Tennis elbow, also known as “lateral epicondylitis,” often affects active adults between the ages of 30 and 60 years, and causes pain on the outside of the elbow joint where the forearm meets the elbow. Internally, tennis elbow pain is localized where the muscles of the forearm merge into tendons and attach to end of the upper arm bone. A patient with tennis elbow will typically feel pain upon extending (unbending) the wrist (think of the wrist motion required to rev a motorcycle). As an aid to evaluation, a therapist can reproduce the pain by resisting the patient’s wrist motion. Sometimes tennis elbow can be so painful that the patient cannot raise his or her hand, even when no resistance is applied.

Although the condition is known by two names, neither is very accurate. You don’t have to play tennis to get tennis elbow! In addition to the high tensile stresses of the backhand tennis stroke, any other activity involving a firm grip, such as using a hammer or screwdriver, or heavy lifting, such as lifting suitcases away from the body with the palm facing the ground, can cause tennis elbow. And the “-itis” suffix of the name “lateral epicondylitis” signifies that the condition is characterized by inflammation, which is not the case. Factors normally associated with inflammation, such as certain white blood cells, cytokines, and chemokines, are not found at the site of the lateral epicondyle of the elbow. What surgeons do find, however, upon opening and examining an affected elbow, is disorganized connective tissue in the form of a characteristic yellow-brown scar. By contrast, healthy tendon tissue is glistening white and is composed of cells organized in neat rows along the axis of tension between the muscles of the forearm and the lateral epicondyle of the elbow.

Palliative measures for tennis elbow include rest and anti-inflammatory medication. Tennis elbow patients are also sometimes instructed to use a tight band around the upper forearm to help rest the painful area and protect it from damaging tensile loads. Although these measures are effective at reducing pain while they are used, they rarely result in full recovery, because they do not restore proper connective tissue alignment.

Fortunately, there are more effective measures. Twenty years ago, exercise physiologists discovered that eccentric exercise is a necessary component of rehabilitation from tendinitis. Eccentric exercise occurs when a muscle generates tension as it is lengthening. For instance, when you place a coffee cup down on a table, you are performing eccentric exercise: your biceps muscles must lengthen in a controlled manner to lower your forearm and place the cup down gently. You may think of eccentric exercise as the braking force needed to slow down the motion. The opposite of eccentric exercise is concentric exercise, which involves active muscle shortening.

Although the exact way in which eccentric exercise improves tendinitis is not known, researchers have discovered that muscle elasticity is a key feature of eccentric muscle contraction, and that eccentric exercise increases muscle elasticity. The leading hypothesis is that muscle tissues that have been made elastic by eccentric exercise effectively distribute and absorb forces that would otherwise lead to fraying of the tendon, formation of disorganized scar tissue, and tennis elbow pain.

At Physical Therapy of Los Gatos, treatment for tennis elbow begins with a thorough evaluation of the problem and a discussion of the patient’s rehabilitation goals. Movements associated with the activities that cause tennis elbow pain must be identified and analyzed. If the patient began having tennis elbow pain after playing tennis on rainy days, perhaps he or she needs only a short course of treatment and to stop hitting wet, heavy tennis balls. In other cases, we may find that improper use or involvement of the neck, shoulder, or wrist during sports or other activities has caused excessive loading of the elbow. In these cases, therapy includes instruction and retraining to balance the physical forces required for the chosen activity correctly.

However, regardless of the other required elements of effective treatment, rehabilitation of tennis elbow will include progressive, eccentric muscle training. Eccentric muscle rehabilitation involves using wrist motion to lower a weight over the edge of a table while the forearm is supported. The patient uses his or her forearm muscles to raise the weight and then lower the weight in a controlled manner. The greatest eccentric muscle force occurs when the patient changes the weight’s direction of motion from downward to upward. Therefore, the amount of weight and the speed at which the weight is moved downward and upward can be varied to increase or decrease the intensity of training. As training progresses, the amount of weight and the speed of weighted movements are both increased. Effective eccentric muscle rehabilitation can also be accomplished using elastic resistance bands.

When going over the instructions for eccentric muscle training, patients might be surprised to hear that their tennis elbow pain should increase towards the end of each exercise session. This is a case where “no pain, no gain” applies. Insufficient loading of the tendon (inadequate intensity) or loading along the wrong axis, will delay recovery.

Progressive, eccentric muscle training is the only type of exercise known to increase muscle elasticity and tendon strength and is the process by which disorganized connective tissues associated with tennis elbow pain are remodeled to become functional once again. In the treatment of tennis elbow, progressive eccentric muscle training as prescribed by a qualified physical therapist is a reliable and effective means of achieving specific recovery goals. The precise method, intensity, frequency, and duration of eccentric muscle training must match the recovery goals of each patient, allowing the tennis player to return to playing tennis and getting the carpenter back to work swinging a hammer without pain.

Osteoarthritis is a degenerative joint disease marked by joint inflammation and deterioration. Osteoarthritis is common: according to the Arthritis Foundation, nearly 21 million Americans, or 7% of the US population, are affected by osteoarthritis. The incidence of osteoarthritis goes up sharply with age.

Considering its prevalence, you probably already know someone who has been diagnosed with osteoarthritis. If that person is a competitive or recreational runner, one might expect to hear others say, “All that running. It’s no wonder he’s got arthritis.”

The fact is, there are plenty of non-runners with osteoarthritis, too, and there is a lack of evidence to support the notion that running causes arthritis.

