TENNIS ELBOW

Common Causes

Lateral elbow tendinopathy (LET) or lateral epicondylitis, also termed “tennis elbow” (TE), is a common sport syndrome that affects more than just tennis pros and the weekend tennis warrior. Tendinitis by definition implies that tendon injury is accompanied by an inflammatory response. Available histopathology studies that compare healthy tendons and those injured secondary to overuse show that injured tendons appear to be in a degenerative state with few or no inflammatory cells. Tendinosis more appropriately defines this process (Charnoff and Naqvi 2018). However, in TE, a tear may be the primary insult and the chronic degeneration a secondary process. For this reason, we prefer the term tendinopathy. Epidemiologic studies have estimated LET occurrence rates from 1 to 3 percent, with the highest incidence among male and female patients 40 to 49 years old, and the second highest incidence from 50 to 59 years old (Allander 1974, Verhaar 1994, Sanders et al. 2015). Historically, it has been stated that the rate of LET was greater than 2:1 (more common in females). More recent data show only a slight increase in rates among females (Sanders et al. 2015). Nirschl and Pettrone described the mechanism of injury at the origin of the extensor carpi radialis brevis, where overuse has resulted in microscopic rupture and subsequent tendinous nonrepair with immature reparative tissue (Nirschl and Pettrone 1979). These muscles originate at a common point at the lateral epicondyle of the elbow. While the overuse injury can occur from many activities, it is the backhand motion of the tennis swing that has the most direct impact on tennis players.

It is clear that certain risk factors come into play when one is investigating the cause of this injury. Epidemiologic studies find that the risk for developing the condition increases in those playing more than two hours per day and in individuals who are under 40 years of age (Gruchow and Pelletier 1979, Pluim et al. 2006). Poor swing mechanics seem to be a common culprit, particularly in one-handed backhands and novice players. Improper equipment also seems to play a role in causing the condition to occur with increased frequency. Often the tennis grip may be too small or too large; the proper grip size is 4-1/2 inches (11.4 cm) from the bottom of the lateral wrist crease to the tip of the ring finger (Adelsberg 1986). Equipment issues including wet, heavy balls, a racket strung too tight, a stiff racket head, a heavy racket, or even playing on faster surfaces like hard courts can increase the load on the extensor muscles and can add to the problem (Adelsberg 1986, Rossi et al. 2014, Giangarra et al. 1993). Finally, weekend warriors who are improperly conditioned are at most risk for injury, because the muscles are not strong and limber enough to account for the stress of infrequent competition.

Identification

A patient who develops LET will most often complain of pinpoint, knifelike pain over the lateral surface of the elbow. The pain usually occurs with wrist extensor and supination activity, such as that seen with a tennis backhand. A physical exam will often confirm the pinpoint tenderness and even swelling on the outside of the elbow. Pain is reproduced by forcibly resisting wrist or finger (especially the long finger) extension. These tests are called the Cozen test and the Maudsley test, respectively. Radiographic studies usually show no abnormality but might reveal a bone spur or calcium deposit outside the elbow joint. Sonographic detection of LET is similar to evaluation of other tendon injuries. Tendinosis appears as areas of hypoechogenicity and thickening of the tendon. It is also important to evaluate the tendon for a tear, which will typically appear hypoechoic or anechoic and is associated with tendon volume loss (Obuchowicz and Bonczar 2016).

If the athlete complains of pain radiating down the forearm, this pain must be distinguished from radial nerve entrapment, which can be mistaken for LET or occur conjointly with it.

Treatment

Treatment of LET is multifaceted and the injury is often very responsive to a conservative approach (Smidt et al. 2006). Over 90 percent of patients will respond to medical treatment. Given the high rate of improvement with medical management, surgery is contemplated only after 12 to 18 months of failed conservative treatment or if there is a frank, complete tear. The first step of treatment is relative rest in order to give the tendon the opportunity to repair itself. Many patients also use bracing in the early stages of recovery. The bracing options include a forearm counterforce brace, often called an elbow clasp or epicondylar brace, that can be coupled with a wrist extensor splint at a 20-degree angle. The clasp reduces stress on the lateral epicondyle by two mechanisms. Firstly, it decreases the expansion and contraction of the muscle via direct compression; secondly, it creates a new area of origin for the extensor tendons, taking the load off of the epicondyle. Data have been unclear as to which treatment is superior. One study showed no difference in total clinical outcome scores between the forearm counterforce strap and the extension wrist splint groups for the treatment of lateral elbow tendinosis at six weeks. However, the extension splint group had significantly better pain relief than the forearm strap brace group (Garg et al. 2010). Manual therapy and taping are also used on occasion.

