Unusual Compression Neuropathies of the Forearm, Part I: Radial Nerve
CURRENT CONCEPTS Unusual Compression Neuropathies of the Forearm, Part I: Radial Nerve Alan C. Dang, MD, Craig M. Rodner, MD Peripheral compression neuropathies are familiar to the hand surgeon. Although compression neuropathies of the forearm are far less common than those of the wrist (namely, carpal tunnel syndrome), for the patient suffering from one of these neuropathies, a missed diagnosis has far-reaching consequences. In this 2-part review (I: Radial Nerve; II: Median Nerve), several compression neuropathies of the forearm are examined. We will first discuss compression neuropathies affecting the radial nerve: (1) posterior interosseous nerve syndrome, (2) radial tunnel syndrome, and (3) superficial radial nerve compression (Wartenberg’s syndrome). (J Hand Surg 2009;34A:1906–1914. © 2009 Published by Elsevier Inc. on behalf of the American Society for Surgery of the Hand.) Key words Posterior interosseous nerve syndrome, radial tunnel syndrome, superficial radial nerve compression, Wartenberg’s syndrome. ATIENTS WITH PERIPHERAL compression neuropathies are ubiquitous in a hand surgeon’s practice. Carpal tunnel syndrome is the most common of these neuropathies, with an annual incidence between 0.1% and 0.35% in the general population, representing more than twice the incidence of the second most common peripheral compression neuropathy.1–3 Compression of the ulnar nerve, such as at the cubital tunnel or Guyon’s canal, is seen considerably less frequently, with an annual incidence of 0.03%.1 Rarer still are compressive neuropathies of the posterior interosseous nerve (PIN) and superficial radial nerve (SRN), with an annual incidence of 0.003%.1 The purpose of this 2-part review is to discuss several of the more unusual compressive neuropathies of the forearm, such as those of the radial nerve (Part I of this series), as well as those of P Current Concepts From the Department of Orthopaedic Surgery, University of Connecticut Health Center, Farmington, CT. Received for publication September 22, 2009; accepted in revised form October 17, 2009. No benefits in any form have been received or will be received related directly or indirectly to the subject of this article. Corresponding author: Craig M. Rodner, MD, Department of Orthopaedic Surgery, University of Connecticut Health Center, 263 Farmington Avenue, Farmington, CT 06034-4037; e-mail: [email protected]. 0363-5023/09/34A10-0027$36.00/0 doi:10.1016/j.jhsa.2009.10.016 1906 䉬 © Published by Elsevier, Inc. on behalf of the ASSH. the proximal median nerve, before its entry through the carpal tunnel (Part II of this series). The effects of compression on peripheral nerves can be attributed to alterations of blood circulation to and from the nerve as well as direct injury to the axonal transport systems. Venous blood flow from the peripheral nerves is shown to be reduced at 20 to 30 mm Hg, whereas frank ischemia can occur at pressures of 60 to 80 mm Hg.4 Blockade of axonal transport can occur at pressures as low as 50 mm Hg and loss of nerve impulse conduction occurs at pressures of 130 to 150 mm Hg.5,6 A compression neuropathy may begin as a mild injury to epineural vessels under mild pressure. The subsequent edema can lead to fibrosis, which increases further pressure on the nerve, leading to a progressive deterioration of the nerve.7 In addition to the mechanical effects, an increase in connective tissue has been hypothesized to cause secondary changes in the mechanical sensitivity of the thin afferent fibers responsible for pain.8,9 Finally, compression may also produce local intraneural sprouting and neuroma formation.10 Early on, compressive neuropathies can initially be treated through nonsurgical methods. These include rest, activity modification, nonsteroidal anti-inflammatory drugs, splinting, and corticosteroid injections. RADIAL NERVE COMPRESSION 1907 FIGURE 1: Schematic of the radial nerve as it bifurcates into the PIN, coursing under the supinator and the SRN, which runs along the undersurface of the brachioradialis. Current Concepts Splinting prevents the patient from moving the extrem(Fig. 1).11,12 The PIN is a motor nerve that courses ity into positions that result in additional compression to deep beneath the supinator muscle; the SRN is a the nerve, and therefore reduces inflammation that sensory nerve that travels anteriorly on the undercan lead to progressive worsening of symptoms. In surface of the brachioradialis and, in the distal instances when conservative management has one-third of the forearm, travels subcutaneously to failed, surgical decompression may be warranted provide sensation to the dorsoradial hand (Fig. 2). to eliminate the anatomical structures responsible Compression neuropathies involving the PIN and