CHAPTER

ELBOW‌

 

●A TENDON TESTS

90

 

Tennis elbow test 90

Golfer’s elbow test 93

●B LIGAMENT/INSTABILITY TESTS

95

 

Valgus test 95

Varus test 97

Posterolateral pivot shift test 98

Chair push-up test 101

●C NEUROLOGICAL TESTS

103

 

Tinel’s test 103

Pressure provocation test 105

Ulnar nerve flexion test 107

Pinch grip test 109

 

89

 

 

 

 

●A TENDON TESTS‌

Tennis elbow test

Purpose

To test for a contractile lesion of the wrist extensor tendons most commonly involving the common extensor origin (CEO).

Technique

Patient position

Standing with the affected elbow fully extended and the forearm pronated.

Clinician position

Standing on the affected side, the clinician supports the patient’s arm by allowing it to rest on his or her own upper arm. Both the clinician’s arms are then extended and pronated so that the thumbs can be placed on the palmar aspect of the patient’s wrist to provide support and counter-pressure while the fingers are placed over the dorsum of the extended wrist.

 

 

 

Fig. 3.1 ● Tennis elbow test.

 

Action and positive test

The patient contracts the wrist extensors isometrically as strongly as possible against resistance. A positive test is indicated by reproduction of pain over the lateral aspect of the elbow.

Clinical context

Tennis elbow is the most commonly encountered lesion at the elbow. It affects 1–3% of the population with prevalence peaking between the ages of 40 and 50 years, particularly among men, who are twice as likely to present with the condition (Bulstrode et al 2002). The common view is that it is a self-limiting condition with natural resolution within a year, but in a substantial number of cases the condition persists and can cause pain and disability for much longer (Bulstrode et al 2002), a scenario commonly encountered in clinical practice. Such a chronic presentation is usually associated with degenerative tendinopathy resulting in a reduction in tensile strength and tendon extensibility. Patients often report more diffuse pain and tenderness, functional weakness and limitation of elbow extension, particularly on waking.

There are a multitude of other similar isometric resisted tests which are generally accepted among clinicians as being diagnostic for tennis elbow, with provocation of lateral elbow pain signifying a positive test. The basic provocative test can be sensitized by adding resistance to third finger extension which intensifies the action of extensor carpi radialis brevis (ECRB) or resisted radial deviation of the wrist with the elbow in full extension which also targets the tendons of extensor carpi radialis longus and brevis. Cozen’s test is a further variation where the affected elbow is fully extended while the clinician applies pressure over the CEO with a thumb. The patient pronates the forearm and makes a fist while the clinician provides resistance over the radial aspect of the patient’s hand so that isometric extension and radial deviation is resisted.

There is little evidence to support the use of any particular diagnostic test for tennis elbow, although provocation of lateral elbow pain on resisted wrist extension and tenderness over the lateral epicondyle were found to be the most commonly used indicators among a sample of Scottish physiotherapists (Greenfield & Webster 2002), and, given the predictable history and well-localized pain, the clinician can be reasonably confident that positive findings to the provocative tests point strongly to a contractile lesion of the common extensor tendon.

 

Clinical tip

Rarely, the condition may be complicated by compression of the posterior interosseous branch of the radial nerve, either as a primary lesion or secondary to a tendinopathy at the CEO. Distinctively, this may result in paraesthesiae in the forearm, tenderness over the course of the nerve in the forearm, as well as the more common findings of pain on resisted third finger extension and limitation to passive elbow extension (Roles & Maudsley 1972). Care should therefore be taken in the differential diagnosis of atypical or resistant cases as radial nerve compression has the capacity to mimic tennis elbow presentation (Stanley 2006).

 

EXPERT OPINION

COMMENTS



Tennis elbow test The most common site for the condition to present is at the teno-osseous junction where the CEO (composed of ECRB, extensor carpi ulnaris, extensor digitorum and extensor indicis) attaches to the small anterior facet of the lateral epicondyle. The other potential sites to exclude are the attachment of extensor carpi radialis longus on the lower third of the lateral supracondylar ridge, the body of the common extensor tendon (approximately 2 cm distal to the CEO) and the muscle belly lying deep to the brachioradialis muscle in the forearm.