Rehabilitation should focus on strengthening and coordination. Initially, full pain-free range of motion is achieved with stretching; then strengthening can occur. When strengthening, it is important to monitor pain levels. Exercises that focus on isometric movements may be tolerated better with a progression to concentric (muscle shortening) and eccentric (muscle lengthening) exercises. It is also important to incorporate proximal muscles that can stabilize the upper body and reduce the strain on the elbow. For example, strengthening the latissimus dorsi, muscles of the rotator cuff, and upper scapula stabilizing muscles will allow the athlete to have a more balanced upper body, support the weight of the racket better, and reduce the focused stress on the lateral elbow. As symptoms improve, focused wrist and forearm strengthening exercises with increasing load can be added. Lastly, sport (or task or job)-specific training is initiated to complete the program. Only when the athlete has pain-free range of motion at the elbow, has normal wrist extensor strength, and can apply this strength to a normal swing should the athlete return to competitive play.

If the athlete fails to improve with these conservative measures, other treatment options exist. Corticosteroid (CS) injections administered to the lateral elbow have been used historically, but recently have come under scrutiny. A recent placebo-controlled study comparing CS injection versus placebo injection found that CS injections do help relieve pain in the short term (less than four weeks), but it was noted that these results reversed at 26 weeks, with CS injection displaying worse outcome in regard to pain control and functional measures. At one year the patients who had the CS injection noted significantly worse pain scores and had a 2.4:1 rate of reinjury as compared to the control group (Coombes et al. 2013). These findings along with other clinical trials that show deleterious effects steroids have on intraarticular cartilage have changed the treatment paradigm (McAlindon et al. 2017). Corticosteroid is still a potential treatment option if short-term pain relief is the main goal of treatment, but the long-term risks must be discussed and considered prior to treatment.

Over the last decade, many new treatments have been developed and show promising results. One noninvasive treatment that has been shown to be beneficial in clinical trials is nitric oxide. This medication is delivered via a transdermal patch. It is theorized to work in tendinosis by regulating local blood flow and host defense (Kahlenberg, Knesek, and Terry 2015). It is also believed to have a positive effect on collagen synthesis (Xia et al. 2006). In randomized clinical trials it has shown a significant reduction in both pain and tenderness at three months after treatment, as well as increased wrist extensor force at six months after treatment (Paoloni et al. 2009, McCallum, Paoloni, and Murrell 2011, Paoloni et al. 2003). That being said, longitudinal studies have failed to reveal any significant difference at five years when compared to a standard tendon rehabilitation program (McCallum, Paoloni, and Murrell 2011, Kahlenberg, Knesek, and Terry 2015).

Another noninvasive treatment that has recently gained popularity is extracorporeal shockwave therapy (ESWT). The idea behind shockwave therapy is to use sound waves to induce microtrauma to pathologic tissue. This microtrauma initiates a new healing response that ultimately leads to new collagen formation and a healthier tendon. A recent systematic review that looked at over 100 randomized clinical trials (RCTs) found ESWT both safe and significantly effective when compared to placebo or other treatments for tendinosis in more than 80 percent of RCTs (Schmitz et al. 2015). Current recommendations are that ESWT be done weekly for a total of three sessions with 2,000 impulses per session and with no local anesthetic.

Orthobiologic treatments have garnered significant attention in recent years due to their potential benefits. Platelet-rich plasma (PRP) has generated some of its most compelling data in treating LET. Studies ranging from case series, RCTs, and meta-analysis have shown PRP to be superior to CS injection for TE, particularly at one- and two-year follow-ups (Ahmad et al. 2013, Arirachakaran et al. 2016, Gosens et al. 2011). There are other studies that have shown no difference in outcomes between PRP and CS. Protocols have been called into question regarding standardization of preparation and administration, including platelet count injected and the optimal number of injections over what period of time. Initially it was thought that three injections were required, but now research has shown that one injection generates comparable results (Glanzmann and Audige 2015). The variation in protocols is a large reason why there are such differences in results seen in some studies.