for compression. the SRN have been sepaThe radial nerve begins as EDUCATIONAL OBJECTIVES rately described. We will ● Describe the anatomy of the radial nerve in the arm and forearm the terminal branch of the discuss compression neuposterior cord of the brachial ● List the various potential compression sites of the radial nerve in the fore- ropathies involving the plexus. The nerve begins PIN and the SRN as 3 separm posterior to the axillary ar- ● Explain the differences between posterior interosseous nerve syndrome arate entities: PIN comtery and travels through the pression syndrome, radial and radial tunnel syndrome triangular interval and then ● State the surgical indications for posterior interosseous nerve syndrome tunnel syndrome (RTS), continues along the spiral and SRN compression and radial tunnel syndrome groove of the humerus. The (Wartenberg’s syndrome). Earn up to 2 hours of CME credit per JHS issue when you read the related nerve travels from the posterior compartment of the arm articles and take an online test. To pay the $20 fee and take this month’s test, COMPRESSION SYNDROMES OF THE into the anterior compart- visit http://www.assh.org/professionals/jhs. POSTERIOR ment as it penetrates the latINTEROSSEOUS NERVE eral intermuscular septum approximately 10 to 12 cm proximal to the elbow. The radial nerve continues to The PIN is thought of as a “motor-only” nerve that travel distally and ultimately bifurcates into deep (PIN) travels through the radial tunnel. The radial tunnel is a and superficial (SRN) branches approximately 6.0 to potential space 3 to 4 finger breadths long, lying along 10.5 cm distal to the lateral intermuscular septum and 3 the anterior aspect of the proximal radius through which to 4 cm proximal to the leading edge of the supinator the PIN travels. The floor of the radial tunnel is created by the capsule of the radiocapitellar joint, which continues as the deep head of the supinator muscle. Anatomically, there are 5 potential sites of compression of the PIN in the area of the radial tunnel: (1) fibrous bands of tissue anterior to the radiocapitellar joint between the FIGURE 2: Schematic of the SRN in the dorsoradial forearm. JHS 䉬 Vol A, December 1908 RADIAL NERVE COMPRESSION brachialis and brachioradialis; (2) the recurrent radial vessels that fan out across the PIN at the level of the radial neck as the so-called “leash of Henry”; (3) the leading (medial proximal) edge of the extensor carpi radialis brevis (ECRB); (4) the proximal edge of the superficial portion of the supinator, commonly referred to as the arcade of Fröhse; and (5) the distal edge of the supinator muscle. The proximal border of the superficial head of the supinator muscle, or arcade of Fröhse, lies approximately 1 cm distal to the leading edge of the ECRB and is thought to cause most PIN neuropathies. The lateral portion of the supinator is tendinous and originates on the lateral portion of the lateral epicondyle. These tendinous fibers course distally before joining the supinator’s medial fibers, which originate from the medial portion of the lateral epicondyle, and can be membranous or tendinous.13 In individuals with a tendinous arcade, the PIN experiences pressures of 46 mm Hg during passive pronation of the forearm and peak pressures of 190 mm Hg during maximal active muscle contraction.14 Interestingly, RTS and PIN syndrome describe compression of the same nerve and therefore can be approached with identical surgical interventions. Although in each syndrome the same nerve is affected, the clinical presentations are divergent. Whereas patients with PIN syndrome have a loss of motor function, patients with RTS typically present with mobile wad and lateral forearm pain without motor involvement. The difference in clinical presentation may well be attributed to a difference in the degree of compression of the nerve. Current Concepts Posterior Interosseous Nerve (PIN) syndrome The PIN is thought of as a “motor-only” nerve innervating the ECRB, supinator, extensor carpi ulnaris, extensor digitorum communis, extensor digiti minimi, abductor pollicis longus, extensor pollicis longus, extensor pollicis brevis, and extensor indicis proprius. It does not innervate the extensor carpi radialis longus (ECRL). PIN syndrome occurs when there is sufficient compression on the PIN—presumably of its large myelinated fibers—to produce a motor loss, which can result from benign tumors (most commonly lipomas or ganglia) or peri-elbow synovitis associated with rheumatoid arthritis.15 Although in 1863 Agnew16 described a compressive neuropathy of the PIN in a woman with a “hickory nut”–sized lesion that compressed both the PIN and the median nerve, the first report of an isolated PIN palsy was made by Guillain and Courtellemont in 1905.17 They wrote about an orchestral conductor