Shoulder anatomy (scapula, humerus, collar bone) myvmc b games car

The shoulder girdle is mainly made up of the true shoulder joint (glenohumeral joint) and the joint between the shoulder blade and the chest (scapulothoracic joint). When we move our arm around, movement occurs at both of these joints, with most (two thirds) occurring at the shoulder joint. The shoulder is basically like a ball and socket. The “ball” is the head of the humerus and the “socket” is theglenoid part of the shoulder blade (scapula).The anatomy of the shoulder is unique – it has a relatively shallow socket which results in amazing flexibility and range of motion to the shoulder joint which is unparalleled elsewhere in the body. In order to achieve this flexibility but maintain a stable shoulder, there is a complex interplay between the joints, muscles and ligaments. Injury to any one of these structures can therefore result in significant ongoing pain, weakness, or instability.

• A tuberosity is a distinct prominence or bump on a bone which is usually where a muscle or a ligament attaches. There are two of these on the humerus, the greater tuberosity and the lesser tuberosity. The greater tuberosity is the site of insertion for three important shoulder ( rotator cuff) muscles; the supraspinatus, infraspinatus and teres minor. The lesser tuberosity is the site of subscapularis insertion which is another shoulder muscle.

The scapula (commonly known as the shoulder blade) is a triangular shaped bone which has a part called the glenoid that forms the “socket” for the head of the humerus. The glenoid cavity is not even half the size of the humeral head so it does not provide the joint with much stability. However, the glenoid socket is made deeper by a rim of “gristle” (fibrocartilage) called the labrum that runs around the periphery of the socket, effectively doubling its depth. When somebody dislocates their shoulder for the first time, they usually rip off this gristle, which then makes their socket shallower and predisposes them to repeat shoulder dislocations. The ball and socket of the shoulder are enclosed by a “sock” of tissue, known as the joint capsule. If this sock of tissue becomes stiff, it can result in shoulder stiffness and pain known as frozen shoulder (adhesive capsulitis).

The shoulder blades sit on the upper part of the back (thorax), with one on each side. Projecting from the front of the shoulder blade is a hook of bone known as the coracoid process. The coracoid process is a bone which serves as the connection point for the ligaments that connect the shoulder blade to the collarbone. Another large hook or shelf of bone projects upwards from the shoulder blade and is known as the acromion. The acromion serves as an attachment for the strong and important deltoid muscle.

The acromioclavicular joint (AC joint) is at the tip of the shoulder and is the site where the collarbone connects to the shoulder blade. The collarbone serves to strut the shoulder blade out from the body, allowing the surrounding muscles to work at their most effective tensions and generate more power. The AC joint commonly wears out as we get older resulting in arthritis, which may or may not be painful.

The glenoid labrum is a rim of gristle (fibrocartilage) attached to the periphery of the glenoid cavity and acts to deepen the socket and increase the contact surface area between the ball and socket, increasing the stability of the shoulder joint.

The shoulder requires a large number of bursae. Bursae are fluid filled sacs that roll over themselves and serve to lubricate the points of possible friction between the muscles and the joint capsule. The major bursae in the shoulder include the subacromial bursa, the subdeltoid bursa and the subscapular bursa.The subacromial bursa can commonly become inflamed and cause pain ( bursitis). It is a common site for injections of cortisone to help decrease the pain in the shoulder.

There are three glenohumeral ligaments which provide some support to the front of the shoulder joint; the superior, middle and inferior glenohumeral ligaments. The superior glenohumeral ligament works in conjunction with the coracohumeral ligament to stabilise the humeral head. The middle glenohumeral ligament is not always present. When it is present, it aids to stabilise the humeral head. The thick inferior ligament is the primary stabiliser of the three.

The shoulder joint has very large powerful muscles which provide the power for strong movements (deltoid, pec major), and smaller muscles (rotator cuff) which help with stability of the glenohumeral joint. If a very powerful muscle like the deltoid contracts on its own, the humeral head would partially slip out of place (sublux) due to the shallowness of the socket. This is prevented by the rotator cuff muscles which co-contract with the deltoid, compressing the humeral head into the glenoid and providing the dynamic stability required for strong shoulder movements.The muscles which comprise the rotator cuff and their individual motions are:

• The pectoralis major muscle is another powerful muscle which like the deltoid is integral to shoulder function. We use this muscle when doing push-ups. It originates from the front of the chest and collar bone and inserts on the upper part of the arm bone (humerus).

• The serratus anterior muscle helps to stabilise the shoulder blade on the chest wall. When it is not functioning, “winging” occurs which is when the shoulder blade protrudes from the back. This muscle inserts into the shoulder blade and originates from the first 9 ribs.

Shoulder injuries are common accounting for up to 20% of all athletic injuries. As mentioned previously, the unique structure of the shoulder joints results in a multiaxial universal joint with an unparalleled range of motion. However, this unique structure also means that the shoulder joint is the most frequently dislocated joint in the body. In addition to shoulder dislocations, other common injuries include rotator cuff tendon tears and broken bones including the humerus and collar bone.