Dislocations are joint injuries that force the ends of your bones out of position. The cause is often a fall or a blow, sometimes from playing a contact sport. You can dislocate your ankles, knees, shoulders, hips, elbows and jaw. You can also dislocate your finger and toe joints. Dislocated joints often are swollen, very painful and visibly out of place. You may not be able to move it.

A dislocated joint is an emergency. If you have one, seek medical attention. Treatment depends on which joint you dislocate and the severity of the injury. It might include manipulations to reposition your bones, medicine, a splint or sling, and rehabilitation. When properly repositioned, a joint will usually function and move normally again in a few weeks. Once you dislocate a shoulder or kneecap, you are more likely to dislocate it again. Wearing protective gear during sports may help prevent dislocations.

Displacement of bones from their normal positions at a joint.

What is a dislocated shoulder?

Your shoulder joint is made up of three bones: your collarbone, your shoulder blade, and your upper arm bone. The top of your upper arm bone is shaped like a ball. This ball fits into a cuplike socket in your shoulder blade. A shoulder dislocation is an injury that happens when the ball pops out of your socket. A dislocation may be partial, where the ball is only partially out of the socket. It can also be a full dislocation, where the ball is completely out of the socket.

What causes a dislocated shoulder?

Your shoulders are the most movable joints in your body. They are also the most commonly dislocated joints.

The most common causes of shoulder dislocations are

• Sports injuries
• Accidents, including traffic accidents
• Falling on your shoulder or outstretched arm
• Seizures and electric shocks, which can cause muscle contractions that pull the arm out of place

Who is at risk for a dislocated shoulder?

A dislocated shoulder can happen to anyone, but they are more common in young men, who are more often involved in sports and other physical activities. Older adults, especially women, are also at higher risk because they are more likely to fall.

What are the symptoms of a dislocated shoulder?

The symptoms of a dislocated shoulder include

• Severe shoulder pain
• Swelling and bruising of your shoulder or upper arm
• Numbness and/or weakness in your arm, neck, hand, or fingers
• Trouble moving your arm
• Your arm seems to be out of place
• Muscle spasms in your shoulder

If you are having these symptoms, get medical treatment right away.

How is a dislocated shoulder diagnosed?

To make a diagnosis, your health care provider will take a medical history and examine your shoulder. Your provider may also ask you to get an x-ray to confirm the diagnosis.

What are the treatments for a dislocated shoulder?

The treatment for dislocated shoulder usually involves three steps:

• The first step is a closed reduction, a procedure in which your health care provider puts the ball of your upper arm back into the socket. You may first get medicine to relieve the pain and relax your shoulder muscles. Once the joint is back in place, the severe pain should end.
• The second step is wearing a sling or other device to keep your shoulder in place. You will wear it for a few days to several weeks.
• The third step is rehabilitation, once the pain and swelling have improved. You will do exercises to improve your range of motion and strengthen your muscles.

You may need surgery if you injure the tissues or nerves around the shoulder or if you get repeated dislocations.

A dislocation can make your shoulder unstable. When that happens, it takes less force to dislocate it. This means that there is a higher risk of it happening again. Your health care provider may ask you to continue doing some exercises to prevent another dislocation.

Displacement of the PATELLA from the femoral groove.

Slippage of the FEMUR off the TIBIA.

Fracture of a bone near an articulation with concomitant dislocation of that joint.

Fractures involving a GROWTH PLATE.

Fracture in the proximal half of the shaft of the ulna, with dislocation of the head of the radius.

Appendicular System: Fractures of Upper Limb Bones

Due to our constant use of the hands and the rest of our upper limbs, an injury to any of these areas will cause a significant loss of functional ability. Many fractures result from a hard fall onto an outstretched hand. The resulting transmission of force up the limb may result in a fracture of the humerus, radius, or scaphoid bones. These injuries are especially common in elderly people whose bones are weakened due to osteoporosis.

Falls onto the hand or elbow, or direct blows to the arm, can result in fractures of the humerus. Following a fall, fractures at the surgical neck, the region at which the expanded proximal end of the humerus joins with the shaft, can result in an impacted fracture, in which the distal portion of the humerus is driven into the proximal portion. Falls or blows to the arm can also produce transverse or spiral fractures of the humeral shaft.

