Shoulder Complex Chapter 5 PDF

Summary

This document is a chapter on the shoulder complex, focusing on the anatomy, physiology and mechanics of joints involved. It includes details regarding the bones of the shoulder, arthrology, and kinematics.

Full Transcript

Shoulder Complex

Chapter 5
PTH516 Pathokinesiology
Letrisha Stallard, DPT
Introduction
 bones of shoulder:

Osteology clavicle
scapula
humerus
sternum
rib

Clavicle – Note that the long axis is positioned
about 20 degrees posterior to the frontal plane.
axis runs through bone

*know these angles*

Scapular plane, motion is
called scaption which
combines abduction and
flexion
 Osteology
Humeral head is positioned ~30 degrees POSTERIORLY relative to the M-L axis
through the elbow (retroversion) WHICH ACCOMMODATES THE SCAPULAR
PLANE.
 Arthrology (joints)

not really a joint (not
bone on bone and its
actually the
Sternoclavicular jt and
Acromioclavicular jt that
makes it move)
Primary Movements of ST Joint

A. Pure frontal plane, superior and inferior on thorax
B. Medial scapular border slides anterior-laterally and posterior-medially
C. Glenoid fossa tilts upward and downward, OR inferior angle of scapula rotates superior-laterally and
inferior-medially.
 Sternoclavicular Joint
basilar joint (saddle, plane, modified ball and socket)

Only structural attachment of clavicle,
scapula, and UE to the axial skeleton

Very stable joint – clavicular fx often occurs
before SC joint dislocates
 Sternoclavicular Joint
Clavicle
Joint surface convex
longitudinal diameter,
concave transverse
diameter

Sternum
Joint surface concave
longitudinal diameter,
convex transverse
diameter
 Sternoclavicular Joint
Articular disc
Separates
joint into
medial and
lateral
cavities
Functions
Strengthens
articulation
Shock
Ligaments absorption
Anterior & posterior sternoclavicular
Interclavicular
Costoclavicular (anterior and posterior bundles) [run
perpendicular to each other]
 Sternoclavicular Joint
Stabilizing muscles
Sternocleidomastoid
(anteriorly)
Sternothyroid (posteriorly)
Sternohyoid (posteriorly)
Subclavius (inferiorly)
 KINEMATICS
Osteokinematics Arthrokinematics
-Joint classification -Motion occurring between
-Degrees of Freedom bony joint surfaces
-Planes and Axes
-Convex/concave rule
-Description of motion (esp.
if not cardinal planes) -Motion-specific stability
-Amount of Motion (in provided by ligaments and
degrees) capsule

Sternoclavicular joint Degrees of Freedom: 3
 SC Elevation
Frontal plane
A/P axis
35-45⁰ ROM
Convex surface of clavicle rolls superiorly & slides inferiorly
on concave sternum
 SC Elevation
Motion-limiting periarticular C.T. at end range
Costoclavicular ligament
Force of stretched ligament same direction as slide
 SC Depression
Frontal plane
A/P axis
10⁰ ROM limited ROM due to ribs being there
Convex surface of clavicle rolls inferiorly & slides
superiorly on concave sternum
 SC Depression
Motion-limiting periarticular C.T. at end range
Interclavicular ligament
Capsule (superior portion)
 SC Protraction
Horizontal plane (nearly)
Vertical axis
15 - 30⁰ ROM
Concave surface of clavicle slides anteriorly on convex
surface of sternum
 SC Protraction
Motion-limiting periarticular C.T. at end range
Costoclavicular ligament (posterior bundle)
Capsular ligament (posterior portion)
Motion-limiting muscles
Scapular retractors
 SC Retraction
Horizontal plane (nearly)
Vertical axis
15 - 30⁰ ROM
Concave surface of clavicle slides posteriorly on convex
surface of sternum
 SC Retraction
Motion-limiting periarticular C.T. at end range
Costoclavicular ligament (anterior bundle)
Capsular ligament (anterior bundle)
Sternoclavicular Axial Rotation
Longitudinal axis through SC and AC joints (Fig. 5-13) (sagittal plane)
20 - 35⁰ ROM posterior rotation
Spin of sternal end of clavicle on lateral surface of
articular disc
 Sternoclavicular Axial Rotation
Motion-limiting periarticular C.T. at end range
Costoclavicular ligament (anterior bundle)
Capsular ligament (anterior bundle)
Acromioclavicular Joint — Plane (gliding) joint
(2 jts making one)