whose palsy was attributed to the repetitive trauma of alternating forearm pronation and supination. As a result of this first description, occupations with repetitive pronosupination were considered to be a risk factor for injury to the PIN, although, owing to the relative infrequency of this condition, no data exist to confirm the magnitude of this risk. Nonetheless, subsequent reports of PIN syndrome have included a bartender,18 a violinist,19 a corsetiere,20 a dairyman,20 a swimmer,21 and even an infantryman after prolonged carrying of an M60 machine gun.22 Patients with PIN syndrome typically present with dropped fingers and thumb resulting from compression of the PIN at the proximal aspect of the supinator muscle.23 Even in situations where there is a complete PIN palsy, the function of the ECRL is always preserved, and thus the wrist is able to extend and radially deviate even in cases of severe neuropathy. Partial lesions are seen when there is compression not of the PIN in its entirety, but rather of isolated PIN branches. For example, compression of the medial branch would cause weakness of the extensor carpi ulnaris, extensor digiti minimi, and extensor digitorum communis, whereas compression of the lateral branch would cause weakness of the abductor pollicis longus, extensor pollicis brevis, extensor pollicis longus, and extensor indicis proprius.15 Imaging studies are not commonly used in the diagnosis of PIN syndrome, although magnetic resonance imaging may, of course, be helpful to delineate a soft tissue mass responsible for compression. Once a PIN palsy has been diagnosed, lipomas should be considered as a causative factor, because they are the most commonly reported tumor to cause PIN syndrome.24 –32 Other sources of compression that have been described include ganglia arising from the anterior capsule of the proximal radioulnar joint and in the supinator muscle,33– 40 rheumatoid pannus,41 septic arthritis of the elbow,42 synovial chondromatosis,43– 45 and vasculitis.46 One case report described the use of sonography to detect fibrous bands that compress the PIN,47 although this imaging modality is not commonly employed in the workup of PIN syndrome. Although clinical examination is the key in making the diagnosis of PIN syndrome, electrodiagnostic studies should be used for additional confirmation. Because loss of motor function is the hallmark of PIN syndrome, electromyographic evaluation is usually positive (in contrast to RTS). Other more proximal etiologies should be ruled out, including lesions of the cervical spine, brachial plexus, and radial nerve proper at the JHS 䉬 Vol A, December RADIAL NERVE COMPRESSION Radial Tunnel Syndrome (RTS) Although it is the same PIN that is being compressed in both RTS and PIN syndrome, patients with these 2 conditions present altogether differently. Rather than weakness or paralysis as their chief report, patients with RTS typically present with lateral proximal forearm pain, which must be distinguished from lateral epicondylitis. Typical reports include mobile wad area tenderness that worsens with activity. Although RTS was introduced as an entity unto itself in 1972, earlier descriptions of “resistant tennis below” refractory to conventional therapy had been described as early as 1883 and may be referring to the same entity.48 Today, the existence of RTS remains a source of controversy owing to limited objective tools that can be used to define its diagnosis, in that it is a pain-only phenomenon with no significant findings on imaging nor electrodiagnostic studies. The clinical diagnosis of RTS must be distinguished from that of lateral epicondylitis by the location of tenderness on physical examination. In lateral epicondylitis, the focal point of tenderness is on the lateral epicondyle at the insertion of the ECRB. In contrast, the characteristic pain of RTS is located 3 to 4 cm distal to the lateral epicondyle in the area of the mobile wad and radial tunnel.48 Compression of the PIN is made greater by placing maximal traction on the radial nerve, by extending the elbow, pronating the forearm, and flexing the wrist. Additional physical examination tests that have been described include pain with resisted active supination or wrist extension, pain with resisted middle finger extension at the metacarpophalangeal joint,48,49 and localized tenderness along the path of the PIN.50 The practitioner should remember, of course, that several of these clinical maneuvers would also provoke pain in the patient with lateral epicondylitis. Electrodiagnostic studies in the diagnosis of RTS have been described, although they are almost always unrevealing in the absence of a PIN syndrome. Forearm rotation can produce differential latencies in nerve conduction studies under laboratory conditions, but the vast majority