In children, a fall onto the tip of the elbow frequently results in a distal humerus fracture. In these, the olecranon of the ulna is driven upward, resulting in a fracture across the distal humerus, above both epicondyles (supracondylar fracture), or a fracture between the epicondyles, thus separating one or both of the epicondyles from the body of the humerus (intercondylar fracture). With these injuries, the immediate concern is possible compression of the artery to the forearm due to swelling of the surrounding tissues. If compression occurs, the resulting ischemia (lack of oxygen) due to reduced blood flow can quickly produce irreparable damage to the forearm muscles. In addition, four major nerves for shoulder and upper limb muscles are closely associated with different regions of the humerus, and thus, humeral fractures may also damage these nerves.

Another frequent injury following a fall onto an outstretched hand is a Colles fracture (“col-lees”) of the distal radius. This involves a complete transverse fracture across the distal radius that drives the separated distal fragment of the radius posteriorly and superiorly. This injury results in a characteristic “dinner fork” bend of the forearm just above the wrist due to the posterior displacement of the hand. This is the most frequent forearm fracture and is a common injury in persons over the age of 50, particularly in older women with osteoporosis. It also commonly occurs following a high-speed fall onto the hand during activities such as snowboarding or skating.

The most commonly fractured carpal bone is the scaphoid, often resulting from a fall onto the hand. Deep pain at the lateral wrist may yield an initial diagnosis of a wrist sprain, but a radiograph taken several weeks after the injury, after tissue swelling has subsided, will reveal the fracture. Due to the poor blood supply to the scaphoid bone, healing will be slow and there is the danger of bone necrosis and subsequent degenerative joint disease of the wrist.

Following are some of the most common sports injuries.

Sprains and Strains

A sprain is a stretch or tear of a ligament, the band of connective tissues that joins the end of one bone with another. Sprains are caused by trauma such as a fall or blow to the body that knocks a joint out of position and, in the worst case, ruptures the supporting ligaments. Sprains can range from first degree (minimally stretched ligament) to third degree (a complete tear). Areas of the body most vulnerable to sprains are ankles, knees, and wrists.

A strain is a twist, pull, or tear of a muscle or tendon, a cord of tissue connecting muscle to bone. It is an acute, noncontact injury that results from overstretching or over-contraction. Although it’s hard to tell the difference between mild and moderate strains, severe strains not treated professionally can cause damage and loss of function.

Knee Injuries

The knee is a complex structure and is weight bearing and can be a commonly injured joint. Knee injuries can range from mild to severe. Some of the less severe injuries to the knee can include:

• Runner’s knee, which causes pain or tenderness close to or under the knee cap at the front or side of the knee.
• Iliotibial band syndrome, which causes pain on the outer side of the knee.
• Tendinitis, also called tendinosis, which shows degeneration within a tendon, usually where it joins the bone.

More severe injuries include bone bruises or damage to the cartilage or ligaments. There are two types of cartilage in the knee. One is the meniscus, a crescent-shaped disc that absorbs shock between the thigh (femur) and lower leg bones (tibia and fibula). The other is a surface-coating (or articular) cartilage. It covers the ends of the bones where they meet, allowing them to glide against one another. The four major ligaments that support the knee are the:

• Anterior cruciate ligament (ACL).
• Posterior cruciate ligament (PCL).
• Medial collateral ligament (MCL).
• Lateral collateral ligament (LCL).

Knee injuries can result from a blow to or twist of the knee; from improper landing after a jump; or from running too hard, too much, or without proper warmup.

Compartment Syndrome

In many parts of the body, muscles, along with the nerves and blood vessels that run alongside and through them, are enclosed in a “compartment” formed of a tough membrane called fascia. When muscles become swollen, they can fill the compartment to capacity, causing interference with nerves and blood vessels as well as damage to the muscles themselves. The resulting painful condition is referred to as compartment syndrome.

Compartment syndrome may be caused by:

• A one-time traumatic injury, also known as acute compartment syndrome, such as a fractured bone or a hard blow to the thigh.
• Repeated hard blows or by ongoing overuse, also known as chronic exertional compartment syndrome. For example long-distance running can lead to this syndrome.

Shin Splints

Although the term “shin splints” has been widely used to describe any sort of leg pain associated with exercise, the term actually refers to pain along the tibia or shin bone, the large bone in the front of the lower leg. This pain can occur at the front outside part of the lower leg, including the foot and ankle (anterior shin splints) or at the inner edge of the bone where it meets the calf muscles (medial shin splints).

Shin splints are primarily seen in runners, particularly those just starting a running program. Risk factors for shin splints include:

• Overuse or incorrect use of the lower leg.
• Improper stretching, warmup, or exercise technique.
• Overtraining.
• Running or jumping on hard surfaces.
• Running in shoes that don’t have enough support.

