A 19-year-old male collegiate baseball pitcher presented to an outpatient physical therapy clinic via direct access for left antecubital pain, which began 6 weeks prior to the evaluation. He provided consent for treatment and to publish his data, and the appropriate institutional review board deemed this case report exempt from review. While maximally throwing a curveball during tryouts, the patient heard a “pop” in his elbow. He was unable to continue pitching and took himself out of the game secondary to pain, apprehension, and lack of control. The day after the injury, he noticed bruising from the antecubital fossa into the anterior medial distal forearm, which lasted for three additional days. After the injury, he was able to throw during warm-ups, long toss 90 feet, and swing a baseball bat repetitively with minimal pain, yet he was unable to pitch off the mound. Four weeks after the injury, he tried pitching again from the mound and heard a similar painful pop while pitching. He then decided to seek physical therapy (PT) via direct access. At initial evaluation, the patient’s primary complaint was localized pain while pitching. The patient described the pain as “sharp” initially in the antecubital fossa and anterior/medial elbow but described the pain during the evaluation as “tight” in the same locations. He pointed to his “popping” sensation at the location of the DBBT. Symptoms were generally improving with time, and pain was reported as minimal in the past 24 h. He denied any numbness, tingling, grip strength changes, instability, or hand atrophy. He denied any pain proximal to the elbow or shoulder or cervical spine pain. Aggravating factors included pitching, especially while throwing curveballs, the rapid elbow flexion component of power clean Olympic lifts and carrying/lifting heavy objects during activities of daily living. Easing factors included rest and avoiding painful activities. The patient denied seeking treatment or medical consultation prior to the evaluation. He had no remarkable past medical history or prior upper-extremity injuries. He was not taking any medications and had no history of smoking. No prior imaging was performed for this injury. The patient’s goal of PT was to screen for any serious pathology in the elbow, identify the problem, and return to pitching for the club baseball team. Based on the subjective information, location of symptoms, and intake forms, the clinician’s primary hypothesis was DBBT tendinopathy. The patient reported a mechanism of injury consistent with substantial load on the biceps brachii (eccentric activity during rapid elbow extension and elevated stress when throwing curveballs, which require more forearm supination). The aggravating factors were also consistent with DBBT pathology due to the nature of heavy elbow flexion concentric and eccentric movement. However, the extent of DBBT injury was unclear based on subjective data. A thorough physical examination was performed with the most salient findings presented in. Upon visual observation, no signs of ecchymosis, edema, hand/forearm atrophy, or Popeye deformity were noted. Seated posture included rounded shoulder and increased thoracic kyphosis. Prior to local elbow testing, proximal segments were assessed to determine the possibility of symptom referral or radiation. A neurological examination including deep tendon reflexes, myotomes, and dermatomes of the upper extremity was normal and symmetrical bilaterally. Cervical, shoulder, and scapular screening including active and passive range of motion (A/PROM) was normal and pain free. Proximal segment screening did not recreate primary elbow symptoms. Elbow extension and flexion A/PROM was normal. Pain was provoked with passive elbow extension when combined with shoulder extension and wrist pronation (which maximally tensions the biceps brachii). Wrist A/PROM was normal in all directions. Tenderness was present approximately 2 cm proximal to the distal attachment on the radius. No palpable defect in the continuity of the DBBT was present. Increased tension was noted in the anterior/medial proximal forearm soft tissue restriction with minimal discomfort reported. No elbow joint pain, complaints of “popping” or symptoms of ulnar nerve pathology were recreated on examination. Manual muscle testing (MMT) was performed on relevant elbow and forearm tissues. Left elbow flexion was weak and recreated typical antecubital pain when performed with the arm bent at the side and with elbow extension and shoulder flexion to 90°. Elbow extension strength was 5/5 and pain free. Left forearm supination strength was weak and recreated typical antecubital fossa pain at 90° of elbow flexion and in full elbow extension. The right elbow and forearm were strong and pain free. Wrist and hand MMT did not elicit pain or weakness. Finally, a number of tissue differentiation tests were performed in efforts to identify the primary pathological tissue(s). Speed’s and Yergason’s tests both recreated typical DBBT pain. The biceps hook test and squeeze test were negative, making rupture less likely. Elbow valgus stress tests in multiple angles was normal. Biceps load II, full can, elbow flexion test, and Wartenberg and Tinel’s tests did not recreate typical symptoms. The outcomes used in this study were a combination of subjective and objective measures. Pain was assessed using the numeric pain rating scale (NPRS). Focus on Therapeutic Outcomes Inc. (FOTO) was used to assess self-reported symptom impact. FOTO allows for a determination of clinically important change although psychometrics are patient specific. FOTO outcome measures and Global Rating of Change (GROC) scales have shown good validity, sensitivity, and responsiveness [,,,,,]. Additional outcomes were palpation, strength, and provocation