The Role of Athletic Trainers in Preventing and Managing Posttraumatic Osteoarthritis in Physically Active Populations: a Consensus Statement of the Athletic Trainers' Osteoarthritis Consortium^a

Joint Injury (Location, Type, Severity, and Recurrence)

Excess Body Weight

Obesity (body mass index [BMI] >30; calculated as kg/m²) is an established and robust risk factor for knee OA. Results from a recent meta-analysis⁶⁴ showed that individuals who were overweight (BMI = 25.0–29.9) were 2.5 times more likely to develop knee OA and those who were obese were 4.6 times more likely to develop knee OA. Further, the risk of knee OA increased by 35% with each increase of 5 in BMI. Being overweight or obese is also a risk factor for hip⁴⁶ and hand⁶⁵ OA. However, fewer data are available examining body weight as a risk factor for PTOA. Being overweight or obese at the time of surgical repair for an ankle fracture increases the risk of developing moderate to severe (Kellgren and Lawrence grade 3–4) PTOA; those patients who were overweight at the time of surgery were 1.9 times more likely to develop OA and those who were obese were 2.8 times more likely to develop PTOA.⁶⁶ In a mouse model of PTOA, obesity increased the severity of OA associated with a traumatic knee fracture.⁶⁷ Although a weight gain greater than 15 lb (6.8 kg) within the first 5 years after ACLR was not directly linked to radiographic or cartilage-measured changes in joint structure, Spindler et al⁶⁸ observed that it was a predictor of poor patient-perceived outcomes.

Range-of-Motion Deficits

Range-of-motion (ROM) loss after injury is commonplace. More often than not, restoration of ROM is considered complete with appropriate rehabilitation, and as such, ROM is not often studied as a potential risk factor for PTOA. Yet based on the limited available evidence, it would appear that ROM deficits may contribute to PTOA development after ACLR. Roe et al⁶⁹ found that flexion contractures were associated with early evidence of PTOA at approximately 7 years after ACLR. Shelbourne and Gray⁷⁰ showed that patients with less than normal ROM after ACLR were 2.5 times more likely to have radiographic evidence of PTOA at approximately 10 years than patients with normal ROM. In a subsequent study, Shelbourne et al⁷¹ noted that limited knee-flexion ROM at return to play increased the risk for radiographic evidence of OA.

Range-of-motion deficits subsequent to injuries other than ACL tears have yet to be linked to PTOA. For instance, patients with chronic ankle instability often present clinically with deficits in dorsiflexion ROM.^72,73 These ROM deficits have been linked to altered landing kinematics,⁷⁴ but their involvement or lack thereof in the development of PTOA secondary to ankle injury has not been systematically investigated.

Strength Deficits

Muscle weakness is a common consequence of many joint injuries. In particular, quadriceps muscle weakness, which often accompanies ACL injuries,^75,76 is thought to lead to impaired dampening and shock-attenuation abilities, resulting in greater loads being transmitted to the knee-joint structures; therefore, it has been suggested as a risk factor for the development of PTOA.^77–79 Available evidence indeed supports the premise that quadriceps weakness is a risk factor for PTOA. Keays et al⁸⁰ demonstrated that 6 years after ACLR, weak quadriceps muscles and low quadriceps-to-hamstrings strength ratios measured at 60°/s trended toward discriminating between participants without OA (Kellgren and Lawrence grade 0 or 1) and those with OA (Kellgren and Lawrence grade 2 or greater). Using a prospective study design, Tourville et al⁸¹ noted that quadriceps strength loss measured within a few months after ACL injury was associated with joint-space narrowing by 4 years after ACLR. Oiested et al⁷⁹ found an association between quadriceps strength loss that occurred 2 to 15 years after ACLR and symptomatic knee OA (Kellgren and Lawrence grade 2) but were unable to establish an association between weakness soon after ACL injury and radiographic OA. These data are not conclusive, but they suggest that quadriceps weakness after ACL injury may be associated with the development of PTOA. More research is necessary to determine if muscle weakness that manifests after other joint injuries (eg, ankle sprains, shoulder sprains, and dislocations) contributes to the risk of PTOA.