CEO  common extensor origin ERCB  extensor carpi radialis brevis

 

Related tests

While the majority of tests aim to test the contractile unit by generating a contraction, the Mills’ test (Fig. 3.2) involves the application of a passive longitudinal stretch to the tendon. The patient sits with the shoulder slightly abducted, elbow flexed to 90°, forearm pronated and wrist flexed so that the palm of the hand is facing the ceiling. Standing behind the patient on the affected side, one hand cups the upper arm for support and takes the arm into about 70° of abduction. The thumb of the other hand is then placed in the patient’s palm between the index finger and thumb and the fingers wrapped around the dorsum of the wrist, which enables the forearm to be maintained in full pronation and the wrist in flexion. While maintaining this position, the elbow is extended slowly

 

(see Fig. 3.2A and Fig. 3.2B). A positive test is indicated by reproduction of the patient’s pain over the common extensors and, depending on the chronicity and severity, will occur in varying degrees of terminal extension. This test can also place considerable stress on the radial nerve and careful discrimination should therefore be exercised to exclude neural involvement. Stress on the nerve can be minimized by any or all of the following: reducing the degree of shoulder abduction, avoiding taking the shoulder into extension, allowing some elevation of the shoulder girdle, and placing the cervical spine in a degree of side-flexion towards the painful elbow.

 

 

A

B

 

 

Fig. 3.2 ● Mills’ test, start position (A) and end position (B).

 

 

 

Golfer’s elbow test

Purpose

To test for a contractile lesion of the wrist flexor tendons most commonly involving the common flexor origin (CFO).

Technique

Patient position

Sitting or standing with the elbow fully extended and the forearm pronated.

Clinician position

Standing adjacent to the patient’s affected side using the hand nearest the patient, the clinician fixes the lower forearm while supporting the patient’s upper arm over the crook of the elbow. The other hand is formed into a fist and placed in the palm of the patient’s flexed wrist.

 

Action and positive test

The patient contracts the wrist flexors isometrically as strongly as possible against resistance. A positive test is indicated by reproduction of pain over the medial aspect of the elbow.

 

 

Fig. 3.3 ● Golfer’s elbow test

 

Clinical context

The term medial epicondylitis implies that the process is purely inflammatory but golfer’s elbow is more accurately described as a degenerative tendinopathy involving the common flexor tendons at their attachment on the anterior aspect of the medial epicondyle of the humerus. The underlying pathology is similar in both tennis and golfer’s elbow where collagen formation becomes disordered with increased fibroblast and vascular content apparent (Atkins et al 2010). In tennis elbow, this process has been associated with tendon tears, although such significant breakdown of the tendon is uncommon at the CFO (Bulstrode et al 2002). The muscles most commonly contributing to unaccustomed or overuse loading of the CFO are pronator teres and flexor carpi radialis, with the others (palmaris longus, flexor carpi ulnaris and flexor digitorum superficialis) less commonly involved (Bulstrode et al 2002). Because of the close proximity of the ulnar nerve to the CFO, ulnar nerve symptoms may co-exist in some patients with golfer’s elbow (Bulstrode et al 2002) and the presence of paraesthesiae distal to the site of compression would require further evaluation (see Tinel’s test, p. 103, and the ulnar nerve flexion test, p. 107).

There is no evidence on the accuracy of this test although, given the very specific presentation of this condition, the clinician can be reasonably confident that a positive test is diagnostic.

 

Clinical tip

Once found to be positive, the clinician will then need to establish the exact site of the lesion by palpation in order to deliver effective treatment. The whole tendon is usually tender on palpation but the primary site is commonly located at the teno-osseous junction on the anterior facet of the medial epicondyle. The musculotendinous junction, located approximately a thumb’s width distally, is less frequently encountered.

Variations

The CFO can also be stressed by applying static resistance to pronation or resistance through the full range of wrist flexion. Passive supination of the forearm with full wrist extension provides a longitudinal stress to the tendon and may also elicit pain.

 

 

 

 

●B LIGAMENT/INSTABILITY TESTS

Valgus test

Aka

Jobe’s test

Purpose

To test the integrity of the medial collateral ligament (MCL) of the elbow.

Technique

Patient position

Standing with the elbow flexed to 20–30° and fully supinated.

Clinician position

Standing on the affected side, one hand stabilizes the humerus by holding it in external rotation above the lateral aspect of the elbow, while being able to palpate the joint line medially with the fingers. The other hand wraps around the medial aspect of the lower forearm.