testing. Informal re-evaluation was performed at each follow-up visit at the beginning of each session. After competing diagnoses were made less likely, DBBT pathology was confirmed as the most likely cause of symptoms and functional decline. This was reinforced with a diagnostic cluster including the location of symptoms, reported mechanism of injury, positive tissue-specific provocation tests, and aggravating activities involving elbow flexion and supination. The patient did not have a DBBT rupture as the DBBT was intact (negative Hook test, biceps squeeze, reverse Popeye’s deformity). The patient did describe an audible “pop,” delayed ecchymosis, pain, and loss of function after an eccentric mechanism to the DBBT. Based on initial complaints, a partial tear was possible, however given the lack of similar signs or symptoms at evaluation, if a tear initially occurred, it was likely healing. Based on Cook’s load-induced tendinopathy continuum [,], the patient initially would have fallen into the category of having a “reactive tendon” due to acute overload. At the time of the initial evaluation (6 weeks after injury), he did not demonstrate signs of inflammation and symptom irritability and severity was reduced, suggesting the tendon was less reactive than at initial onset. During the “reactive” tendinopathy phase, interventions are typically aimed at minimizing pain, which includes relatively unloading the tissue to avoid continued aggravation [,]. At this phase, higher tendon strain through eccentric and plyometric loading or compression through end-range stretching should be avoided. However, it was the clinician’s assessment that, at time of initial evaluation, the patient did not present with a reactive tendinopathy but rather with a tendon needing improvement in load capacity to allow for improved functional levels. Given the patient’s need for substantial eccentric control of the biceps brachii during overhead pitching and the strong evidence supporting eccentric exercise in a number of other tendinopathies, the clinician concluded that eccentric loading should be integrated as possible to optimize function. When creating an optimal rehabilitation program, it is essential to understand the individual’s task-specific demands. In sports rehabilitation, mimicking sport-specific movement patterns through exercise may give the clinician a better understanding of the athlete’s readiness to play and may also give the patient more confidence in returning to sport. The overhead pitching motion consists of a sequence of movements that start in the lower extremity and trunk and transfer to the most distal segments in the upper extremity. There are six phases of pitching: windup, early cocking/stride, late cocking, acceleration, deceleration, and follow-through. The windup is when the transfer of energy from the ground into the lower extremities and trunk occurs. The early cocking/stride phase begins once the lead leg reaches the maximum height and the ball is removed from the glove and continues as the pelvis and lead leg travel down the mound toward the home plate []. The late cocking phase occurs between lead foot contact and the point of maximal external rotation (ER) of the throwing shoulder. During this phase, maximum valgus force torque is experienced at the elbow []. The biceps brachii reaches peak activity as it flexes the elbow, limits anterior humeral translation, and provides a compression force on the humeral head []. Extreme amounts of glenohumeral ER are achieved at this stage. The acceleration stage starts between maximum ER and ball release []. Internal rotation (IR) velocities have been recorded as high as 7000° to 9000° per second [,]. During the acceleration, the elbow initially flexes from 90° to 120°, and then rapid extends to near 25° just before ball release [,]. The biceps brachii supplies elbow flexion torque reaching a maximum value of up to 61 N-m just before ball release []. Maximum elbow extension angular velocity occurs just before ball release and may reach as high as 2251° per second [,]. The deceleration phase occurs between ball release and maximum glenohumeral IR and elbow extension. This phase is typically described as the most violent phase []. During deceleration, there is marked biceps brachii and brachialis activity decelerating the rapidly extending elbow and pronating forearm []. The follow-through proceeds as the body continues the motion until motion has ended. Many pitchers, such as the patient in this case study, have a variety of pitches that they use. Our patient primarily used fastballs, change-ups, and curveballs for his pitch selection. The curveball was the pitch that the patient stated he had increased pain with during pitching. The curveball arm motion and grip are almost identical to the fastball, but rather than gripping on the top of the ball, fingers are placed on the side of the ball during curveballs []. During curves, the pitcher will supinate the forearm until ball release during the late acceleration, generating rotation of the ball around a central axis. The added supination could theoretically increase biceps brachii loading, as compared to the fastball. Maximum elbow extension angular velocity and shoulder IR angular velocity are greater with a curveball versus that with a changeup []. After taking into consideration the DBBT pathology and the sport-specific demands of overhead throwing, the primary focus of the intervention program was an impairment-based approach, with an emphasis on improving tendon load capacity while minimizing undue strain through addressing adjacent-segment inadequacies. Assessment of the patient’s function, pain, and strength was used to guide the intensity of progression toward his goal of pitching. Intervention progression is described in detail