In his excellent book, “Lore of Running,” Dr. Timothy Noakes cites a variety of research studies designed to examine the relationship between running and arthritis. Studies published in 1994 and 1997 determined that recreational joggers are not at any increased risk of developing osteoarthritis. A study published in 1985 found that the incidence of osteoarthritis in a group of runners who competed between 1930 and 1960 was lower than a matched group of swimmers who competed at the same time. A Danish study published in 1990 found that a group of athletes that ran 20 to 40 km per week for 30 years had an incidence of osteoarthritis that was no different from that of a comparison group. And a 1986 study found that runners with an average age of 60 who had run an average of three hours per week for 12 years did not have a greater prevalence of osteoarthritis than a comparison group.

Though at no greater risk of developing osteoarthritis than others, runners can and do experience pain from soft tissue injuries, such as hip bursitis, iliotibial band (ITB) friction, and tendonitis. Pain resulting from these other causes can be serious enough to interrupt training and recreational running. The runner with poor mechanics may never train long enough to develop osteoarthritis from running. And clearly an athlete who has jogged for 30 years has the correct biomechanics to run without breaking down.

Excluding injuries resulting from falls, runners’ injuries are almost always due to progressing their training too quickly or overloading the muscle support around the affected joint. A runner’s muscular strength around his or her load-bearing joints must be considerably stronger than that of non-athletic individuals of the same age and sex. Furthermore, different types of running such as sprinting, long-distance, cross-country, and asphalt training have different muscle support requirements.

The running program at Physical Therapy of Los Gatos is a goal-directed training program designed to prevent running injuries, get runners who have been injured or recovering from orthopedic surgery back into training, and increase running speed. The evaluation for the running program includes a comprehensive interview process where we measure baseline parameters of running fitness, uncover specific deficiencies, analyze your running form, and help you clarify your goals. For additional information on preventing running injuries, rehabilitation of running injuries, and increasing running speed, please contact Physical Therapy of Los Gatos by calling (408) 358-6505.

An unintended consequence of the increase in sports participation by girls and young women over the past thirty years has been an extraordinary rise in the incidence of anterior cruciate ligament (ACL) injuries in young female athletes. At the college level, one in ten young female athletes participating in sports such as soccer, volleyball, and basketball will suffer an ACL tear injury. These girls are typically unable to practice or compete for one or more seasons and face potential loss of scholarship funding and significant psychological trauma. A widely cited 1985 study found that at the high school level, the knee injury rate among female athletes is one per 100 participants, and noted the need for preventative measures.

In 1983, sports medicine researchers determined that four-fifths of ACL injuries are non-contact injuries, that is, they are caused by the athlete’s own motions rather than collisions with other players. To the researchers, this finding meant that the high incidence of ACL tear injuries in young female athletes might be greatly reduced if those motions could be identified and avoided.

The ACL is one of four major ligaments that connect the upper and lower leg at the knee. The ACL provides joint stability and supports cutting and pivoting motions. Oftentimes, the ACL will tear with a “pop” that can be heard by spectators and other players. Pain and immediate swelling follow. ACL tears require surgical reconstruction using tendon grafts from other areas of the knee or from cadavers, followed by a long period of rehabilitation.

The frequency and seriousness of ACL tears in young female athletes has led to research studies aimed at understanding the problem. These studies are now yielding valuable data. Three major hypotheses to account for the higher number of ACL tears in female athletes versus male athletes have been examined: hormonal differences causing laxity of the female athlete’s ACL, a smaller and more narrow space within the knee for the female athlete’s ACL, and sex-based differences in lower extremity strength and coordination. The last of these three hypotheses is receiving the most scientific support from study data.

Certain aspects of lower extremity strength and coordination can be captured and measured by videotaping athletes while they perform athletic movements in the research lab. While video recordings do not capture complex three-dimensional movements and the rotational stresses that these movements place upon the knees, the recordings do enable researchers to make close measurements of joint and limb positions in a single plane. These measurements were found to have predictive value.

In one well-designed study of 205 young female athletes, researchers found that athletes with a specific way of posturing their lower extremities, known as “valgus” (or “knock-kneed”) alignment, during certain athletic movements were more likely to suffer ACL injury than athletes with more “neutral” or straighter lower extremity alignment. This valgus alignment can be seen by analyzing the angles formed between the ankles, knees, and hips when the athlete lands from a jump off a small box and when she jumps vertically from a crouched position. A separate study that included videographic analysis of 325 young female athletes showed that a six-week neuromuscular training program corrected the lower limb valgus alignment associated with injury during jump landing and takeoff.

It is already well-known to physical therapists that muscular strength stabilizes the knee by helping to maintain the correct relative positions of knee structures during sports movements and by allowing muscles in the legs to absorb forces that would otherwise subject the joint to potential injury. But physical therapists treating young female athletes must now consider the implications of the new studies. Physical therapists familiar with these studies infer that rehabilitation from ACL injury should, in addition to conventional strength training treatment methods, include specific neuromuscular training aimed at improving the athlete’s ability to avoid valgus alignment of the lower extremities during high-risk sports.

It is no longer acceptable to reconstruct the ACL but leave neuromuscular control deficient.

The jump strength training program at Physical Therapy of Los Gatos is an element of rehabilitation from surgical reconstruction of the ACL as well as a standalone performance improvement module. The program includes jump analysis, strength conditioning, and neuromuscular training designed to improve power and acceleration. The neuromuscular training methods employed include visual, auditory and proprioceptive cues to train athletes to use muscular strength to absorb jump impacts in a controlled fashion, and, if necessary, to correct jumping, landing, and pivoting techniques in order to avoid forces associated with injury. For additional information about prevention of ACL injury, rehabilitation from surgical ACL repair, and jump strength performance training for athletes, please call Physical Therapy of Los Gatos at (408) 358-6505.