Action and positive test

A valgus stress is applied to the elbow by abducting the forearm on the humerus. Tension in the ligament can often be felt as the stress is applied. Pain, excessive valgus movement or loss of the normal ligamentous end-feel indicate a positive test.

 

 

 

Fig. 3.4 ● Elbow valgus test.

 

Clinical context

Valgus instability can occur following an acute injury or as a result of chronic strain. Rupture of the MCL following trauma may be associated with injury to other medial structures such as the common flexor origin (CFO) and ulnar nerve. Repeated high-speed overhead activities associated with throwing sports can also result in microtrauma and chronic strain. If other medial structures are affected, the patient may complain of pain, weakness, neurological symptoms or flexion contracture secondary to posteromedial olecranon impingement (Lee & Rosenwasser 1999).

A study examining the range of valgus movement in cadavers where the MCL was compromised by a surgical incision found that complete release was required for between 4 and 10 mm of ulno-humeral joint gapping to be noted arthroscopically. The maximum opening was seen with the radio-ulnar joint positioned in pronation with between 60° and 75° of elbow flexion (Field & Altchek 1996), which suggests that in order to stress the ligament comprehensively the test should be repeated in this position (see variations). In a study of normal elbows, significant gapping was noted under radiographic examination when 25N of valgus stress was applied; this degree of ‘normal’ gapping may lead the clinician to falsely identify instability unless comparison with the opposite limb is made (Lee et al 1998).

Clinical tip

Because of the possibility of concurrent injury to the CFO and the ulnar nerve resulting from valgus injury or strain, further evaluation of these structures may be necessary (see golfer’s elbow test,

p. 93; ulnar nerve flexion test, p. 107; pressure provocation test,

p. 105; Tinel’s test, p. 103).

 

Variations

The ligament can be tested through range with the moving valgus stress test. The examiner applies a constant valgus stress to the fully flexed elbow which is then passively extended while maintaining the valgus stress. A positive test is indicated by medial elbow pain between 120° and 70° of elbow flexion.

 

TABLE 3.1 MOVING VALGUS STRESS TEST
Author and year	LR+	LR —	Target condition
O’ Driscoll et al 2005	4 ★	0 ★★★	Medial collateral ligament pathology

 

 

 

Varus test

Purpose

To test the integrity of the lateral collateral ligament of the elbow.

Technique

Patient position

Standing with the elbow flexed to 20–30° and fully supinated.

Clinician position

Standing in front of the patient, one hand stabilizes the humerus at the elbow by gently gripping above the medial aspect of the elbow while being able to palpate the radiohumeral joint line laterally. The other hand wraps around the lateral aspect of the lower forearm.

 

 

 

Fig. 3.5 ● Elbow varus test.

 

Action and positive test

A varus stress is applied to the elbow by adducting the forearm on the humerus. Tension in the ligament can often be felt as the stress is applied. Pain, excessive varus movement or loss of the normal ligamentous end-feel indicates a positive test.

Clinical context

The normal valgus carrying angle at the elbow means that varus instability in isolation is not commonly encountered and is more likely to be found in posterolateral rotatory instability (see posterolateral pivot shift test, p. 98; posterolateral rotatory drawer test, p. 100; chair push-up test, p. 101). This occurs as a result of lateral collateral ligament disruption which can be associated with acute elbow dislocation, chronic instability following trauma or excessive use of the arms for weight-bearing purposes (e.g. crutch use) (O’ Driscoll 2000).

 

 

 

Posterolateral pivot shift test

Aka

Lateral pivot shift apprehension test

Purpose

To test for posterolateral rotatory instability (PLRI) of the elbow and the integrity of the lateral collateral ligament (LCL).

Technique

Patient position

Lying supine with the forearm supinated, the shoulder is elevated to 180° and the elbow flexed to approximately 20°. The arm is thus above the head with the palm of the hand facing the floor and the olecranon pointing to the ceiling.

Clinician position

Standing at the affected side of the patient, one hand holds the outer aspect of the forearm just distal to the elbow while the other hand holds just above the wrist, wrapping the fingers around the palmar aspect and the thumb over the dorsal aspect.

Action

The forearm is maintained in full supination while an axial compression is applied through the radius and ulna towards the humerus, followed by a valgus stress to the forearm.

