C Comparison of the shoulder girdle and pelvic girdle in their relation to the skeleton of the trunk

Superior view. Unlike the very mobile shoulder girdle, the pelvic girdle, consisting of the paired hip (coxal) bones, is firmly integrated into the axial skeleton. As the trunk assumes an upright position, the pelvis moves over the weight-bearing surface of the feet, making it necessary for the pelvis to support the total weight of the trunk. This basically limits the lower limbs to functions of locomotion and support while freeing the upper limbs from these tasks and making them a versatile organ of movement and expression that is particularly useful for touching and grasping.

A Position and shape of the right clavicle

a Clavicle in its normal relation to the scapula, superior view.

b Isolated clavicle, superior view.

c Isolated clavicle, inferior view.

The clavicle is an S-shaped bone, approximately 12 to 15 cm long in adults, that is visible and palpable beneath the skin along its entire length. The medial or sternal end of the clavicle bears a saddle-shaped articular surface, while the lateral or acromial end has a flatter, more vertical articular surface. The clavicle is the only bone in the limbs that is not preformed in cartilage during embryonic development; instead, it ossifies directly from connective tissue (membranous ossification). A congenital failure or abnormality in the development of this connective tissue results in an anomaly called cleidocranial dysostosis. There may be associated ossification defects in the cranial vault, which are also formed by membranous ossification (craniofacial dysostosis). Besides fractures due to obstetric trauma (1–2% of all newborns), fractures of the middle third of the clavicle are one of the most common fractures that are sustained by children and adults (in children, some 50% of all clavicular fractures occur before 6 years of age).

C The right scapula. Anterior view

D The right scapula. Posterior view

A The right humerus

a Anterior view, b posterior view.

A The right humerus

a Lateral view, b medial view.

A The radius and ulna of the right forearm

a Anterior view, b posterior view.

The radius and ulna are not shown in their normal relationship; they have been separated to demonstrate the articular surfaces of the proximal and distal radioulnar joints.

A The right upper limb

Lateral view. The forearm is supinated (the radius and ulna are parallel).

B Right forearm

Lateral view. The radius and ulna are shown in a disarticulated position to demonstrate the articular surfaces of the ulna for the proximal and distal radioulnar joints (see C).

A The bones of the right hand. Palmar view

The skeleton of the hand consists of

• the carpal bones,

• the metacarpal bones, and

• the phalanges.

The palm refers to the anterior (flexor) surface of the hand, the dorsum to the posterior (extensor) surface. The terms of anatomic orientation in the hand are palmar or volar (toward the anterior surface), dorsal (toward the posterior surface), ulnar (toward the ulna or small finger), and radial (toward the radius or thumb).

C Articular surfaces of the radiocarpal joint of the right hand

The proximal row of carpal bones is shown from the proximal view. The articular surfaces of the radius and ulna and the articular disk (ulnocarpal disk) are shown from the distal view.

Clinically, the radiocarpal joint is subdivided into a radial compartment and an ulnar compartment. This takes into account the presence of the interposed ulnocarpal disk, which creates a second, ulnar half of the radiocarpal joint in addition to the radial half. Accordingly, the radius articulates with the proximal row of carpal bones in the radial compartment, while the head of the ulna and ulnocarpal disk articulate with the proximal row of carpal bones in the ulnar compartment.

A Architecture of the metacarpus

The metacarpus is the key region for the architecture of the hand. It is where the five digital rays form and then develop into the thumb and fingers. While in neutral position, the longitudinal axis of each finger is parallel, and the longitudinal axis of the abducted thumb and the spread fingers converge to an intersection point in the capitate (a). However, when bending the finger joints, the axes converge to an intersection point in the scaphoid (b). Only the knowledge of these defined basic anatomic positions allows for the diagnosis of mal-alignments caused by injury (most notably rotational mal-alignments of the fingers, meaning “twisting” of phalanges as a result of a fracture (see inset). The five digital rays are connected by three functionally significant arches (c): a longitudinal arch along the third ray, a metacarpal arch, and a transverse carpal arch.

D Scaphoid fractures

a Scaphoid fracture as seen on X-ray, dorsopalmar view (from Matzen P. Praktische Orthopädie. 3rd ed. Stuttgart: J. A. Barth Verlag Thieme; 2002).

b Frequency and distribution of scaphoid fractures.

Carpal fractures, most notably scaphoid fractures (accounting for two thirds of all cases), are another injury caused by falling on the outstretched hand extended in the dorsal direction. Unlike distal radial fractures (see C), young people are predominantly affected by scaphoid fractures (typical sports injury). During physical examination, the symptoms can be relatively discrete. Usually the symptoms include tenderness on palpation of the area around the anatomic snuff box with simultaneous radial or ulnar abduction and compressive pain around the thumb and index finger. In the case of a suspected scaphoid fracture, conventional radiographs of the wrist in four different planes (so-called scaphoid quartet series) should be taken (see a, white arrow), in order to determine the direction of the fracture gap. If the X-ray image fails to confirm the suspected diagnosis 10 to 14 days after initially stabilizing the fracture, a follow-up X-ray must be taken (if needed using CT scans). At this point, the process of resorption in the fracture hematoma is usually completed so that the fracture gap is wider and thus more clearly visible. Depending on the location, scaphoid fractures are classified into fractures of the proximal third, central third, or distal third (see b). The healing process is especially lengthy in fractures of the proximal third (up to 3 months in an upper arm cast for stabilization with inclusion of the thumb basal joint, see c) because this part of the bone has few blood vessels (the scaphoid receives the majority of its blood supply via distal vessels). The healing process is just as lengthy in slanted or vertical fractures due to the resulting shearing forces pushing in opposite directions (see d).

Note: The scaphoid bone is involved in all movements of the hand, which makes long-term stabilization rather difficult. Thus, pseudo-osteoarthritis is a typical complication of scaphoid fracture (= false joint after failed fracture healing, see 42).

C The acromioclavicular joint and its ligaments

Right shoulder, anterior view. The acromioclavicular joint (the lateral clavicular joint) has the form of a plane joint. Because the articulating surfaces are flat, they must be held in place by strong ligaments (acromioclavicular, coracoacromial, and coracoclavicular ligaments). This greatly limits the mobility of the acromioclavicular joint. In some individuals the acromioclavicular joint has a variably shaped articular disk that gives the joint greater mobility.

A Ligaments of the sternoclavicular and acromioclavicular joints

Right side, superior view.

B Injuries to the acromioclavicular ligaments

These injuries often result from falling on a shoulder or an outstretched arm. According to Tossy, they can be classified into three types:

Rockwood added three more types that occur less frequently:

Depending on the extent of the injury, the so-called piano-key phenomenon can be triggered through palpation (caution: painful!). The lateral end of the clavicle, which is elevated due to the injury, can be reduced by applying pressure from the cranial direction, but it pops back up when pressure is released. Radiographs in different planes will show widening of the space in the acromioclavicular joint. Comparative-stress radiographs with the patient holding approximately 10-kg weights in each hand will reveal the extent of upward displacement of the lateral end of the clavicle on the affected side (is not performed in cases of visible partial rupture of ligaments in order to avoid further damage).