary force)2 + (dislocating force)2 = (muscle force)2 (14.14 lbs)2 + (14.14 lbs)2 = (muscle force)2 399.88 lbs = (muscle force)2 √ 399.88 = muscle force 20 lbs = muscle force