 

Positive test

If performed on a conscious patient, a positive test is indicated by pain and apprehension as, sensing that the elbow could dislocate, the patient is unlikely to relax sufficiently to allow completion of the test. The remaining component, therefore, can only be performed under anaesthesia. The elbow is taken into further flexion and at between 40° and 70° the radius and ulna sublux posterolaterally from the humerus, a movement often accompanied by a palpable click. This may produce both a visible prominence where the radial head subluxes and an associated skin dimple in the gap between the radial head and humerus. Reduction occurs as the elbow is flexed beyond 90° or returned to the start position of extension.

 

 

Fig. 3.6 ● Posterolateral pivot shift test, prior to further elbow flexion being added. The arrow indicates the direction of axial compression.

 

Clinical context

A history of elbow dislocation or other significant trauma will guide the clinician to consider the possibility of PLRI and should also be considered if the patient complains of symptoms of recurrent pain, catching, clicking or locking. The mechanism of injury is often a fall on an outstretched hand and the posterolateral pivot shift test reproduces similar but more controlled stress to the joint. At the moment of impact, axial compression drives the radius and ulna against the humerus with the elbow in a semi-flexed position. The forearm supinates on the fixed hand, and this, combined with a valgus stress, causes the ulna (and radius) to externally rotate away from the trochlea of the humerus. A spectrum of soft tissue injury occurs, starting with disruption of the ulnar portion of the LCL. This may cause only momentary subluxation but is sufficient to give rise to positive instability testing on examination. If the

 

bony displacement is more marked, frank dislocation occurs with concurrent injury to the other portions of the LCL and the elbow joint capsule. Finally the medial collateral ligament is injured. Associated fractures and injuries to the common extensor and flexor origins can also accompany the dislocation injury.

Where PLRI is present the symptoms occur most commonly when the elbow is extended with the forearm in supination. Recurrent frank re-dislocation is rare but the incidence of instability symptoms following simple elbow dislocation is reported to lie somewhere between 15% and 35% (Bulstrode et al 2002). PLRI can also occur as a consequence of connective tissue disorders causing laxity or as a result of chronic overuse (e.g. prolonged use of elbow crutches) (O’Driscoll 2000). Although not extensively evaluated, this test was shown to be more sensitive for PLRI than the posterolateral rotatory drawer test (see below) and the chair push-up test (see p. 101) (O’Driscoll 2000). In a small study of patients with known elbow instability, it was found to be 100% sensitive when performed under anaesthesia but this dropped to only 38% in the conscious patient (Regan & Lapner 2006).

 

Clinical tip

Further investigation including plain and stress X-rays, MRI, CT arthrography, examination under anaesthesia and arthroscopy are likely to be indicated if a diagnosis of PLRI is suspected (Bulstrode et al 2002).

 

EXPERT OPINION	COMMENTS
	The posterolateral rotatory apprehension test is a variation where the axial compression component is removed. A positive test is indicated by apprehension rather than visible or palpable subluxation and may serve as a useful starting point if PLRI is suspected.

Related test

The posterolateral rotatory drawer test (Fig. 3.7) can also be used to assess for PLRI of the elbow. The patient lies supine with the forearm supinated, the shoulder elevated and the elbow flexed to approximately 60°. The arm is therefore above the head with the palm of the hand facing the floor and the olecranon pointing towards the ceiling. Standing adjacent to the affected side, one hand

 

stabilizes the humerus just above the elbow joint. The other hand wraps around the proximal aspect of the radius and ulna from the radial side, so that the thumb lies on the posterior surface with the fingers lying anteriorly. Stabilization of the humerus is maintained while gliding the radius and ulna posteriorly from the humerus with some supination of the forearm. During the test the radius and ulna will rotate around an intact medial collateral ligament with excess movement, elbow pain, clicking and/or apprehension indicating a tear of the lateral collateral ligament and associated posterolateral rotatory instability. An additional finding may be the appearance of a dimple behind the radial head (O’Driscoll 2000). This test is comparable in action to the drawer test or Lachman’s test at the knee.

 

 

 

 

 

 

 

Chair push-up test

Aka

Stand-up test Chair sign

Fig. 3.7 ● Posterolateral rotatory drawer test.

 

Purpose

To test for posterolateral rotatory instability (PLRI) of the elbow and the integrity of the lateral collateral ligament.

Technique

Patient position

The patient sits on a chair with the hands resting on the sides of the seat or on the chair arms.

