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Imaging & Diagnostics

Back Clinic Imaging & Diagnostics Team. Dr. Alex Jimenez works with top-rated diagnosticians and imaging specialists. In our association, imaging specialists provide fast, courteous, and top-quality results. In collaboration with our offices, we provide the quality of service our patients’ mandate and deserve. Diagnostic Outpatient Imaging (DOI) is a state-of-the-art Radiology center in El Paso, TX. It is the only center of its kind in El Paso, owned and operated by a Radiologist.

This means when you come to DOI for a radiologic exam, every detail, from the design of the rooms, the choice of the equipment, the hand-picked technologists, and the software which runs the office, is carefully chosen or designed by the Radiologist and not by an accountant. Our market niche is one center of excellence. Our values related to patient care are: We believe in treating patients the way we would treat our family and we will do our best to ensure that you have a good experience at our clinic.


The Knee

The Knee

The Knee | MRI may be requested for:

  • Ligament injuries
  • Meniscal tears and degeneration
  • Rheumatoid arthritis
  • Osteochondral fractures
  • Tendon disruptions

Bones & Cartilage Of The Knee

The knee joint is the largest, most complicated, and most vulnerable joint in the body, as it does not have a stable bony configuration. It consists of the tibiofemoral and patellofemoral articulations, which include the femur, tibia, and patella. The knee is a synovial joint that is enclosed by a ligament capsule. The capsule contains synovial fluid that keeps the joint lubricated (Figure 82). The knee provides flexible movement, but must also bear large weight and pressure loads. During walking, the knees support 1.5 times your body weight. When climbing stairs, they support 3-4 times your body weight. When squatting, your knees support 8 times your body weight.

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Figure 82. Anatomy of the knee.

The tibiofemoral articulation is a modified hinge joint that allows bending and straightening, but also allows for slight rotation. This articulation consists of the lateral and medial condyles of the femur resting on the lateral and medial aspects of the tibial plateau. The femoral condyles make up the distal portion of the femur, which is expanded in order to assist with weight distribution at the knee joint. The medial femoral condyle is typically larger and rounder. The condyles are united anteriorly to provide the articular surface for the patella, but they are separated posteriorly by the intercondylar notch. This notch, or fossa, is the attachment site for the cruciate ligaments, the ligaments of Humphrey and Wrisberg, and the frenulum of the patellar fat pad. A large part of the posterior distal femur is called the popliteal surface. This area is covered by fat, which separates it from the popliteal artery. The medial and lateral edges of the popliteal surface are attachment sites for muscles. Superior to the femoral condyles are the epicondyles, which are the attachment sites for muscles, tendons, and capsular ligaments. The medial epicondyle is the attachment site for the medial (or tibial) collateral ligament (Figure 83). The lateral femoral epicondyle is the attachment site for the lateral (or fibular) collateral ligament, as well as the tendon of the popliteus muscle, fibers of the iliotibial tract, and the lateral capsular ligament. Superior and posterior to the epicondyles is the most distal extent of the linea aspera, the bony ridge of the femur.

The tibia is the distal portion of the tibiofemoral articulation at the knee. The tibia is the second longest bone in the body, ranked just behind the femur. Its proximal end is flattened and expanded to provide a larger surface for the body weight that is transmitted through the femur. Like the femur, the proximal tibia has medial and lateral condyles. The medial condyle is larger, and somewhat flattened where it contacts the medial meniscus. The lateral condyle has a circular look to its femoral articular surface. The lateral tibial condyle articulates with the head of the fibula posteriorly, which is as close as the fibula comes to any involvement in the knee joint. Both the medial and lateral condyles rise in the center of the superior aspect of the tibia to form the intercondylar eminence. Posterior to this eminence are the attachments sites for the posterior horns of the medial and lateral menisci, which will be discussed with the ligaments of the knee. The medial and lateral tibial condyles, and the area of the intercondylar eminence are often grouped together and referred to as the tibial plateau (Figure 84). This is a critical weight-bearing area, and greatly affects the stability of the knee joint. The tibial tuberosity (or tubercle) is located on the anterior surface of the proximal tibial shaft. It has a smooth upper portion, and a roughened lower portion, which is the insertion site for the patellar tendon. The lateral side of the tibial tuberosity has a ridge for the attachment of fibers from the iliotibial tract. This is the strongest direct attachment site for the iliotibial tract. The IT tract, or band, helps in limiting lateral movement of the knee.

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Figure 84. Tibial plateau.

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Figure 83. Tibiofemoral anatomy.