of patients with RTS have normal electrodiagnostic testing.51,52 Because there is a paucity of objective tests to confirm the presence of RTS, pain relief after the administration of a local corticosteroid injection adjacent to the PIN at the level of the proximal radius has a useful role in diagnosis.53 Injecting the corticosteroid with a short-acting local anesthetic is wise, because temporarily producing a PIN palsy confirms accurate placement of the cortisone. Unlike PIN syndrome, imaging does not have a key role in the workup of RTS, although one study reported muscle edema and atrophy as characteristic magnetic resonance imaging findings in RTS.54 Management Nonsurgical management of both PIN syndrome and RTS is recommended initially and may include a trial of rest, activity modification, splinting, stretching, and antiinflammatory medications.55 In managing RTS, nonsurgical treatment is standard and the patient should make every attempt to eliminate frequent provocative positioning of the arm, which would include avoiding long periods of elbow extension, forearm pronation, and wrist flexion. Because no randomized controlled trials have been done to compare nonsurgical and surgical treatments, the optimal duration and efficacy of conservative regimens have not yet been determined.56 After activity modification is attempted, an injection of local anesthetic and corticosteroid is frequently used to confirm the diagnosis of RTS and may additionally serve a therapeutic purpose. In 1 study of 25 patients with RTS, 18 patients (72%) had resolution of their symptoms with a single injection of 2 mL 1% lidocaine and 40 mg of triamcinolone in 1 mL of carrier at 6 weeks of follow-up and 16 patients continued to have long-term pain relief at greater than 2 years.57 Injection may also have a role in the management of PIN syndrome, but if there is an underlying cause detected, such as a lipoma or ganglion occupying the radial tunnel and producing motor weakness, early surgical excision of the mass is more appropriate. If there is no cause identifiable on imaging studies, initial nonsurgical management of PIN syndrome is appropriate. If there is no improvement in the motor dysfunction by approximately 3 months, spontaneous recovery is not likely and surgery is recommended. In a 1996 study by Hashizume et al.,58 94% of patients (16 of 17) had a full recovery of motor function at a mean of 4.5 months JHS 䉬 Vol A, December Current Concepts level of the humeral shaft. Finally, it is important to consider peripheral neuropathy or mechanical limitations to finger extension in the differential diagnosis. Extensor tendon rupture or extensor digitorum communis tendon subluxation may mimic a PIN palsy clinically at first glance but can be ruled out with a more thorough physical examination. The characteristic feature of extensor tendon subluxation is the ability to maintain but not obtain metacarpophalangeal extension, whereas tendon rupture can be evaluated by passively bringing the wrist from a position of extension to flexion and determining whether there is an appropriate tenodesis effect. 1909 1910 RADIAL NERVE COMPRESSION Current Concepts after surgery. Vrieling et al. showed 75% good to excellent results after a mean of 5 years in a smaller study of 8 patients with nontraumatic PIN syndrome.59 What may account for the difference in success is that Hashizume et al.’s patients underwent surgery after 2.2 months after the onset of symptoms, whereas the Vrieling et al. patients underwent surgery an average of 4.7 months after the onset of symptoms. If PIN syndrome is neglected for approximately 18 months, muscle fibrosis of PIN-innervated muscles will occur, leaving only tendon transfers as a viable surgical option. Whereas patients with motor weakness or palsy (ie, those with PIN syndrome) might be diagnosed and surgically treated relatively early, those with RTS might not be diagnosed for many months. Once a patient is diagnosed with RTS, nonsurgical treatments should be attempted. If activity modification is not helpful and if multiple cortisone injections are only temporarily efficacious, surgical intervention should be considered. Because of a lack of high-level evidence, the optimal duration of such nonsurgical treatments is unknown. In a recent review of observational studies on various interventions for treating RTS, Huisstede et al.56 identified 6 articles9,48,49,60 – 62 of an eligible 21 over the past few decades that met their standards for methodological quality (although 5 used a retrospective study design). Together, those reports show a tendency for the efficacy of surgical decompression of the radial tunnel in patients with RTS, but say almost nothing about the natural history of untreated RTS or the effectiveness of conservative treatment. An evaluation of