Action and positive test

The patient takes their weight through their arms and actively pushes up to assist the transition into a standing position. Reproduction of the pain, apprehension, clicking or locking are suggestive of lateral collateral ligament failure and PLRI instability.

 

 

 

Fig. 3.8 ● Chair push-up test.

 

Clinical context

Because PLRI diagnostic testing has not been thoroughly evaluated, using a variety of tests is more likely to direct the clinician to consider PLRI as a possible diagnosis (see posterolateral pivot shift test, p. 98; posterolateral rotatory drawer test, p. 100) (O’Driscoll 2000). The chair push-up test was evaluated in a small study of patients

 

undergoing surgery for recurrent dislocation and was found to be sensitive in 87.5% of patients but, due to the absence of true negative cases, specificity could not be calculated (Regan & Lapner 2006).

See posterolateral pivot shift test (p. 98) for further clinical context.

 

Clinical tip

The chair push-up test reproduces the functional movement most likely to reproduce PLRI symptoms, i.e. elbow extension and forearm supination. Anticipating the outcome, the patient is unlikely to be enthusiastic about this test and apprehension or an unwillingness to perform it are the most likely outcomes.

 

Variations

The active floor push-up test has the patient lying prone with their hands resting flat on the floor, approximately level with their head. The patient then attempts to do a push-up using their arms only. A positive test is indicated by apprehension, dislocation or guarding as end-range extension is reached. In a small study the sensitivity of this test for PLRI was reported to be 87.5% which rose to 100% when the results of this test and the chair push-up test were combined (Regan & Lapner 2006). This is obviously a test requiring significant upper body strength and will not, therefore, be suitable for all patients.

 

●C NEUROLOGICAL TESTS

Tinel’s test

 

 

Purpose

To test for compression neuropathy of the ulnar nerve at the elbow (cubital tunnel syndrome).

Technique

Patient position

The patient sits or stands.

Clinician position

The arm is taken away from the patient’s side to expose the medial aspect of the elbow to enable the clinician to identify and palpate

 

the ‘cord-like’ ulnar nerve just proximal to the cubital tunnel (see clinical tip), where it lies in a groove on the posterior aspect of the medial epicondyle.

Action and positive test

The area immediately proximal to the cubital tunnel is identified with palpation and then tapped using a reflex hammer a few times. A positive sign is indicated by paraesthesiae in the distribution of the ulnar nerve (little finger, ulnar half of the ring finger and the medial aspect of the hand).

 

 

 

Fig. 3.9 ● Tinel’s test.

 

 

Clinical context

The pathophysiology of compressive neuropathy is thought to have a bearing on the outcome of Tinel’s test, as a positive finding is usually only found in the presence of regenerating axons distal to the compression site. In the early stages of the condition, the compression has not been severe or prolonged enough to cause significant Wallerian degeneration and the test is therefore negative. In more advanced cases, Tinel’s may be negative because, after prolonged compression, there is no further axonal regeneration taking place. Tinel’s is therefore most useful in the middle stages of the condition, where some axonal recovery is underway (Kuschner et al 2006).

In a study of 200 asymptomatic individuals, the test triggered symptoms in 36% of the population (Kuschner et al 2006), confirming the propensity for false positives exposed in an earlier study (Rayan et al 1992). In a small population of patients with proven cubital tunnel syndrome, Tinel’s test demonstrated 70% sensitivity and 98% specificity (Novak et al 1994). Generally there is wide

 

agreement in the literature that clinical examination combined with the patient history is sufficiently sensitive and specific to diagnose cubital tunnel syndrome and may be more valuable than electrodiagnostics which, in the early stages of the condition or in mild cases, is not sufficiently sensitive or specific to detect a lesion (Dellon 1989, Greenwald et al 2006, McPherson & Meals 1992, Novak et al 1994).

 

 

TABLE 3.2 TINEL’S TEST
Author and year	LR+	LR—	Target condition
Novak et al 1994	35 ★★★	0.3 ★	Ulnar nerve entrapment

 

Clinical tip

The cubital tunnel is formed by the bony walls of the olecranon and the medial epicondyle of the humerus. The roof is formed by the overlying fascial bands of flexor carpi ulnaris and the medial ligament of the elbow. The ulnar nerve is vulnerable as it enters, traverses and exits the tunnel.

There is no standardized method of applying Tinel’s test but the technique described above produced relatively favourable results (Novak et al 1994) although the attendant problems of generating a false-positive with Tinel’s test should not be under estimated (Gerr & Letz 1998).