 

 

 

 

 

 

 

 

 

 

The patella is the third bone involved in the knee joint, specifically in the patellofemoral articulation. Patella means �little plate� in Latin, which describes the look and function of this sesamoid bone. The patella develops in the tendon of the quadriceps femoris muscle (Figure 85). It moves when the leg moves, and protects the knee joint by relieving friction between the bones and muscles when the knee is bent or straightened. The patellofemoral joint is a saddle-type synovial joint, allowing the patella to glide along the bottom front surface of the femur between the femoral condyles in the patellofemoral groove. Ossification of the patella is typically completed in females by age 10, and in males between the ages of 13-16. If the patella has more than one ossification center, and the additional center does not fuse, it is termed a bipartite patella (Figure 86).

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Figure 86. Bipartite patella.

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Figure 85. Patella location.

 

 

 

 

 

 

 

 

 

 

 

Articular, or hyaline, cartilage covers the ends of the bones involved in any joint. In the knee joint, this includes the distal end of the femur, the proximal end of the tibia, and the posterior aspect of the patella (Figure 87). In larger joints, this cartilage is approximately �� thick. Articular cartilage is white, shiny, rubbery, and slippery, enabling surfaces to slide against one another without damage. Articular cartilage is very flexible, due in part to its high water content, which also makes it highly visible on MRI. In contrast to the bones that it covers, articular cartilage has almost no blood vessels, so it is not good at repairing itself. Bones, on the other hand, have numerous blood vessels, and are good at self-repair.

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Figure 87. Articular cartilage.

Another type of cartilage is found between the femur and tibia- the fibrous cartilage that makes up the medial and lateral menisci. The menisci, also referred to as �articular disks�, wrap around the round ends of the femur to fill the space between the femur and tibia (Figure 88). Since the menisci are more fibrous in composition, they have tensile strength and can resist pressure. They can help spread the force from our body weight over a larger area. By helping with weight distribution, the menisci protect the articular cartilage on the ends of the bones from excessive forces. The menisci are fashioned to be thicker on their outsides, creating a shallow socket on the tibial surface. They act like a wedge on the rounded distal portion of the femur, improving the overall stability of the knee joint by preventing any �rolling� of the femur. Despite how strong they sound, the menisci can crack or tear when the knee is forcefully rotated or bent. The medial meniscus is fused with the medial collateral ligament, so it is less mobile than the lateral meniscus. It is often injured when the anterior or posterior cruciate ligaments are injured. The inner 2/3 of the medial meniscus receives a limited blood supply, so the entire meniscus is usually slow to heal. The lateral meniscus suffers from fewer injuries than the medial meniscus. Meniscal tears are one of the most common causes of knee pain, with suspected meniscal tears the most common indication for an MRI of the knee joint.

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Figure 88. Superior view of menisci of right knee.

Symptoms that might indicate a problem with the bones of the knee joint include locking of the joint, the knee giving way, crackling or grinding felt in the joint, and pain and swelling. Locking of the joint can be indicative of a �loose body� (bone, cartilage, or foreign object) in the joint space, which can often be removed through arthroscopy (Figure 89). A knee that gives way can indicate that the patella is out of the patellofemoral groove, which leaves the knee unstable. Crackling and grinding at the joint can result from degenerative arthritis or osteoarthritis, as well as from a dislocating patella. An increase in pain with activity can occur due to a stress fracture or bone fracture. One of the pathologic conditions that can affect the bones of the knee joint is osteochondritis dissecans, which can affect the distal femur, and was discussed previously with the femur anatomy. Various types of arthritis manifest in the bones of the knee joint, including osteoarthritis, infectious arthritis, and rheumatoid arthritis. Chondromalacia patella, also known as patellofemoral syndrome or �runner�s knee� results from an irritation of the undersurface of the patella (Figure 91). If the patella is not tracking correctly in the patellofemoral groove, the articular cartilage may rub against the knee joint (Figure 90). The cartilage degenerates, and becomes irritated and painful. This condition is most common amongst young, healthy athletes, especially females and runners that are flat-footed. Treatment is typically rest and physical therapy to stretch and strengthen the quads and hamstrings. If surgery is required, it may be to perform a �lateral release�, as the abnormal tracking of the patella can cause a tightening of the lateral tissues of the knee. The lateral release procedure cuts the tight tissues, so the patella can return to its normal position and tracking. Osgood-Schlatter disease involves the anteriorly located tibial tuberosity, and the patellar tendon that inserts on that tuberosity (Figures 92, 93). This condition affects children during their growth spurts, and is typically found more in boys. During growth spurts, contractions of the quad muscle put additional stress on the patellar tendon at its attachment site on the tibial tuberosity. This can result in multiple subacute avulsion fractures and inflammation of the tendon. Excess bone growth occurs on the tuberosity, and a lump on the tuberosity can be seen and felt. This lump can become irritated and swollen, causing knee and leg pain. This condition is typically worsened with running, jumping, and climbing stairs. Osgood-Schlatter usually resolves with rest, ice, compression and elevation, as well as maturity of the youngster�s skeleton.