Degrees of Freedom: 3

Articulation:
Clavicle
Scapula
Acromioclavicular Joint
Joint capsule directly reinforced by
superior and inferior AC ligaments
Ligaments
Superior & inferior
acromioclavicular
Coracoclavicular
Articular disc
Stabilizing muscles
Deltoid
Trapezius
Aponeurotic
AC Upward rotation

Scapular plane
A-P axis
Up to 30⁰ ROM
Gliding arthrokinematics
Close-packed position of AC joint is
upward rotation
AC Upward rotation

Motion-limiting periarticular C.T. at
end range
Coracoclavicular ligament (both
portions)
Capsule (inferior portion)
AC Downward rotation

Scapular plane usually (motion occurs
naturally during shoulder ext. or add.)
A-P axis
Motion-limiting periarticular C.T. at end
range
Capsule (superior portion)
Horizontal plane rotational adjustments
Vertical axis
During internal rotation of AC joint, the
medial border of the scapula pivots away
from thorax
During external rotation of AC joint, the
medial border of the scapula pivots toward
the thorax
Up to 30 ROM
Acromial joint surface spins on clavicle
Motion-limiting periarticular C.T. at end range
Not researched well
Functional significance of motion
Optimally- aligns scapula against the thorax
Adds to total motion of scapula
Sagittal plane rotational adjustments
Medial-lateral axis (nearly)
During anterior tilting (of glenoid fossa) the
inferior angle of the scapula pivots away
from posterior surface of the thorax
During posterior tilting the inferior angle
pivots toward the thorax
5-30⁰ ROM
Motion-limiting periarticular C.T. at end range
Not researched well
AC Joint Dislocation
Fall on shoulder or
outstretched arm
SC joint is stronger that AC
joint
Type I = partial
damage to ligaments
(sprain)
Type II = complete tear
of AC & partial tear of
CC
Type III dislocation =
AC & CC torn, resulting
in permanent bump
Type IV = AC tear and
avulsion of CC from
clavicle]
Scapulothoracic Joint —not a true joint
Articulation: Point of
contact between the
anterior surface of the
scapula and the
posterior-lateral wall of
the thorax.
-> separated by
muscle.

Scapula position: Ribs 2-7,
scapular plane, medial
border 6 cm from spine
Scapulothoracic Jointt
Shock absorption
(scapular muscles)
protects the shoulder
(fall on outstretched
arm)
Stabilizing muscles
Rhomboids
Trapezius
Serratus anterior

Primary movements of Scapulothoracic Jointt
Degrees of freedom: 3

1. Elevation and depression (pure frontal plane, superior and inferior on
thorax)

2. Protraction and retraction (medial scapular border slides
anterior-laterally and posterior -medially)

3. Upward and downward rotation (Glenoid fossa tilts upward and
downward, or inferior angle of scapula rotates
superior- laterally and inferior -medially.)

Movement of ST joint must result in movement of SC and/or AC joint
movement emphasis
Primary role is to assist GH joint motion, thus increasing the GH joint
range of motion.
 ST Joint Elevation/Depression
Elevation (shoulder shrug)
SC joint elevation
AC joint downward rotation
Depression occurs opposite to elevation
 ST Joint Protraction/Retraction
Protraction
SC joint protraction
AC joint internal rotation
Retraction
SC joint retraction
AC joint external rotation
ST Joint Upward/Downward Rotation
Upward rotation Downward rotation
60⁰ from: 60⁰ from:
○ SC joint elevation (30⁰) ○ SC joint depression (30⁰)
○ AC joint upward rotation (30⁰) ○ AC joint downward rotation (30⁰)
 Glenohumeral Joint
Ball and Socket
Articulation
Glenoid fossa of
scapula
Humeral head