These injuries are often associated with flat (overpronated) feet.

Achilles Tendon Injuries

An Achilles tendon injury results from a stretch, tear, or irritation to the tendon connecting the calf muscle to the back of the heel. These injuries can be so sudden and agonizing that they have been known to bring down charging professional football players in shocking fashion.

The most common cause of Achilles tendon tears is a problem called tendinitis, a degenerative condition caused by aging or overuse. When a tendon is weakened, trauma can cause it to rupture.

Achilles tendon injuries are common in middle-aged “weekend warriors” who may not exercise regularly or take time to stretch properly before an activity. Among professional athletes, most Achilles injuries seem to occur in quick-acceleration, jumping sports like football and basketball, and almost always end the season’s competition for the athlete.

Fractures

A fracture is a break in the bone that can occur from either a quick, one-time injury to the bone, also known as an acute fracture, or from repeated stress to the bone over time, also known as a stress fracture.

Acute fractures can be:

• Simple, usually a clean break with little damage to the surrounding tissue.
• Compound, meaning a break in which the bone pierces the skin with little damage to the surrounding tissue.

Most acute fractures are emergencies. One that breaks the skin is especially dangerous because there is a high risk of infection.

Stress fractures occur largely in the feet and legs and are common in sports that require repetitive impact, primarily running or jumping sports such as gymnastics or track and field. Running creates forces two to three times a person’s body weight on the lower limbs.

The most common symptom of a stress fracture is pain at the site that worsens with weight-bearing activity. Tenderness and swelling often accompany the pain.

Dislocations

When the two bones that come together to form a joint become separated, the joint is described as dislocated. Contact sports such as football and basketball, as well as high-impact sports and sports that can result in excessive stretching or falling, cause most dislocations. A dislocated joint is an emergency that requires medical treatment.

The joints most likely to be dislocated are some of the hand joints. Aside from these joints, the joint most frequently dislocated is the shoulder. Dislocations of the knees, hips, and elbows are uncommon.

Introduction

Hamstring muscles comprise the three major muscles of the posterior aspect of the thigh. These include the semimembranous as the medial most, long and short heads of the biceps femoris as the lateral most, and semitendinosus in between. These groups of muscles are clinically significant as they are highly susceptible to injury, especially in the athletes. The semimembranosus and long head of the biceps femoris have a common origin on the posterolateral aspect of the ischial tuberosity while semitendinosus has an origin on the anterolateral part of the ischial tuberosity. The short head of biceps has origin medial to the linea aspera on the distal aspect of the posterior part of the femur. Both the long and short head of biceps femoris go on to insert over the head of the fibula while semimembranosus inserts over the medial condyle of the tibia. Semitendinosus inserts onto the pes anserine region on the medial part of the tibia. All the hamstring muscles traverse two joints (hip and knee) from origin to insertion except the short head of biceps femoris, which only traverses knee joint from its origin to insertion. The main function of the hamstring muscles is flexion at the knee joint and extension at the hip joint. Biceps femoris also helps in the external rotation of the hip while semimembranosus and semitendinosus help in the internal rotation of the hip joint.

Hamstring injuries mostly occur while players are running or sprinting. These groups of muscles are particularly susceptible to injury due to their anatomic arrangement. Also, their mechanism of action over two joints (knee and hip) that occur together with opposing effects on the hamstring length makes them vulnerable to injury. Also, their key role in deceleration while walking, running, and making acute changes in direction at high speed, makes them more prone to getting injured. Hamstrings bear the major strain during the phase of motion when they transition from decelerating the extension of the knee to extending the hip joint. During this rapid transition of functional biomechanics of these muscles, they are most vulnerable to injury.Besides this, dual nerve supply of two heads of biceps femoris leading to asynchronous stimulation as well as an anatomical variance of attachment of its two heads makes it more commonly injured hamstring.

Grading of Injury

• Grade 1: Mild pain or swelling, non-appreciable tissue disruption, no or minimal loss of function

• Grade 2: Identifiable partial disruption of tissue with moderate pain and swelling, leading to loss of function.

• Grade 3: Complete disruption or tear of the musculotendinous unit with severe pain and swelling and lack of function.