Figure 89. Intraarticular loose body.

 

Figure 90. Patellofemoral groove.

Figure 91. Patellofemoral syndrome or �runner�s knee�.

 

 

 

 

 

 

 

 

Figure 92. Xray displaying Osgood-Schlatter disease.

 

Figure 93. MRI displaying Osgood- Schlatter disease.

 

Ligaments Of The Knee

Ligaments are the tough bands of tissue that connect bones. They are considered to be �viscoelastic�, meaning they can gradually lengthen under tension, but return to their original shape when the tension is removed. However, if they are stretched for a prolonged period of time, or past a certain point, the ligaments cannot retain their original shape, and may eventually tear or snap. This is one of the reasons that a dislocated joint should be re-located as quickly as possible. If the ligaments lengthen, they leave the joint weakened and prone to future dislocations. Controlled stretching exercises to lengthen ligaments, and make the joints more supple, are part of the daily routines of athletes, gymnasts, dancers, etc. Damaged ligaments can lead to unstable joints, wearing of the cartilage, and eventually osteoarthritis. The numerous ligaments of the knee joint are the most important structures in controlling stability of the knee. Many of these ligaments were mentioned in the femur anatomy section, as they have attachments on the distal femur. The more important ligaments will be reviewed here in greater detail, in regards to their functions in the knee joint. The main intracapsular ligaments are the anterior and posterior cruciates (Figures 94, 95). Intracapsular ligaments are not very common in synovial joints. They provide stability, but permit a larger range of motion as compared to capsular or extracapsular ligaments. The anterior cruciate ligament (ACL) stretches from the lateral femoral condyle to the anterior intercondylar area of the tibia, preventing the tibia from being pushed too far anterior relative to the femur. It is the more commonly injured of the cruciate ligaments, and can be torn during twisting and bending of the knee. Women are at higher risk for ACL ruptures due to the facts that the maximum diameter of the intercondylar fossa is in its posterior aspect (the ACL attaches anteriorly), and the overall width of the intercondylar fossa is smaller in females. The posterior cruciate ligament (PCL) stretches from the medial femoral condyle to the posterior intercondylar area of the tibia, preventing posterior displacement of the tibia relative to the femur. It is the stronger of the two cruciate ligaments, and is injured less frequently; however, it can be injured from direct force or trauma. The menisci are also considered to be intracapsular structures, with connections to ligaments inside and outside the joint capsule. Two of their intracapsular ligaments are the anterior and posterior transverse meniscomeniscal ligaments. They attach the medial and lateral menisci to each other at their anterior and posterior aspects. Posterior transverse meniscal ligaments are very rare- only 1-4% of knees will have them. Two additional intermeniscal ligaments are the medial and lateral oblique meniscomeniscal ligaments (Figure 96). Their names describe their anterior horn attachment sites; they attach on the posterior horn of the opposite meniscus (i.e. medial oblique meniscomeniscal attaches to the anterior horn of the medial meniscus and posterior horn of the lateral meniscus). The oblique meniscomeniscal ligaments both traverse the intercondylar notch, and pass between the anterior and posterior cruciate ligaments (Figure 97).

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Figure 94. Cruciate ligaments and menisci.

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Figure 95. Posterior view of cruciate ligaments of left knee.

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Figure 96. Axial fatsat T2 FSE image with arrow indicating
oblique meniscal ligament coursing from anterior horn of
medial meniscus to posterior horn of lateral meniscus.

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Figure 97. Sagittal dual-echo T2 through the intercondylar notch at the level of the posterior cruciate ligament (curved arrow); thin linear structure of low signal intensity inferior to PCL represents the oblique meniscomeniscal ligament (straight arrow); sometimes misinterpreted as displaced meniscal fragment.