1. Glenoid fossa: anterior-lateral and slightly
upward 4 degrees

2.
Glenohumeral Capsular Ligaments
 Superior GH Capsular Ligament
Taut in full ER , then restrains inferior and anterior translations
of the humeral head
 Middle GH Capsular Ligament
Taut with anterior translation of humeral head, especially with
45-90⁰ abduction. Taut at end range of external rotation.
 Inferior GH Capsular Ligament
Anterior band taut with combined 90⁰ abd. & full external rotation so will
resist ant. translation of humeral head
Posterior band taut with combined 90⁰ abduction and full internal
rotation
Axillary pouch (connects anterior & posterior bands) becomes taut in 90⁰
abduction
Coracohumeral Ligament
Blends with
superior capsule
and supraspinatus
tendon
Taut with humeral
adduction so will
restrain inferior
translation and
external rotation
of the humeral
head
Stabilizing Muscles
Subscapularis S
Infraspinatus I rotator cuff muscles
Teres minor T
Supraspinatus S
Long head biceps tendon
Glenoid labrum

Joint stabilization by increasing humeral head contact area
 Scapulothoracic Posture
At complete rest with arms hanging at side the humeral head is stable
(static stability)
Superior capsular structures
Gravity
Resultant force prevents inferior displacement of the humerus
Inclined plane of glenoid
 Scapulothoracic Posture
Increased demand calls upon secondary muscular support
Rotator cuff muscles
Posterior deltoid
 PATHOKINESIOLOGY
Loss of upwardly rotated glenoid fossa may cause
subluxation/dislocation of humeral head
Could be caused by poor posture
Coracoacromial Arch

Formed by
coracoacromial
ligament and the
acromion process
Coracoacromial Arch
Contents
Supraspinatus
muscle and tendon
Subacromial bursa
Long head of
biceps tendon
Superior capsule
(portion)
 Glenohumeral Kinematics
Degrees of Freedom: 3
GH Abduction
Frontal plane
A-P axis
120⁰
Convex head rolls
superiorly and
slides inferiorly
Close-packed
position of is GH
full abduction
with full external
rotation

Motion-limiting periarticular C.T.
Inferior GH
capsular ligament
(all portions)
Middle GH
capsular ligament
(Norkin and
White)
Protective and
Stabilizing structures
Supraspinatus
tendon
GH Adduction
Frontal plane
A-P axis
Return to neutral
from raised
position
Convex head rolls
inferiorly and
slides superiorly
No CT restriction
GH Flexion
Sagittal plane
M-L axis
120⁰ ROM same as
abd
Spin of humeral
head in glenoid fossa
Motion-limiting
periarticular C.T. at end
range
Inferior GH capsular
ligament
Posterior capsular
ligament
Coracohumeral
ligament
GH Extension
Sagittal plane
(near)
M-L axis (near)
~65⁰ actively, 80⁰
passively

Motion-limiting
periarticular C.T. at end
range
Anterior GH
capsular ligament
Coracohumeral
ligament
GH Internal Rotation
Vertical axis
Horizontal plane
75-85⁰ ROM
Convex head rolls anteriorly
and slides posteriorly on
concave glenoid fossa
○ Note: spin occurs if IR
motion occurs in 90⁰
abducted position
Motion-limiting periarticular C.T. at
end range
Posterior GH joint capsule
Inferior GH ligament
(posterior band)
Coracohumeral ligament
(posterior portion)
Dynamic stabilization
Anterior GH joint capsule due
to active pull of subscapularis
Post. GH jt. capsule due to
passive pull of infraspinatus
and teres minor
Motion limiting periarticular CT

Motion-limiting periarticular C.T. at
end range
Posterior GH joint capsule
Inferior GH ligament
(posterior band)
Coracohumeral ligament
(posterior portion)
Dynamic stabilization
Anterior GH joint capsule due
to active pull of subscapularis
Post. GH jt. capsule due to
passive pull of infraspinatus
and teres minor
GH External Rotation spin