the literature reveals that no randomized controlled trials examine the precise role of surgical decompression versus conservative treatment in the management of patients with RTS.56 Of the 6 higher-quality RTS studies cited by Huisstede et al., the efficacy of surgical decompression of the radial tunnel ranged from 67%62 to 92%48 when the criteria put forth by Roles and Maudsley48 or Hagert et al.61 were used. Werner described an 81% success rate after 90 procedures9 and Lister et al. documented pain relief in 95% of their patients.49 However, not all data are so promising. Despite having 75% effectiveness using the above-mentioned criteria, patients in the De Smet et al. study60 only had a 40% patient satisfaction rate. Similarly, in a lower-quality study (using the Huisstede et al. methodological assessment), Atroshi and colleagues reported 41% patient satisfaction after surgical decompression in 37 patients at an average of 3.5 years of follow-up.63 When one reviews the RTS literature, it is important to recognize when a study does not exclude patients with concomitant lateral epicondylitis. Jalovaara and Lindholm, for example, published a large series of 111 procedures in 1989.64 However, their findings cannot be extrapolated to patients with a single diagnosis of RTS, because the authors did not clearly distinguish between the 2 entities. A more recent study examined the relationship between radial tunnel release and coexisting lateral epicondylitis.65 In that 2007 study by Lee et al., surgical decompression had good results in 86% of patients with a lone diagnosis of RTS, but was only 40% successful in patients with concomitant tennis elbow. Furthermore, surgery was only 57% successful in patients with multiple compression syndromes. Because RTS is a pain-only phenomenon without abundant objective criteria to aid in diagnosis, strict patient selection becomes essential to achieving reasonably good outcomes. Not surprisingly, patients who receive workers’ compensation or who are in litigation have been shown to have relatively poor outcomes after radial tunnel decompression.65,66 Lee et al. reported a success rate of 58% in patients receiving workers’ compensation (compared with 73% not receiving it).65 Similarly, Sotereanos et al. demonstrated a dramatically low 32% success rate after surgery in patients involved with workers’ compensation.66 Only 1 study showed no statistically significant difference between work-related and work-unrelated claims; however, it is unclear whether the study had adequate statistical power to determine such a difference, because it was comparing 14 patients with workers’ compensation and 9 patients who did not receive such benefits.67 The method of radial tunnel decompression in the treatment of both PIN syndrome and RTS may vary from surgeon to surgeon, but should share the common theme of releasing the 5 potential sites of PIN compression that we have outlined previously. The preferred method of the senior author (C.M.R.) was taught by his mentors Weiss and Akelman,68 and is performed through a longitudinal or 6-cm lazy-S-type incision that is centered over the mobile wad starting just distal (approximately 1 cm) to the radial aspect of the elbow flexion crease. The brachioradialis-ECRL interval is identified by a fascial stripe. Dissection is continued bluntly with a probing finger down to the fatty tissue surrounding the radial nerve. We use bipolar electrocautery to maintain meticulous hemostasis during the surgery to aid in visualization and avoid a postoperative hematoma. The SRN can be seen coursing along the undersurface of the brachioradialis and is protected throughout the surgery. The arcade of Fröhse and supinator muscle proper are identified, as is the PIN, which is dissected distally until it disappears, passing JHS 䉬 Vol A, December RADIAL NERVE COMPRESSION 1911 beneath the arcade of Fröhse. If traversing vessels compromise visualization, they may have to be bipolar electrocauterized or suture ligated, depending on their caliber. Once the PIN is identified as coursing deep to the supinator muscle, the surgery is performed by either excising the soft tissue mass encroaching upon it (as in PIN syndrome, for example) or freeing it up from all the potential sites of compression (as in RTS). The decompression should begin with the release of any proximal fascial bands connecting the brachialis to the brachioradialis, and then continue through the leash of Henry, the fibrous edge of the ECRB, and all the way through the radial tunnel with a complete release of the arcade of Fröhse and distal supinator muscle (Fig. 3). Current opinion suggests that release of the arcade of Fröhse may be the most important element in decompressing the radial tunnel.69,70 The wound is closed in layers and early active range of motion