Other minimally invasive treatments considered “experimental” by many clinicians include botulinum toxin A (Botox) injections and prolotherapy. The proposed mechanism of prolotherapy injections is that an injected irritant (hypertonic dextrose, phenol-glycerine-glucose, or sodium morrhuate) either causes a cell rupture through osmosis or attracts inflammatory mediators, thus improving blood supply to the diseased tendon. Data including those from one RCT showed positive short-term decrease in pain up to 16 weeks; however, there does not appear to be supportive evidence for long-term benefits (Scarpone et al. 2008). Botox is not a commonly used treatment of LET, even though there are some promising data that show significant pain decreases at 4, 8, and 12 weeks (Placzek et al. 2007). The theorized mechanism is that the paralysis Botox causes of extensor carpi radialis brevis (ECRB) and extensor carpi radialis longus (ECRL) prevents further microtrauma to the origin and allows the pathologic tissue to heal (Kahlenberg, Knesek, and Terry 2015, Lin et al. 2010, Placzek et al. 2007). A more recent study has shown significantly improved pain scores in patients treated with CS versus Botox in short-term follow-up. The current data regarding this treatment are not clear, so we suggest using the treatment with caution. It is also important to keep in mind that the inherent extensor weakness that results secondary to treatment must be considered prior to administering to athletes who require this type of strength in their sport.

When all conservative treatments fail to improve the condition, surgery is considered. A less invasive form of tendon debridement has been gaining popularity and shows promise as a treatment for recalcitrant LET. This procedure is called percutaneous ultrasonic tenotomy (PUT). The procedure can be completed in an outpatient setting. After superficial and deep local anesthetic is injected, a small incision is made and a probe is placed over the diseased tissue. Ultrasound is used to guide the procedure. Percutaneous ultrasonic tenotomy uses technology based on the principles of phacoemulsification used in cataract surgery (Paul and Braga-Mele 2005, Kelman 1994). An ultrasonic vibrating tip is directed at the pathological tissue seen in tendinopathy. The tissue becomes emulsified and requires debridement, which is done by the device (Koh et al. 2013, Peck, Jelsing, and Onishi 2016). It is theorized that the pain evoked by the necrotic tendon is mediated by cytokines, which resolves upon removal of the pathologic tissue. In addition, it is hypothesized that the space created by the ultrasonic tenotomy allows a more normal environment leading to a rapid healing response (Barnes, Beckley, and Smith 2015). To date, all of the studies are case series. They show immediate and prolonged patient satisfaction as well as sonographic improvement for up to three years (Seng et al. 2016, Barnes, Beckley, and Smith 2015, Elattrache and Morrey 2013, Patel 2015).

Other surgical procedures include either open or arthroscopic, depending on the underlying condition and the experience of the surgeon. Surgeons can remove a portion of the damaged tendon or release the attachment of the affected tendon. A repair of the healthy portion of tendon is sometimes carried out as well. Postoperatively, the patient usually is placed in a 90-degree brace. Early motion in a brace may be initiated at three to five days, with strengthening exercises usually starting by three weeks postoperatively. Return to tennis and racket sports can be expected by four to six months. Depending on the specific job requirements, patients can return to work in 6 to 12 weeks, although job modification or persistent use of a counterforce brace during work activities may be necessary. Approximately 85 percent of patients who fail conservative treatment and undergo the surgery ultimately report some degree of pain relief.

Return to Action

The criteria for return to play after treatment for lateral epicondylitis elbow injury are similar to those for other musculoskeletal injuries. The goal of treatment and benchmarks for clearance include the restoration of normal strength, endurance, and flexibility. Returning too early puts the athlete at risk of reinjury and the inability to perform at a satisfactory level. Lateral elbow tendinopathy reinjury does not usually result in fracture or severe disability; therefore, some flexibility may be granted for the recreational athlete. Thus, some athletes may gradually return to sport with less than normal physical capacity. For full competitive play, grip and wrist extensor strength in the dominant arm should exceed that in the nondominant by approximately 10 percent. Accelerating the return would include steps to change swing technique, training habits, and equipment and obtaining an elbow counterforce brace. Ultimately, 95 percent of those who receive treatment for LET should achieve excellent functional recovery with conservative treatment.