in. Interventions initially focused on restoring pain-free AROM for the elbow and forearm using high repetitions and low load [,,,]. Soft tissue restrictions of the forearm were addressed to allow for optimal movement patterns. Instrument-assisted soft tissue mobilization (IASTM) was performed on areas of restriction and followed by self-stretching [,,]. The patient was instructed to stretch the anterior forearm and biceps with elbow/wrist/flinger extension for three sets of thirty seconds each. The patient was also instructed to perform this stretch after performing a self-massage using hands of biceps and anterior/medial forearm for thirty seconds each. Education was provided to avoid aggravating activities (i.e., heavy lifting, power cleans, pitching) until the effect of treatment was established. Eccentric training on the first session (initial evaluation) was performed with low intensity. Multiple forearm positions were used in order to replicate the stress on the biceps during overhead pitching and to strengthen additional elbow flexors (brachialis and brachioradialis) ( and ). In efforts to avoid undue strain and manage total tension of the tendon, eccentric training started with mid-range positions of shoulder and elbow flexion. Three sets of seven repetitions were prescribed, as this dosage was found effective for a high-level wrestler with distal biceps tendinopathy []. After the second session, the patient was instructed to perform the exercises every day at the gym with supinated, neutral, and pronated grip using a load that was “heavy as tolerated, feeling uncomfortable but not disabling,” with good form and able to control eccentric descent for three seconds. Numerous variables such as rotator cuff fatigue or lack of scapular control can contribute to poor shoulder mechanics and excessive strain on the arm while pitching [,,,,]. Shoulder ER/IR exercises were performed, starting by the side then progressing to 90° shoulder abduction and 90° elbow flexion positions. Scapular strength and endurance are essential for pitching. Scapular strengthening was performed, yet many common scapular strengthening exercises use concentric elbow flexion (i.e., rows). Exercises started in prone position to improve scapular control while avoiding pulling motions at the elbow. The patient reported that he performed eccentric training every day outside of the clinic other than two rest days. Concentric biceps activation was emphasized two weeks after evaluation, with multiple forearm positions such as supination, pronation, and neutral grip once the patient had non-painful MMT for elbow flexion and wrist supination. The primary focus of concentric training was to improve the biceps strength in mid-range positions. Dosage for concentric training was three sets of ten repetitions, which have been shown to improve muscle strength and endurance []. Load was chosen based on rate of perceived exertion as the patient was instructed to select a weight that ensured the last two reps out of ten were challenging while maintaining good form. Eccentric loading was gradually increased as tolerated to build tendon capacity. Pitching specific exercises were also progressed with increased resistance and repetitions toward sport-specific positions such as arm cocking. Resistance bands were used to perform shoulder external and internal rotation due to the ability for the patient to perform easily at home as well as the end-range strengthening qualities of the band. Rows with pulley were integrated to allow for concentric elbow flexion in more functional movement patterns. Once the patient had asymptomatic resisted and provocative testing, progression focused on plyometric training and baseball-specific movement patterns (, and ). Exercises incorporated rapid, sport-specific eccentric loading of the DBBT. Fast concentric motions at end range were also included during this stage. After completing the plyometric exercises, the patient performed light throwing with a tennis ball at thirty feet. Unfortunately, the patient was returning home for winter break after the fifth session and was unable to continue formal PT. He was given a progressive return to throw program to be performed during the month of break before club baseball resumed. The interval long-toss throwing program started on flat ground progressing distance and number of throws. After completing a long-toss program, the program progressed to simulated pitching off flat ground and then on the mound. Curveball throwing was initiated in the later phases of the program. It was recommended that he should be able to complete a phase without compensation or pain before progressing to the next phase. The patient was instructed to contact the treating therapist should questions arise. The patient was seen in PT five times, including the initial evaluation, over the course of four weeks. Subjective and objective reassessment measures were completed at the beginning and end of each session, with outcomes presented in. FOTO was used on the initial evaluation and discharge. The Patient’s Physical FS Primary Measure score intake improved from 83 to 98 points and demonstrated 15 points of change. Given the patient’s risk-adjustment variables and the actual intake FS score, FOTO predicted that the patient will increase in function by at least 8 points (to 91), suggesting his minimal clinically important difference (MCID) was satisfied. NPRS and GROC both improved greater than their respective MCIDs. MMT was normal and pain free, and he no longer had tenderness or pain with provocative testing. The patient was contacted via email six weeks after discharge. He reported that he did not have any residual pain or loss of function related to his elbow. He returned to pain-free throwing and was satisfied with his improvement.