is allowed, although many surgeons favor a short course of a postoperative splint.15,68 Controversy Although RTS is classically described as a nerve compression and entrapment syndrome, there is dispute over its etiology. Skeptics note that the signs and symptoms of RTS contrast from other well-described entrapment neuropathies such as carpal tunnel syndrome and cubital tunnel syndrome in that there is: (1) prominent focal tenderness, (2) normal neurologic function, and (3) no confirmatory electrodiagnostic evidence of nerve dysfunction.71,72 Prominent focal tenderness in the area of the radial tunnel remains one of the principal diagnostic criteria for RTS. However, focal tenderness at the radial tunnel in RTS differs from a positive Phalen’s test in carpal tunnel syndrome in that the symptoms do not occur in the distribution of the purportedly affected nerve. Finally, although there are several reports supporting the efficacy of surgery in RTS, there has been no randomized controlled trial that compares surgical with nonsurgical treatment or with a placebo.56 Skeptics of RTS point to the great variability of surgical results reported in the literature as one of the characteristics of placebo surgery.72 Randomized controlled studies will certainly be needed to definitively settle this issue, but a review of basic science principles provides 1 hypothesis for RTS as a viable entrapment neuropathy. Although the PIN is classically thought of as being a “motor-only” nerve, the PIN also carries unmyelinated (group IV) afferent fibers from the wrist capsule as well as small myelinated (group IIA) afferent fibers from the muscles along its distribution.73 Unmyelinated group IV fibers from muscles (designated as C-fibers when of cutaneous origin) have long been associated with nociception and pain. Whereas many group IV fibers respond to noxious stimuli, others have been shown to be excited by relatively innocuous mechanical stimuli. Small myelinated group IIA afferent fibers have been associated with temperature sensation. Importantly, unmyelinated and small myelinated fibers are not assessed by nerve conduction studies. Under mild to moderate compression, it is possible that the unmyelinated and small myelinated fibers of the PIN are affected, thereby producing the painful clinical picture of RTS, whereas the large myelinated fibers of the PIN remain completely unfazed, accounting for a normal motor examination and nerve study. If the degree of compression is notable enough to cause damage to these larger myelinated fibers, as may be the case with a large soft tissue mass in the radial tunnel, the motor-palsy presentation of PIN syndrome might be seen. The absence of pain in PIN syndrome might be consistent with a complete dys- JHS 䉬 Vol A, December Current Concepts FIGURE 3: Intraoperative photographs of a left elbow A during and B after release of the arcade of Fröhse and supinator muscle. After release, the PIN is well visualized at the superior aspect of the photograph (with an hourglass-type compression deformity appreciated at the former location of the arcade of Fröhse) and the SRN is well visualized at the inferior aspect of the photograph, as it courses deep to the brachioradialis. 1912 RADIAL NERVE COMPRESSION function of the unmyelinated group IV and small myelinated group IIA fibers. Current Concepts COMPRESSION OF THE SUPERFICIAL RADIAL NERVE (SRN) The SRN is the superficial sensory branch of the radial nerve. After the radial nerve bifurcates into the SRN and PIN, the SRN courses distally into the forearm deep to the brachioradialis. Approximately 9 cm proximal to the radial styloid, the SRN becomes a subcutaneous structure by traveling between the brachioradialis and ECRL tendons (Fig. 2).74 The SRN continues to travel in the subcutaneous tissues and branches out into dorsal digital nerves responsible for afferent sensory input from the dorsum of the thumb, index, and middle fingers proximal to the proximal interphalangeal joints. In 1932, Wartenberg published a series of 5 adult patients describing an isolated neuropathy of the SRN.75 Given its clinical similarity to isolated neuropathy of the lateral femoral cutaneous nerve in the lower extremity (also known as meralgia paresthetica), Wartenberg coined the term “cheiralgia paresthetica” for this syndrome. Although compression neuropathy of the SRN had been described a decade earlier by other authors,76,77 Wartenberg syndrome and cheiralgia paresthetica have since become synonymous with a compression neuropathy of the SRN. The SRN can be compressed at any point along its course in the forearm, but it is believed to be at greatest risk at the posterior border of the brachioradialis as the nerve transitions from a deep to a subcutaneous structure. Trauma is also a common etiology for SRN compression, which