Static Alignment

Joint malalignment has been established as a risk factor for knee OA. In 2 large prospective cohort studies,^82,83 varus knee alignment was associated with 1.5-fold and 2-fold increased risks of knee OA. Although the data linking malalignment to PTOA are not as strong, the current research suggests that malalignment may be a risk factor. In a retrospective study,⁵⁰ patients who sustained a tibial plateau fracture and displayed a valgus malalignment of 5° or greater were more likely to develop moderate to severe PTOA (Kellgren and Lawrence grade 3–4). Similarly, varus malalignment of the contralateral, uninjured knee of patients who sustained an ACL injury approximately 15 years earlier predicted the risk of OA in the ACL-injured knee (OR = 3.9; 95% confidence interval = 1.0, 15.8).⁸⁴

Static malalignment is also a common indication for a high tibial osteotomy, which is often performed for a varus-aligned knee with isolated medial compartment OA (PTOA or primary OA). The surgery reduces the load on the medial knee compartment by shifting the mechanical axis to the lateral compartment.⁸⁵ The goals of this procedure are to reduce symptoms and potentially prevent further overload of the medial compartment in an attempt to alter or slow disease progression. Pain and function improve with high tibial osteotomy,⁸² yet no evidence shows a beneficial effect in slowing disease progression. Studies are needed to examine disease-related outcomes of high tibial osteotomy and nonoperative treatment to better understand the effectiveness of the surgery.

Physical Activity and Sports Participation

The health benefits associated with physical activity strongly support the importance of a physically active lifestyle in children and adults. Physical activity may be beneficial to joints because it encourages strength, endurance, neuromuscular control, and weight management; however, certain high-level physical activities may expose joints to repetitive overloading and a greater risk of injury or osteoarthritis. In a large prospective study, more than 5000 individuals (minimum age = 20 years, 2/3 of the study population was between 40 and 60 years old) were surveyed regarding physical activity (frequency, duration, intensity, and type) and then radiographs were taken 4, 9, and 13 years after the survey.⁸⁶ No association was evident between OA development and running, walking, or physical activity. Hansen et al⁸⁷ compiled the evidence related to running and OA and were unable to support an association between short-distance to moderate-distance running and OA; however, the evidence was inconclusive regarding high-volume running (>20 miles [32 km] per week). There may indeed be a dose-response relationship between physical activity and OA (ie, high-level physical activity is more risky and low-level activity is safe). Michaelsson et al⁸⁸ found that cross-country skiers participating in 5 or more high-level races had a 70% higher rate of OA than skiers who completed only a single race. Further, skilled skiers (ie, those with faster racing times) were also more likely to develop OA.

Not only is low to moderate physical activity safe for joints but it may also protect a joint from OA.⁸⁹ For example, over a 2-year period, Wijayaratne et al⁹⁰ observed that retropatellar cartilage volume was less in sedentary women than in physically active women. Similarly, Mosher et al⁹¹ demonstrated increased femoral cartilage volume in marathon runners compared with nonrunners.

With regard to specific sports, Driban et al⁹² quantitatively analyzed 17 studies and found that the prevalence of knee OA in former sport participants (n = 3759) was 7.7%, compared with 7.3% among nonexposed control participants (n = 4730, OR = 0.9). Athletes who were involved in certain sports were more likely to have knee OA: competitive weight lifting (OR = 6.9), wrestling (OR = 3.8), soccer (OR = 3.5), or elite-level long-distance running (OR = 3.3), suggesting a 3 to 7 times higher prevalence of knee OA in these sports. It should be noted that the authors were unable to control for a previous history of joint injury and, thus, we do not know if the higher OA rates were due to higher rates of joint injury or the result of participation in the activities themselves. However, in this same systematic review, the authors were able to control for joint injury in a smaller subset (4 studies) and found similar results. Uninjured participants in elite-level (soccer or orienteering) and nonelite-level (soccer or American football) sports had a higher prevalence of knee OA (OR = 9.46 and 3.75, respectively) than nonexposed control participants. Supporting the contention that an interaction exists between competition level and injury and the risk for PTOA is work by Roos et al,⁹³ who compared elite and nonelite soccer players with or without a history of injury. The prevalence of knee OA was highest in injured elite-level soccer players (33.3%) and lowest in uninjured control participants (1.3%) and nonelite soccer players (2.7%).