Cause

There have been some studies done to highlight the etiologies and risk factors associated with a hamstring injury. All the studies tend to suggest hamstring injury has a multifactorial etiology. Interaction among various risk factors is of paramount significance when considering the etiology of this type of muscle injury. A previous hamstring injury, older age, and peak quadriceps torque are strongly associated with the risk of a hamstring injury. Ethnicity, particularly African and Aboriginal origin and a higher level of competitiveness, have also been found to be associated with a higher incidence of a hamstring injury. Other risk factors like hamstring flexibility, the weight of the athlete, hip flexor, quadriceps flexibility, and hamstring peak torque need further study to be proven as potential risk factors.

A university study performed by eliminating the previous history of a hamstring strain concluded that high-speed running and maximum stretch of the hamstring during contact sports, hurdle jumping, falling, or dancing are associated with an increased risk of an injury.In a Union of European Football Associations (UEFA) study analyzing the risk of hamstring injury in professional soccer players, previous hamstring injury had a significant association with increasing the future hamstring injury while age didn't show significant association. Injury risk decreased in goalkeepers compared to the outfield players, injury decreased in away matches compared to the home matches, and more injury rates were seen during the regular season compared to the pre-season.

The British Medical Journal published an article with a prospective study done in 100 professional soccer players, which showed functional asymmetry of the muscles predisposed them to a higher risk of sustaining a hamstring injury. Also, the incidence of hamstring injury is, most of the time, sports specific as well. Sports that require rapid acceleration and deceleration like American football, soccer, Australian rule football had more incidence of a hamstring injury. More severe injuries have been found during kicking, while a higher incidence of injuries occurs during running.Likewise, high-intensity training sessions, a higher level of competitiveness,positions in play that demand more running (e.g., wide receiver in American football) are associated with more hamstring injuries.

Epidemiology

Studies showed hamstring injury peaks at 16 to 25 years of age. It is mostly related to sports where hamstrings bear the most burden, with a rapid transition of its functional biomechanics at high speed like sprinting, soccer, football, track and field sports. A 13-year study done by UEFA among the elite soccer clubs of Europe found an annual 2.3% year on year increase in hamstring injury during the study. In comparison to the training-related injuries, the study showed an overall 9 times higher rate of injuries during the matches. An FC Barcelona study done between July 2007 through June 2010 among its 1157 young athletes with an average age of 13.56 years found that injury was less prevalent in young athletes compared to the older ones. The average time lost from play was 21 days. In the case of avulsion from the ischium, the average days away from the play was 43.4 days.One NFL study done over 10 years showed more than 50% injury during the preseason with mostly in positions like defensive secondary and wide receivers that demand more speed. Even in contact sports, the non-contact mechanism of injury was more common than the contact.

History and Physical

When an athlete develops an acute posterior thigh pain during a game, which makes it difficult to return to play immediately, a hamstring injury should be suspected. Acute hamstring injuries have pain with weight-bearing and an abnormal stiff-legged gait as a result of avoiding hip and knee flexion. If there is an associated complete rupture from the ischial tuberosity, pain can be localized to the proximal thigh with point tenderness at the ischial tubercle. Patients often have difficulty sitting as a result of pain at the avulsion site. Usually, proximal injuries go hand in hand with the distal strain of semimembranosus, which might divert attention. Within a few days after the injury, patients usually notice the presence of ecchymosis over the buttocks and the posterior aspect of the thigh that may extend down into the leg. Some patients may present with posterior thigh dysesthesia. This clinical presentation is called gluteal sciatica. It is associated with compression of the sciatic nerve, mainly its posterior cutaneous branch. The compression could be either by a hematoma, scar tissue or retracted muscle stump. Patients with distal hamstring injuries can have a presentation similar to that of patients with proximal injuries. In addition, knee flexion could be compromised as well.

Physical examination, though an important part of the initial evaluation of hamstring injury, should not be relied upon completely to determine the exact nature of the injury due to the deep location of the hamstring muscles. Localized swelling in the posterior thigh with tenderness to palpation and induration in the posterior thigh along the hamstring muscle bellies are the common examination findings. Complete rupture may have a palpable defect within the muscle substance. At the time of physical examination, strength, and range of motion of the affected hamstring should be tested and compared with those on the unaffected side. Ideally, the patient should be prone, and hip positioned at 0° of extension; then, knee flexion is assessed with resistance applied at the heel, the knee being in 15°, and 90° of flexion. Pain or weakness appreciated during the examination is considered a positive finding. Hip flexion and knee extension should be examined, which may be limited by pain in patients with a hamstring injury.