The ulnar nerve is also vulnerable to compression as it passes through the tunnel of Guyon at the wrist but at this point it has only a sensory function. More proximally at the elbow, compression may compromise motor function and assessment for weakness of the muscles supplied by the nerve distal to this point (i.e. medial side of flexor digitorum profundus, flexor carpi ulnaris, the hypothenar muscles and the third and fourth lumbricals) may help to make a distinction.

 

 

 

Pressure provocation test

Purpose

To test for compression neuropathy of the ulnar nerve at the elbow (cubital tunnel syndrome).

 

Technique

Patient position

Sitting with the elbow flexed to approximately 20° and the forearm supinated.

Clinician position

The clinician places an index finger over the ulnar nerve just proximal to the cubital tunnel (see clinical tip Tinel’s test, p. 103)

Action and positive test

The pressure is maintained over the ulnar nerve for 60 seconds. A positive test is indicated by an increase in pain, paraesthesiae or numbness in the distribution of the ulnar nerve over the little finger, ulnar half of the ring finger and medial aspect of the hand.

 

 

 

Fig. 3.10 ● Pressure provocation test.

 

Clinical context

Cubital tunnel syndrome is the second most frequent entrapment neuropathy in the upper limb. A comprehensive history and physical examination is generally considered more valuable in the diagnosis of the condition than electrodiagnostics, particularly in early or mild cases (Dellon 1989, Greenwald et al 2006, Kuschner et al 2006, McPherson & Meals 1992). When the elbow is fully flexed, the cubital

 

tunnel narrows by approximately 55% as the flexor carpi ulnaris aponeurosis and the arcuate ligament tighten, causing an increase in pressure on the ulnar nerve, and this corresponds to the position most likely to reproduce the patient’s symptoms (Kuschner et al 2006).

A controlled study compared responses to provocative tests for ulnar nerve entrapment in symptomatic and asymptomatic subjects. The pressure provocation test was maximally sensitive when maintained for 60 seconds but this dropped if the pressure was only applied for 30 seconds; specificity remained high regardless (Novak et al 1994).

 

TABLE 3.3 PRESSURE PROVOCATION TEST
Author and year	LR+	LR—	Target condition
Novak et al 1994	44.5 ★★★	0.1 ★★	Ulnar nerve entrapment

 

 

 

Ulnar nerve flexion test

Aka

Elbow flexion test

Purpose

To test for compression neuropathy of the ulnar nerve at the elbow (cubital tunnel syndrome).

Technique

Patient position

The patient sits with the elbow fully flexed with the forearm supinated and wrist in neutral for 1 minute.

Positive test

A positive test is indicated by symptoms of paraesthesiae or numbness in the little finger, ulnar half of the ring finger and medial aspect of the hand.

Clinical context

Cubital tunnel syndrome at the elbow may be caused by obvious extrinsic factors such as arthritis or a previous fracture or, more commonly, by the intrinsic factors associated with compression neuropathies. The patient may complain of pain, numbness and paraesthesiae in the ulnar nerve distribution of the hand. Weakness in the muscles innervated by the ulnar nerve (flexor carpi ulnaris and medial portion

 

 

 

 

 

Fig. 3.11 ● Ulnar nerve flexion test.

 

 

of flexor digitorum profundus, the hypothenar muscles and the third and fourth lumbricals) will only become apparent in long-standing or severe cases. Variations exist in both the test position and the length of hold recommended, although sustained full elbow flexion is universally included (Kuschner et al 2006). In a controlled study comparing responses in symptomatic and asymptomatic subjects, this test demonstrated a good degree of both sensitivity and specificity when the position was held for 1 minute (Novak et al 1994). The risk of a false positive result increased from a reported 3.6% of normal subjects when the position was held for 1 minute (Rosati et al 1998) to 20.5% if sustained for 3 minutes (Kuschner et al 2006), with paraesthesiae reproduced in the asymptomatic population –providing a good rationale for not maintaining the test position for longer than a minute. In subjects with proven electrophysiological evidence of cubital tunnel syndrome, the incidence of a positive test at 3 minutes increases to 86% (Buehler & Thayer 1988).