The level of physical activity after acute traumatic joint injury could play a role in the initiation and progression of PTOA, yet conflicting evidence makes it difficult to establish a clear association. Among a young and physically active population, individuals with a history of knee-joint injury reported lower scores on the Knee Injury and Osteoarthritis Outcome Score (KOOS)^94,95 and Western Ontario and McMaster University Osteoarthritis Index (WOMAC)⁹⁶ scales, indicating more symptoms and impaired function, despite reporting higher levels of physical activity (as measured by the Marx Activity Rating Scale) than uninjured control participants.^97,98 Similar results were recently reported in collegiate athletes.⁹⁹ If symptoms persist, structural alterations are present, or physical function is not regained after joint injury, returning to a high level of physical activity could exacerbate symptoms and prove detrimental to long-term joint health. Therefore, low-impact activities may be an appropriate alternative. Further research is needed to determine when it is safe to return to physical activity after joint injury and whether certain types of physical activity (eg, excessive loading, cutting) are associated with the initiation and progression of PTOA after joint injury.

Neuromuscular Deficits

Neuromuscular deficits, such as an inability to control muscle force or activate a muscle completely, could be related to the onset of PTOA; however, little evidence is available to verify this hypothesis. After ACLR, patients who performed a single-legged landing had greater hamstrings coactivation and higher tibiofemoral compressive forces than uninjured, control participants.¹⁰⁰ Similarly, when patients who had undergone ACLR were asked to complete a force-matching task approximately 18 months after their surgery, they displayed less accurate quadriceps force control and more quadriceps and hamstrings coactivation than healthy individuals.¹⁰¹ Aberrant loading at the knee joint (eg, overloading or underloading) resulting from altered muscle activation or diminished quadriceps control after ACLR could influence joint-loading patterns and lead to joint degeneration. In the same way, modified knee-joint kinematics, such as altered knee flexion and rotation, may result in greater loads on previously unloaded regions of articular cartilage and lead to the biological changes that result in PTOA.^40,102

Arthrogenic muscle inhibition, an inability to completely activate a muscle voluntarily, is another neuromuscular deficiency that could play a role in PTOA.⁷⁸ Arthrogenic inhibition affects a muscle's ability to contract even in the absence of direct trauma to that muscle. This occurs commonly in the quadriceps after ACL injury or reconstruction. The inhibition is due to diminished motoneuron activity and may contribute to the lingering strength deficits that have been noted after ACLR and that have been linked to PTOA.

Although the aforementioned neuromuscular deficits and alterations have been identified after joint injury, a direct link between them and the development of PTOA has yet to be shown. Future research is necessary to support or refute the hypothesis that altered neuromuscular control after joint injury contributes to the onset of PTOA.

Primary Injury Prevention

To aid in the prevention of PTOA, ATs should continue to promote, deliver, and evaluate the efficacy and effectiveness of primary injury-prevention programs designed to reduce the risk of acute traumatic joint injuries. Compared with the uninjured population, knee injury increases the risk of developing OA 4-fold and hip injury appears to increase the risk of PTOA 5-fold.¹⁰⁵ Therefore, by preventing the initial insult to the joint, it is likely that we can also prevent the long-term consequences of joint injury (eg, PTOA). Even though it is impossible to prevent all joint injuries, reducing a moderate number of these injuries would be a substantial step toward reducing the incidence and prevalence of PTOA in the young and active patient populations often treated by ATs. For example, if we were able to prevent 30% (or 75 000) of the roughly 250 000¹⁰⁶ ACL injuries that occur each year in the United States, we could prevent approximately 37 500 cases of PTOA if we assume that half of the persons who sustain ACL ruptures would go on to develop PTOA.