Diagnosis

Radiographic evaluation is an important aspect of the assessment of suspected hamstring injury to determine the nature, extent, and severity of the injury. Plain radiographs are useful to rule out a bony fracture, especially the apophyseal fracture.Ultrasound and MRI are the diagnostic modalities of choice. Area of injury, as evidenced by edema and hemorrhage, is depicted by echotexture in ultrasound and high signal intensity in T2 weighted images in MRI.Ultrasound allows dynamic assessment of the injured hamstring muscles, but its sensitivity is increased if the ultrasound is done early after injury. MRI is still the investigation of choice to assess deeper muscle injuries, to evaluate a recurrent injury, and to differentiate new injury from the residual scarring. MR imaging also provides an estimate of the rehabilitation period.Though it can predict estimated time away from the sport, it cannot identify the risks for reinjury, which needs further study.

Treatment / Management

An evidence-based approach to injury management does not exist. Management is guided based on clinical experience, anecdotal evidence, and knowledge of the biological basis of tissue repair.Proximal injuries are more common and manifest from strain to complete tear.

Grades I and II strains are generally managed nonoperatively with rest, ice packs, relative immobilization, and pain and inflammation management with NSAIDs and analgesics. This is followed by progressive stretching and strengthening.NSAIDs are given for no more than 5 to 7 days, and glucocorticoids are not recommended.Platelet-rich plasma (PRP) and other growth factors do not have enough evidence to prove their use. None of these growth factors meet the World Anti-Doping Agency (WADA) set guidelines, mainly because of the IGF-1 content of such preparations. In the first 3 to 5 days, the goal should be to control hemorrhage, edema, and pain. After this, progressive ambulation assisted with crutches is initiated until pain-free walking is possible. Posture control mechanisms and pelvic alignment should be considered when managing hamstring injuries.

For grade III, there is a belief to go for nonsurgical treatment for isolated single tendon avulsion injury with less than 2 cm of retraction. Literature review shows nonsurgical treatment for complete tendon rupture with retraction results in an unsatisfactory outcome, including the inability to resume active lifestyle/sports, chronic knee flexion weakness, mild hip extension weakness, sciatic neuralgia, pain with sitting down and deformity. Hence, for grade III injury, surgery is recommended. Acute repair is generally preferred vs. the delayed one due to the risk of scarring of the stump to the sciatic nerve. The ideal time for surgical repair is believed to be 4 to 6 weeks post-injury. There is no proven benefit of other modalities of treatment like the therapeutic ultrasound, therapeutic laser, electric stimulation, massage, and extracorporeal shock wave (ECSW) treatment.

Differential Diagnosis

Proximal Thigh

• Lumbosacral facet syndrome

• Chronic gluteal sciatic pain (hamstring syndrome)

• Lumbosacral radiculopathy

• Piriformis syndrome

• Sacroiliac joint injury

• Lumbosacral discogenic pain syndrome

• Sciatic nerve compression by inferior or superior gluteal artery aneurysm

Distal Thigh

• Deep vein thrombosis

• Baker cyst rupture

• Knee meniscus injury

• Proximal gastrocnemius injury

• Popliteus injury

Prognosis

Clinical assessment, as well as imaging studies, help to outline the factors involved in the prognosis of a hamstring injury. Patients with a grade I and II injuries or a negative MRI study, an ability to walk pain-free within 24 hours of an injury, or short muscle tear tend to have a good prognosis in recovering from the injury as demonstrated by less time to return to play. On the other hand, Grade III injury in MRI, hamstring injuries with an avulsion fracture of bones, proximal tendon injuries, injury with large and deep hematoma tend to incline towards a poor outcome from the injury and longer recovery time. An injury sustained from low-speed stretching movements has a poorer prognosis compared to the injury sustained during high-speed activities.

Complications

• Chronic hamstring pain and injury associated with too early return to play

• Reinjury related to areas of calcification and inflammation in hamstring after injury

• Hamstring syndrome - Scar formation and impingement on the sciatic nerve

Postoperative and Rehabilitation Care

The rehab process is an important aspect of the management of hamstring injury and plays a crucial role in making the transition back to the sport. A rehabilitation program that encompasses progressive agility and stabilization of the trunk exercises are more effective than a program emphasizing the isolated hamstring muscle.A Swedish study found that a rehabilitation protocol emphasizing lengthening type of exercises is more effective than a protocol containing conventional exercises in promoting the time to return to sports.

