0:00

Let's take a look at stable Hill-Sachs defects.

0:06

I mean, this is a deep hatchet job, if you will.

0:10

But yet, no matter whether you're in the mid-range,

0:14

where the capsule is lax, or you're in the end range

0:18

with the arm in abduction and external rotation,

0:21

there is always contact between the surface of

0:25

the humerus and the glenoid articular surface.

0:29

Even though there's laxity here, which is very common,

0:33

and in fact there's usually some anterior translation

0:38

of the humerus when you're in the mid-range position.

0:42

In other words, when you're not fully

0:43

abducted and externally rotated.

0:47

Now in some athletes, the amount of translation that you

0:50

might see here would be greater than the average person.

0:54

In fact, some people in the mid-range, even without a

0:59

Hill-Sachs, And without a glenoid lesion, may be able

1:03

to sublux and even dislocate the shoulder spontaneously.

1:09

Further contributing to the failure of dislocation,

1:15

or helping to support the shoulder, is the

1:18

concavity, as we've said before, of the glenoid cup.

1:22

So you're much more likely to spontaneously

1:24

dislocate with anterior laxity, with or without

1:27

a Hill-Sachs, if the cup is completely flat.

1:31

And that's why you must pay attention to this conformity

1:36

and the fit between the humeral head and the glenoid

1:39

cup, even though the humeral head is a heck of a lot

1:42

bigger, and that's why this joint is prone to dislocation.

1:48

Now the glenoid socket is twice as deep in the

1:51

cranial caudate, or superior to inferior direction,

1:55

as it is in the anterior to posterior direction.

2:00

As a result, the force necessary to translate

2:03

the humeral head under constant compressive

2:06

force is twice as large in the supero inferior

2:10

direction than it is in the AP direction.

2:13

And that's why AP dislocations dominate

2:17

more over direct inferior dislocations.

2:21

The anteroinferior capsule and inferior dislocations,

2:25

as you would expect, are at high risk, and this is

2:28

what may generate your haggle, your bagel, your raggle,

2:31

and your gaggle.

2:33

So, this is an example of mid-range shoulder positioning

2:38

with capsular laxity and end-range abduction external

2:42

rotation with the anterior capsule taut that get this

2:47

patient translating a little bit but not dislocating

2:50

even in the face of a good size Hill-Sachs laxative.

On-Track/Off-Track: Stable Hill-Sachs Lesions

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0:00

Let's take a look at stable Hill-Sachs defects.

0:06

I mean, this is a deep hatchet job, if you will.

0:10

But yet, no matter whether you're in the mid-range,

0:14

where the capsule is lax, or you're in the end range

0:18

with the arm in abduction and external rotation,

0:21

there is always contact between the surface of

0:25

the humerus and the glenoid articular surface.

0:29

Even though there's laxity here, which is very common,

0:33

and in fact there's usually some anterior translation

0:38

of the humerus when you're in the mid-range position.

0:42

In other words, when you're not fully

0:43

abducted and externally rotated.

0:47

Now in some athletes, the amount of translation that you

0:50

might see here would be greater than the average person.

0:54

In fact, some people in the mid-range, even without a

0:59

Hill-Sachs, And without a glenoid lesion, may be able

1:03

to sublux and even dislocate the shoulder spontaneously.

1:09

Further contributing to the failure of dislocation,

1:15

or helping to support the shoulder, is the

1:18

concavity, as we've said before, of the glenoid cup.

1:22

So you're much more likely to spontaneously

1:24

dislocate with anterior laxity, with or without

1:27

a Hill-Sachs, if the cup is completely flat.

1:31

And that's why you must pay attention to this conformity

1:36

and the fit between the humeral head and the glenoid

1:39

cup, even though the humeral head is a heck of a lot

1:42

bigger, and that's why this joint is prone to dislocation.

1:48

Now the glenoid socket is twice as deep in the

1:51

cranial caudate, or superior to inferior direction,

1:55

as it is in the anterior to posterior direction.

2:00

As a result, the force necessary to translate

2:03

the humeral head under constant compressive

2:06

force is twice as large in the supero inferior

2:10

direction than it is in the AP direction.

2:13

And that's why AP dislocations dominate

2:17

more over direct inferior dislocations.

2:21

The anteroinferior capsule and inferior dislocations,

2:25

as you would expect, are at high risk, and this is

2:28

what may generate your haggle, your bagel, your raggle,

2:31

and your gaggle.

2:33

So, this is an example of mid-range shoulder positioning

2:38

with capsular laxity and end-range abduction external

2:42

rotation with the anterior capsule taut that get this

2:47

patient translating a little bit but not dislocating

2:50

even in the face of a good size Hill-Sachs laxative.

Report

Description

Faculty

Stephen J Pomeranz, MD

Chief Medical Officer, ProScan Imaging. Founder, MRI Online

ProScan Imaging

Lesson

MRI Mastery Series: Shoulder - Pre-course Activities

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Sample Lesson - 53 Year Old Female, Injured While Playing Softball

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Shoulder MRI: Assessing Instability - Anatomy

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Shoulder MRI: Assessing Instability - Protocols

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Shoulder MRI: Assessing Instability - Pathology

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Shoulder MRI: Assessing Instability - Case Review

Lesson

Shoulder "Shark" Week -- Review of Rotator Cuff Anatomy

Lesson

The Six Components of the Rotator Cuff

Lesson

Identifying The Six Components of Rotator Cuff Tears in Practice

On-Track/Off-Track: Stable Hill-Sachs Lesions