Neuromuscular training, which includes balance, strength, plyometric, and agility exercises, along with education regarding proper movement control, delivered as a preseason program or a warm-up during the season, appears to be effective in preventing lower extremity injury. In their recent meta-analysis, Emery et al¹⁰⁷ compiled outcomes from 25 investigations in which neuromuscular training was delivered to youth (aged 19 years or younger) who participated in team sports. The authors found that neuromuscular training had a protective effect on lower extremity injury risk, noting a 36% risk reduction. They also identified a preventive effect of neuromuscular training in reducing knee injuries by 26%, but this number did not reach statistical significance.¹⁰⁷ Sugimoto et al¹⁰⁸ observed a larger preventive effect of neuromuscular training for female athletes: 73.4% relative risk reduction. Specifically, a 73.4% relative risk reduction (ie, 73% less likely to experience a noncontact ACL injury) was evident in females who participated in a neuromuscular training program compared with those who did not. Herman et al¹⁰⁹ conducted a meta-analysis of 9 studies involving more than 13 000 participants to examine the effectiveness of neuromuscular warm-up strategies on injury prevention and demonstrated similar findings. Their study highlighted that, in general, neuromuscular training programs can reduce the risk of lower extremity and knee injuries. Further, it showed that protocols (eg, Anterior Knee Pain Prevention Training Program) are available to reduce the incidence of anterior knee pain in military recruits. Also of interest from their results is that neuromuscular training programs did not produce significant reductions in hip or thigh injuries. In summary, neuromuscular training appears to reduce lower extremity injury risk and, thus, we encourage ATs to incorporate such programs into sports and activities in which lower extremity injuries are common.

Although our intent was not to review neuromuscular training programs, we highlight the following key aspects of most effective programs¹¹⁰: (1) Neuromuscular training programs that incorporate multiple components (lower extremity and core-muscle–strengthening exercises, plyometric exercises, balance exercises, and consistent feedback to participants on proper technique) appear to demonstrate the greatest overall protective effect¹¹¹; (2) making the programs sport specific and securing coach involvement appear to be important for successful implementation¹¹²; (3) completing the program at an appropriate dosage (ie, over at least 3 months and at all training sessions during that period¹⁰⁹ or 15 sessions over 6 weeks with minimum 15-minute exposures, started before the season)¹¹⁰; (4) no to minimal equipment is required to complete the program¹¹⁰; and (5) some ongoing maintenance training may be necessary to retain the benefits of these programs over time (ie, across multiple years or seasons).^113,114 More research is needed in many areas related to neuromuscular training programs, but implementation research that integrates theories of health-behavior change is a top priority. The focus needs to be on how to encourage people to change their attitudes and behaviors toward these neuromuscular training programs so that athletes and the physically active are more likely to adopt and maintain participation in the programs over time, as compliance is critical to program effectiveness.¹¹⁵ Theories of health-behavior change have been applied to a number of health conditions to improve participation and compliance; however, many studies of musculoskeletal injury prevention, including ACL injury-prevention programs, have failed to integrate these theories. Also, research related to the necessary timing, dose, and strategies for effective retention is needed.

Proprioceptive training programs, which consist of exercises that challenge a patient's ability to target, detect, and react to varying joint positions,¹¹⁶ are popular interventions for ankle-injury prevention. This type of training includes exercises such as balancing on a wobble or balance board, reacting to a sport-specific stimulus (eg, catching or throwing a ball) while standing on a single limb, and balancing on a single leg with the eyes closed. A recent meta-analysis¹¹⁷ demonstrated that compared with various other control training interventions, proprioceptive training reduced ankle-sprain risk by 35% (relative risk = 0.65, 95% confidence interval = 0.55, 0.77). Similar findings were demonstrated among patients with or without a history of ankle sprain, reinforcing the importance of primary injury-prevention efforts. Although proprioceptive training may be effective for combating ankle injuries, evidence supporting its ability in isolation to reduce the overall risk of lower extremity injury, similar to neuromuscular training, is lacking. As such, we recommend adopting a neuromuscular training program that incorporates proprioceptive training over proprioceptive training alone so that any protective effects potentially span more than 1 joint.

No evidence to detail the effectiveness of primary prevention programs for upper extremity injuries is currently available. This is most likely because knowledge of upper extremity injuries lags behind that of lower extremity injuries. For prevention programs to be developed, we must determine risk factors for the shoulder, elbow, wrist, and hand and test programs aimed at targeting the modifiable risk factors for these upper extremity joint injuries.

Secondary and Tertiary Prevention

Traditionally, the management of acute traumatic joint injuries has ended when patients are deemed fit to return to activity. Treatment has focused on healing joint tissues, restoring anatomic structures, and improving functional capabilities through surgical repair or rehabilitation (or both). Patients are typically discharged from follow-up care within several weeks to more than 9 months, depending on the injury severity and treatment approach. However, as noted earlier, for many patients, these injuries are the starting point for a cascade of progressive pathologic joint changes (eg, PTOA) that, over the course of several years, leading to chronic pain and loss of function, resulting in limitations that affect both physical performance and activities of daily living. The paradigm in which the initial injury is treated and the long-term consequences are ignored must change.