Vertical axis
Horizontal plane
60-70⁰ ROM
Convex head rolls posteriorly and
slides anteriorly on concave glenoid
fossa
○ Note: spin occurs if ER motion
occurs in 90⁰ abducted position
Close-packed position of is full GH
external rotation with abduction
Motion-limiting periarticular C.T. at end
range
Anterior GH capsular ligaments
○ Superior GH, Middle GH,
Inferior GH (anterior band).
Dynamic stabilization
Anterior GH ligament due to passive
pull of subscapularis tendon
attachment to capsule
Posterior GH capsule due to active
pull of infraspinatus and teres minor
Motion limiting periarticular CT

Motion-limiting periarticular C.T. at end
range
Anterior GH capsular ligaments
○ Superior GH, Middle GH,
Inferior GH (anterior band).
Dynamic stabilization
Anterior GH ligament due to passive
pull of subscapularis tendon
attachment to capsule
Posterior GH capsule due to active
pull of infraspinatus and teres minor
 Part 2
SC, AC, ST, GH
Part 1:
○ Osteology
○ Arthrology
○ Kinematics
Part 2:
○ Overall Kinematics of Shoulder Abd.
○ Muscle and Joint Interaction
Overall Kinematics: Shoulder
Abduction
Principle 1
3,2,1 or 2:1 ratio
For every 3⁰
shoulder
abduction, 2⁰
occurs at GH
joint; 1⁰ at ST
joint’
120⁰ GH joint
60⁰ ST upward
rotation
Overall Kinematics: Shoulder
Abduction

Principle 2
60⁰ combined
ROM
○ 30⁰ SC joint
elevation
○ 30⁰ AC joint
upward
rotation
Overall Kinematics: Shoulder
Abduction
Principle 3 (Clavicular
retraction)
20⁰ retraction
posterior to the
frontal plane or 15⁰
in scaption

Retracting clavicle
assists AC joint with
optimal positioning
of the scapular
within the horizontal
plane (p. 145)
Overall Kinematics: Shoulder
Abduction

Principle 4 (Scapular
rotation adjustments)
Posterior tilt (sagittal
plane)
o Primarily AC
joint
External rotation
(horizontal plane)
o Net rotation at
SC and AC joints
Posterior Rotation of Clavicle

Principle 5
Clavicular elevation stopped by strong coracoclavicular ligament
As scapular upward rotators provide continued force, slack is
taken up in the conoid ligament portion of the coracoclavicular
ligament
Tension in conoid ligament pulls on conoid tubercle of clavicle,
posteriorly rotating clavicle
Overall Kinematics: Shoulder
Abduction

Principle 6 (GH joint
external rotation)
GH external rotation
25-50⁰ with the
majority occurring
before 70-80 degrees
of abduction
Allows greater
tubercle to pass
posterior to the
acromion
o Potential
impingement
Scapulohumeral Rhythm
Important components for smooth
motion for abduction:
1. Superior roll and compression of
humeral head
2. Scapula upward rotation
3. Humeral ER
Shoulder Abduction with Muscular
Interaction
happens simulateously, all happens during shoulder abduction

1. Upper and lower trap and serratus anterior
upwardly rotate scapula.
2. Supraspinatus superiorly rolls humerus and
compress it
3. Deltoid elevates humerus
4. Infraspinatus, subscapularis and teres minor
prevents excessive superior translation.
5. Infraspinatus and teres minor ER humerus
Muscle and Joint Interaction
need to have proximal stability in order to have distal mobility.

The function of the shoulder muscles

1. Proximal stabilizers: origin on the spine, ribs and cranium and
insert on clavicle or scapula
2. Distal mobilizers: origin on the scapula and clavicle and insert
on the humerus or forearm
 ST Elevators
Counter the force of gravity acting on the UE to maintain UE and
shoulder girdle posture

Upper trapezius
Levator scapulae
Rhomboids
ST Depressors
Lower trapezius
Latissimus dorsi (indirectly)
Pectoralis minor
Subclavius (indirectly)
ST Protractor
Serratus anterior
o Force transferred across GH joint
providing forward reach and push
Serratus Anterior Weakness
Serratus anterior gets stretched out and allows scapula to wing out
ST Retractors
Middle trapezius
Rhomboids
Lower trapezius