A systematic review found that to speed up the process, consideration should also be given to the lumbar spine, sacroiliac, and pelvic alignment as well as posture control mechanisms. Lengthening hamstring exercises showed the fastest return to play with a lower reinjury rate compared to the conventional hamstring exercises. Treating with PRP after the injury had no proven effect on time to return to play and reinjury risk. It is important to ensure the return of normal flexibility and endurance before the patient returns to play as reinjury is common due to lack of both. Also, when the injured hamstring has 90% strength compared to that of the unaffected one and a 50% to 60% hamstring-quadriceps ratio, the athlete should return to play.

Proximal injuries involving the semimembranosus and its proximal free tendon were associated with prolonged recovery time.A systematic review found the factors associated with the prolonged recovery time. These were stretching type injuries, recreational type sports, a greater range of motion deficit with the hip flexed at 90°, time to the first consultation less than one week, increased pain on the visual analog scale, and less than one day to be able to walk pain-free after the injury. A rehabilitation program that comprises loading hamstring during extensive lengthening showed evidence of an early return to sport. Besides that, 4 different sessions every day of static hamstring stretching also showed promising results in decreasing time to return to play.

Deterrence and Patient Education

Hamstring injury is one of the most common sports-related injuries in the competitive realm of professional sports. It is also one injury that keeps an athlete out of action for a long time and requires proper rehabilitation before returning to play. Multiple recurrences could complicate the process of rehabilitation. In athletes who are in sports involving running and sprinting as well as non-athletes like dancers, hamstring injury should be considered if they experience acute, sharp posterior thigh pain that restricts further participation in sports unless it is clinically or radiologically ruled out with certainty. It is also important to discuss with the patients about the possible length of time away from the sport. They should also be counseled about the need for surgery in severe injuries and the importance of rehabilitation and physical therapy before returning to play.

Enhancing Healthcare Team Outcomes

Managing the patient of hamstring injury requires proper communication and understanding of responsibilities on the part of the team involved in the management. This includes the primary provider, orthopedic surgeons, radiologist, nursing staff, pharmacist, physical and occupational therapist, and, most importantly, the patients themselves. Good coordination of care is required for proper recovery and also preventing reinjuries. If a patient comes with pain on the back of the thigh while running, sprinting, or stretching, which prevents further continuation of the activity, they should be evaluated for an acute hamstring injury. Radiologists have a key role in determining the size, nature, and extent of the injury, which will be crucial in further management of the injury. These patients should be evaluated by either sports medicine or Orthopedics to determine the need for surgical management.

Early surgical intervention gives better results than the late interventions, especially in the complete proximal avulsions of the hamstring muscle. Generally, complete (grade III) proximal injuries and grade II and III distal hamstring injuries would require surgical repair for a better outcome. Results are promising from surgical repair of proximal injuries even after the non-operative method has been tried initially and has failed.

An orthopedics consultation is of paramount significance to have a better outcome after the injury as early operative treatment gives promising results. The nursing staffs have a key role too in both non-surgical as well as surgical management. The physician assistant, nurse practitioner, if they are seeing a patient with a hamstring injury, should be able to determine when to refer to orthopedics or sports medicine and the need for operative vs. non-operative management. After proper surgical or non-surgical management, physical and occupational therapists have a crucial role in the rehabilitation, strength training, and speeding up the return to play. Studies have generally shown there is 87% strength return after 6 to 12 months post-surgery, while about 98% strength returns after more than 12 months of surgery. The athletes should also follow the guidelines and comply with the instruction of the team involved in the care and not rush to return to play.

Dislocation of the TMJ may occur when opening the mouth too wide (such as when taking a large bite) or following a blow to the jaw, resulting in the mandibular condyle moving beyond (anterior to) the articular tubercle. In this case, the individual would not be able to close his or her mouth. Temporomandibular joint disorder is a painful condition that may arise due to arthritis, wearing of the articular cartilage covering the bony surfaces of the joint, muscle fatigue from overuse or grinding of the teeth, damage to the articular disc within the joint, or jaw injury. Temporomandibular joint disorders can also cause headache, difficulty chewing, or even the inability to move the jaw (lock jaw). Pharmacologic agents for pain or other therapies, including bite guards, are used as treatments.

Figure 9.15 Temporomandibular Joint The temporomandibular joint is the articulation between the temporal bone of the skull and the condyle of the mandible, with an articular disc located between these bones. During depression of the mandible (opening of the mouth), the mandibular condyle moves both forward and hinges downward as it travels from the mandibular fossa onto the articular tubercle.