In September 2012, COAMI issued a call to action highlighting the need to adopt a chronic management model for OA, similar to the models used to treat heart disease, diabetes, and hypertension.¹⁵ The treatment goals of this chronic management model are to detect and modify risk factors early, before symptoms develop, so that the debilitating outcomes associated with PTOA can be mitigated or prevented entirely (Figure 2). The chronic management model typically focuses on secondary and tertiary prevention of PTOA after joint injury. In 2014, the American Orthopaedic Association conducted a symposium to examine emerging management strategies after acute traumatic joint injury in order to shift the clinical approach to PTOA from palliation to prevention.¹¹⁸ A primary emphasis was the diagnosis and management of preosteoarthritis in the time between joint injury and the traditional radiographic diagnosis of OA: on average, 10 to 15 years after injury. It noted that orthopaedic surgeons who treat the full spectrum of joint injuries should have “an awareness of the paradigm shift toward the prevention of OA which is critical to the promotion of improved clinical care.”¹¹⁸ Athletic trainers who care for patients with acute traumatic joint injuries should also be aware of this paradigm shift focusing on the secondary and tertiary prevention of PTOA after joint injury.

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Athletic trainers are in an ideal position to serve as case managers in the chronic management model for PTOA, particularly in young and physically active patients at risk for joint injury. We are also well positioned to detect and modify risk factors for PTOA as soon as possible after joint injury, preferably before symptoms appear, so that this debilitating condition can be managed more effectively or prevented entirely. It is important to point out that the traditional approach of waiting until radiographic or symptomatic OA is diagnosed to implement treatment is too late, as the disease process cannot be reversed; therefore, ATs must take steps to mitigate PTOA before it occurs. An overview of a possible chronic disease management model for PTOA after acute traumatic knee joint injury, in which an AT serves as a case manager, is shown in Figure 2. As noted previously, the AT is typically present when an athlete or patient sustains an acute traumatic knee-joint injury, and he or she commonly manages the care and referrals for treatment in the early stages of injury and throughout rehabilitation and return to play. During this time, ATs can also play a critical role in educating the patient about the risk of PTOA postinjury and discussing evidence-based management strategies to potentially mitigate or prevent the development and progression of PTOA (eg, self-management, weight management). Athletic trainers are also well positioned to monitor joint health and other known risk factors over the life span after joint injury. This can be accomplished through annual visits or preparticipation screening. The goals of these annual assessments are to monitor joint pain and function over time and to refer patients who report increased levels of pain or decreased levels of function, as these may be signs of preosteoarthritis. If we can identify these patients early, PTOA could be more effectively managed and perhaps further joint damage would not ensue or symptoms would not worsen. In other words, early identification would provide an opportunity for early interventions or behavior modifications (eg, weight management, activity modifications, exercise programs). Athletic trainers could also work with patients on appropriate exercise prescriptions and weight-management strategies to reduce symptoms, improve function, and potentially limit the development and progression of PTOA. These practices are in alignment with evidence-based recommendations for the management of OA.¹⁴ The ultimate goal of secondary and tertiary prevention efforts is to push the end stage of disease as far off in the timeline as possible in an attempt to delay total joint failure and the need for total knee replacement surgery.

Evidence-Based Management Recommendations

Recently, Nelson et al¹⁴ conducted a systematic review of treatment and management recommendations and guidelines for OA. They evaluated treatment recommendations for OA from all professional medical associations and societies that had published recommendations or guidelines at the time of their review. A summary of their recommendations is provided in Table 2. A key finding was agreement on many recommendations for the management of OA across the multiple professional societies and organizations making such recommendations; however, how these recommendations were being disseminated and implemented in clinical practice varied considerably. Although these recommendations were primarily focused on managing patients currently suffering from the symptoms and consequences of OA, some may be beneficial in the secondary and tertiary prevention of PTOA after acute traumatic joint injury and before the onset of symptoms or dysfunction. For example, self-management strategies for monitoring joint health over time, managing regular exercise and the type of physical activity patients engage in, and maintaining a healthy weight likely play important roles in the secondary prevention of PTOA after joint injury. The remaining recommendations are probably more appropriate for tertiary prevention to manage pain and symptoms in order to delay end-stage disease and total joint arthroplasty. We will elaborate on the recommendations for secondary PTOA prevention (weight management, physical activity, and self-management strategies), as they will likely be critical in improving the quality of life for those with PTOA (Figure 3). These recommendations were generated by the Centers for Disease Control and Prevention as management and intervention strategies for OA in general,¹⁶ but they are also applicable to secondary prevention of PTOA.