The elevation force of
the rhomboid is
cancelled by the
depressor force of the
lower trapezius.
ST Upward Rotators

Serratus anterior
Upper trapezius
Lower trapezius
ST Downward Rotators
Rhomboid major
and minor
Levator scapula
Pec minor

Force Couple
pg. 154
Muscles that Elevate the Arm at the GH
GH Abductors
Anterior deltoid
Middle deltoid
○ With supraspinatus
paralysis or tendon
rupture, full abduction is
difficult or impossible
because of altered GH
arthrokinematics
Supraspinatus
○ With deltoid paralysis, full
abduction usually
achieved
GH Flexors
Anterior deltoid
Coracobrachialis
Biceps brachii
ST Upward Rotators
evolute- when the axis moves along a path

A/P Axis location
changes for scapular
upward rotation
Early phase- near
the root (base) of
the scapula spine
Late phase- near
acromion

Serratus anterior
Upper trapezius
Lower trapezius
Middle trapezius
 Serratus Anterior

Most effective upward rotator
 Serratus Anterior Paralysis

Long thoracic nerve., spinal cord, or cervical
nerve root involvement
Winging scap- Ant tilt and IR
Subacromial impingement could occur
Upper Trapezius
pulls on spine, clavicle, and scapula
elevates clavicle, which in turn does
upward rotation of scapula
 Trapezius Paralysis

Moderate to marked difficulty elevating the arm
overhead
Lower Trapezius
 Middle Trapezius
o Since line of force is directed through the upward rotation
axis, it cannot rotate the scapula

o The middle trapezius is active as a stabilizing synergist
with serratus anterior.
o Note: Upward rotation of scapula occurs due to force
coupling of these muscles.
 Function of Rotator Cuff Muscles
During Arm Elevation

The Supraspinatus, Infraspinatus, Teres minor, and subscapularis-
rotator cuff muscles

1. Dynamic stability
2. Active control
Dynamic stability Provided by Rotator Cuff
for the Arthrokinematics at the GH Joint
 Example 1: GH External Rotation
Infraspinatus and teres minor
actively rotate humerus
externally
Increase active tension of
posterior GH capsule via
their capsular attachments
Additionally, passive
tension of anterior capsule
enhanced by passive
stretch of subscapularis

Note: Both provide centralizing force to humeral head therefore
stabilizes the joint.
 Example 2: GH Internal Rotation

Subscapularis rotate humerus
internally

1. Increase active tension of
anterior capsule via
capsular attachment

2. Additionally, passive
tension of posterior
capsule is increased by
passive stretch of teres
minor and Infraspinatus
Example 3: GH Abduction
Supraspinatus
Active Control Provided by Rotator Cuff
for the Arthrokinematics at the GH Joint

Abduction, External rotation, Internal rotation
Active Control by RC for
Abduction
Supraspinatus
facilitates superior roll
Subscapularis,
infraspinatus, teres
minor: inferior glide
of humeral head
Infraspinatus and
teres minor actively
externally rotate clear
greater tubercle from
acromion process
Active Control by RC for External
Rotation

Infraspinatus
and teres
minor assist
posterior roll
of humeral
head
Active Control by RC for Internal Rotation

Subscapularis
assists with
anterior roll
arthrokinematic
of convex
humeral head
Muscles that Adduct/Extend the
Shoulder
Posterior deltoid
Latissimus dorsi
Teres major
Triceps (long
head)
Pectoralis major
(sternocostal
head)
Infraspinatus
Teres minor
 Stabilization by Rhomboids

During resisted adduction, upward rotation and abduction forces are
countered by rhomboids.
Muscles that IR the Shoulder
They importantly
control high-velocity
external rotation
motions.

Subscapularis
Anterior deltoid
Pectoralis major
Latissimus dorsi
Teres major
 Muscles that ER the Shoulder

Function to eccentrically control internal rotation
Infraspinatus
Teres minor
Posterior deltoid
Supraspinatus
Glenoid Labrum Tears
Shoulder Instability