It is also possible to generate ulnar nerve paraesthesiae in an asymptomatic patient by adding neural sensitization (i.e. any of the following components: scapular retraction and depression, shoulder abduction, elbow flexion, forearm pronation and wrist extension) to

 

the test. In a study of normal subjects ulnar nerve paraesthesiae were reproduced in 10% of the sample with the wrist and shoulder held in a neutral position and this rose marginally to 13% with the addition of shoulder abduction and wrist extension (Rayan et al 1992).

 

TABLE 3.4 ULNAR NERVE FLEXION TEST
Author and year	LR+	LR—	Target condition
Novak et al 1994	75 ★★★	0.25 ★	Ulnar nerve entrapment

 

Variations

The combined pressure provocation and flexion test is a variation of the ulnar nerve flexion test. Full elbow flexion is maintained while the clinician applies pressure over the ulnar nerve just proximal to the cubital tunnel for 30 seconds. A positive test is indicated by reproduction of the patient’s symptoms in the distribution of the ulnar nerve.

 

TABLE 3.5 COMBINED PRESSURE PROVOCATION AND FLEXION TEST
Author and year	LR+	LR—	Target condition
Novak et al 1994	30 ★★★	0.09 ★★★	Ulnar nerve entrapment

 

 

 

Pinch grip test

Aka

‘OK’ sign

Purpose

To test for compression of the anterior interosseous branch of the median nerve.

Technique

Patient position

This is an active test performed by the patient who is asked to approximate the tips of the thumb and index finger together in a pinch grip position.

 

Action and positive test

The clinician checks to assess that the patient has flexed the distal interphalangeal (IP) joint of the index finger and IP joint of the thumb (Fig. 3.12A). A positive test is indicated by the patient being unable to approximate the tips of the thumb and index fingers and instead the pads of the digits are pinched together (Fig. 3.12B).

 

A

B

 

 

Fig. 3.12 ● A normal pinch grip test response (A). A positive test indicated by an inability to approximate the thumb and finger tips (B).

 

Clinical context

The anterior interosseous nerve branches posteriorly from the median nerve approximately 2–8 cm below the medial epicondyle, running between the two heads of pronator teres to supply pronator quadratus, flexor pollicis longus and the lateral part of flexor digitorum profundus.

The nerve does not provide sensory innervation so external pressure or compression caused by fascial bands within pronator teres or flexor digitorum superficialis (Standring 2005) results in weakness, a condition known as Kiloh–Nevin syndrome (Farber & Bryan 1968). External pressure more proximally on the main branch of

 

the median nerve (‘Saturday night palsy’) will also cause sensory symptoms, epitomized by significant paraesthesiae on waking.

 

 

 

References

Atkins, E., Kerr, E., Goodlad, J., 2010. A Practical Approach to Orthopaedic Medicine, third ed. Churchill Livingstone, Edinburgh.

Buehler, M.J., Thayer, D.T., 1988. The elbow flexion test: a clinical test for the cubital tunnel syndrome. Clin. Orthop. Relat. Res. 233, 213–216.

Bulstrode, C., Buckwalter, J., Carr, A., et al., 2002. Oxford Textbook of Orthopaedics and Trauma. Oxford University Press, Oxford.

Dellon, A.L., 1989. Review of treatment results for ulnar nerve entrapment at the elbow. J. Hand Surg. Am. 14 (4), 688–700.

Farber, J.S., Bryan, R.S., 1968. The anterior interosseous nerve syndrome. J. Bone Joint Surg. 50, 521–523.

Field, L.D., Altchek, D.W., 1996. Evaluation of the arthroscopic valgus instability test of the elbow. Am. J. Sports Med. 24 (2), 177–181.

Gerr, F., Letz, R., 1998. The sensitivity and specificity of tests for carpal tunnel syndrome vary with the comparison subjects. J. Hand Surg. Br. 23 (2), 151–155.

Greenfield, C., Webster, V., 2002. Chronic lateral epicondylitis: a survey of current practice in the outpatient departments in Scotland. Physiotherapy 88 (10), 578–594.

Greenwald, D., Blum, L., Adams, D., et al., 2006. Effective surgical treatment of cubital tunnel syndrome based on provocative clinical testing without electrodiagnostics. Plast. Reconstr. Surg. 117 (5), 87–91.

Kuschner, S.H., Ebramzadeh, E., Mitchell, S., 2006. Evaluation of elbow flexion and Tinel tests for cubital tunnel syndrome in asymptomatic individuals. Orthopaedics 29 (4), 305–308.

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