Table 2.  Guidelines for the Management of Osteoarthritis (OA)¹⁴

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Maintaining a healthy body weight is important. People who maintain a healthy weight are less likely to develop symptomatic knee OA,^119,120 and this appears to apply to PTOA as well. Englund and Lohmander¹²¹ found that obesity was associated with symptomatic tibiofemoral PTOA after a meniscectomy in persons 15 to 22 years old. Greater body weight increases the loads transmitted across weight-bearing joints and can, therefore, increase the pain and symptoms associated with OA. In fact, Messier et al¹²² observed that for each pound of weight lost, the load exerted on the knee per step during daily activities in adults with knee OA who were overweight or obese was reduced 4-fold. Further, in a subsequent randomized clinical trial, Messier et al¹²³ found that adults with knee OA who were overweight or obese and who participated in a diet and exercise regimen not only reduced compressive forces at the knee but also had reductions in inflammatory markers and self-reported pain as well as improvements in physical function. Therefore, ATs should encourage athletes to maintain a healthy weight (BMI <25) after joint injury. In addition, patients who are overweight (BMI ≥25) or obese (BMI ≥30) should be encouraged to manage weight through an individualized eating plan, physical activity and exercise regimen, and, if needed, referral to appropriate members of the sports medicine team.

Living a sedentary lifestyle could increase the risk for PTOA and other lifestyle-related diseases, such as diabetes and cardiovascular disease. Regular physical activity has been shown to decrease pain and disability and improve function in all forms of arthritis.¹²⁴ Low-impact, moderate-intensity aerobic physical activity (eg, cycling, swimming, walking) and muscle strengthening are considered the safest and most effective exercises for adults who have OA.¹⁶ Although this guideline is likely also appropriate for patients at risk for PTOA, it may be difficult to implement, especially in younger athletes who participate in high-impact or elite-level sports. In these instances, until more research is available to support or refute sport participation and high-intensity physical activity as a risk factor for PTOA, patients should be educated to monitor their symptoms during activity and to report to a health care provider (AT, physician) if participation in their normal physical activities is causing them difficulty. In addition to aerobic activity, strengthening programs should be adopted to maximize muscle strength (eg, achieve preinjury strength values equivalent to the contralateral limb or strength values that allow a high level of physical function). This could not only help to prevent PTOA but also to reduce pain and increase joint function in those experiencing PTOA symptoms.¹²⁵ Maintaining muscle strength after achieving strength goals is critical to continued success of the initial program and, therefore, continued participation in strengthening exercises is warranted. Thus, even if preinjury strength levels are achieved, participation in strengthening programs should be continued at least 2 times per week.¹⁶ Hence, patients should be encouraged to continue aerobic and strengthening exercises not only during their competitive careers but also throughout their lives.

Self-management education is a process in which patients with a chronic disease are taught how to manage their condition, prevent its consequences, and achieve the best possible quality of life. Several arthritis self-management programs are available. The Centers for Disease Control and Prevention currently recommend the use of the Arthritis Self-Management Program and the Chronic Disease Self-Management Program (each has an English and Spanish version available), as sufficient research supports their effectiveness.¹²⁶ Generally speaking, both programs contain information regarding how to deal with problems associated with arthritis and chronic disease; appropriate exercise regimens; appropriate use of medications; suggestions on how to communicate effectively with family, friends, and health care providers regarding arthritis and chronic disease; nutritional information; and guidelines on how to evaluate new treatments and therapies.^127,128 The research behind both programs shows that participation in these programs improves patients' confidence in managing their conditions, reduces depression and anxiety related to the condition, reduces pain, improves quality of life, and can lead to increased exercise participation.¹²⁹ Athletic trainers need to highlight to patients that the choices they make after joint injury will likely affect the initiation and progression of PTOA and that part of their self-management strategy is to understand the risk factors for PTOA and to make educated decisions with regard to physical activity, diet and weight management, and monitoring of joint health.