can occur from direct pressure on the nerve (ie, by a wristband75–78 or handcuffs79 – 81) or from a stretch injury to the nerve (ie, during a closed reduction of a forearm fracture82). Patients with SRN compression typically report pain or dysesthesias on the dorsal radial forearm radiating to the thumb and index finger, although the distribution of symptoms may vary owing to differences in anatomy. When such sensory disturbances present concomitantly with weakness of the PIN-innervated muscles, the clinician should consider alternative diagnoses, such as a more proximal lesion (of the cervical spine, posterior cord of the brachial plexus, or radial nerve proper) or perhaps a mass in the radial tunnel large enough to affect both the PIN and SRN. Because irritation of the SRN often occurs in the region of the first dorsal compartment, SRN compression symptoms may be confused with the symptoms of de Quervain’s stenosing tenosynovitis owing to pain with ulnar deviation of the wrist. One principal difference between the 2 conditions is that patients with SRN tend to have symptoms at rest, independent of the position of the wrist and thumb. SRN compression and de Quervain’s tenosynovitis may in fact both be present simultaneously.83,84 A Tinel’s sign over the course of the SRN is the most common physical examination finding, although the clinician should be mindful that this may also be positive in patients with more proximal pain generators, such as a lateral antebrachial cutaneous neuritis. Although electrodiagnostic testing is often negative in cases of SRN, it is part of a thorough workup and may be helpful if positive. Management Patience is the cornerstone of therapy in patients with SRN compression symptomatology because spontaneous resolution is common. As external compression is a common underlying etiology, removal of the inciting element such as a wristwatch or bracelet is an essential component of nonsurgical management. In addition, rest, splinting, and nonsteroidal anti-inflammatory drugs are, of course, appropriate first-line treatments. The role of corticosteroid injection is less clear. Lanzetta and Foucher reported a 71% success rate in 29 patients who underwent conservative management alone, which was defined as removal of a tight watch strap, splinting, and, in 3 cases, a corticosteroid injection.83 Surgical decompression, which was offered only to patients who failed conservative therapy or whose symptoms were longstanding and had no distal progression of a Tinel’s sign, had a 74% success rate in 23 patients. Surgical decompression may also be indicated in posttraumatic situations in which scar tissue may be the critical compressive factor. As was the case with the PIN syndrome/RTS literature, there are no randomized controlled trials to our knowledge examining the efficacy of different types of conservative regimens (compared with one another or with surgical decompression) in the management of Wartenberg’s syndrome. Controversy Owing to the subcutaneous location of the SRN, a number of noninvasive therapeutic modalities centered around peripheral nerve stimulation (PNS) have been studied for the treatment of nerve pain, including pulsed low-intensity infrared laser, as well as direct electrical stimulation.85– 89 The use of PNS to treat neuropathic pain is based on the gate control theory of pain originally described by Melzack and Wall in 1965.90 The theory suggests that pain is not the result of simple on-and-off signals from nociceptive fibers, but is instead subject to neuromodulation, and may perhaps JHS 䉬 Vol A, December even be inhibited by simultaneous activation of tactile afferents mediating touch (which may explain why a child’s pain may be alleviated by a mother’s touch). Although this theory has found support in the medical literature and is certainly intriguing,91 there is mixed evidence supporting the use of PNS. Although some studies have shown no measurable effect from laser stimulation,86,87,89 others have shown alterations in the cortical evoked potential latency and amplitude, suggesting that stimulation of peripheral nerves suppresses nociceptive processing.85,88 Certainly, more clinical research is warranted to determine the precise role of PNS in the treatment of SRN compression and other subcutaneous peripheral neuropathies. Compression neuropathies of the radial nerve include PIN syndrome, RTS, and SRN compression. When the clinician encounters a patient with digital extension weakness or palsy, mobile wad pain, or numbness and tingling in the dorsoradial forearm and wrist, he or she must consider these diagnoses. Initial treatment is usually nonsurgical; however, surgical decompression has been shown to yield good results after failure of conservative management. 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