 

The medial (or tibial) collateral ligament is considered a capsular ligament, as it is part of the articular capsule surrounding the synovial knee joint. It acts as mechanical reinforcement for the joint, protecting the knee from valgus force, or being bent open medially due to stress on the lateral side of the knee. The medial collateral ligament (MCL) is one of the most commonly injured of all knee ligaments, occurring in all sports, in all ages, and often times with medial meniscal tears (Figures 98-101). It has both superficial and deep components. Fibers from the superficial portion of the MCL attach to the medial epicondyle of the femur and the medial tibial condyle. Fibers from the deep medial collateral ligament attach to the medial meniscus. Proximal to the attachment point, this ligament is referred to as the meniscofemoral ligament, as it attaches the medial meniscus to the medial aspect of the femur. Distal to the meniscal attachment, the ligament is referred to as the meniscotibial (or coronary) ligament, as it attaches the medial meniscus to the medial aspect of the tibia. The meniscofemoral and meniscotibial are also referred to as the meniscocapsular or medial capsular ligaments, as they play an important role in anchoring peripheral parts of the medial meniscus in the medial side of the knee. The meniscotibial ligament is typically injured more often than the meniscofemoral ligament. The meniscotibial ligament attaches to the tibia several millimeters inferior to the articular cartilage. Its job is to stabilize and maintain the meniscus in its proper position on the tibial plateau. Disruption of the meniscotibial ligament can result in a floating meniscus or meniscal avulsion, while the meniscofemoral ligament may not be affected. The deep medial collateral ligament is short, and tightens quickly with rotation motions. It is often damaged, along with the ACL, when the mechanism of injury involves tibial rotation. Diagnosis and surgical repair of the deep medial collateral ligament can be challenging.

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Figure 98. Normal MCL is linear,
has low signal intensity.

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Figure 99. Grade 1 sprain shows adjacent edema, no change in signal intensity of MCL.

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Figure 100. Grade 2 sprain or partial tear shows increased edema,
abnormal signal intensity,
thickening or thinning of ligament.

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Figure 101. Grade 3 involves complete disruption of ligaments or attachments.

 

In addition to fibers of the medial collateral ligament, the deep portion of the capsular compartment of the medial knee is the location of the medial knee�s posterior support. The posterior oblique ligament is attached proximally to the medially located adductor tubercle of the femur, and distally to the tibia and the posterior aspect of the knee joint capsule. If the posterior oblique is injured, it is usually torn from its femoral origin. The posterior oblique ligament provides static resistance to valgus loads as the knee moves into full extension, as well as dynamic stabilization to valgus forces (stress from lateral side) as the knee moves into flexion. It acts as an important restraint to posterior tibial translation in cases of posterior cruciate ligament injury. The posterior oblique ligament has three �arms�. Its superior capsular �arm� becomes continuous with the posterior knee capsule, and the proximal portion of the oblique popliteal ligament. The oblique popliteal ligament is also an important posterior stabilizing structure for the knee joint Figure 102). It extends from the posteromedial aspect of the tibia, running obliquely and laterally upward to insert near the lateral epicondyle of the femur.

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Figure 102. Oblique popliteal ligament in posterior view of knee.

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Figure 103. Medial (tibial) and lateral (fibular) collateral ligaments.

 

The lateral (or fibular) collateral ligament is considered an extracapsular ligament. It helps to provide joint stability and protects the lateral side of the knee from varus forces, or inside bending forces that are directed at the medial side of the knee. Injuries to the lateral collateral ligament are less common than injuries to the medial collateral, as the opposite leg can guard against medial forces that can lead to lateral collateral injuries. Injuries can occur in sports such as soccer and rugby, where the knee is extended and unprotected during running. The lateral, or fibular, collateral ligament stretches obliquely downward and backward, from the lateral epicondyle of the femur to the head of the fibula (Figure 103). It is not fused with the capsular ligament or with the lateral meniscus, so it has increased flexibility and decreased incidence of injury when compared to the medial collateral ligament. Similar to the medial meniscus, the lateral meniscus has a meniscotibial, or coronary, ligament. It connects the inferior edges of the lateral meniscus to the periphery of the tibial plateau. The lateral meniscus also has a meniscofemoral ligament that extends from the posterior horn of the lateral meniscus to the lateral aspect of the medial femoral condyle. It is given two distinct names, based on its location in relation to the posterior cruciate ligament (PCL). The ligament of Humphrey passes in front of the posterior cruciate ligament. It is less than 1/3 the diameter of the posterior cruciate ligament, but may be confused for the posterior cruciate during arthroscopy. The ligament of Wrisberg passes behind the posterior cruciate ligament, and is about � of the posterior cruciate�s diameter (Figure 104). Its femoral origin often merges with the posterior cruciate ligament. Both ligaments are present in only about 6% of knees. Approximately 70% of people have one or the other of these ligaments, with the majority possessing the more posterior ligament of Wrisberg (Figure 105). MRI is the preferred imaging modality for medial collateral or lateral collateral ligament injuries, as it can detect any associated internal knee derangements, cruciate-collateral ligament injuries, or cartilage deficiencies.

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Figure 104. Rendering of posterior knee, arrow indicates Ligament of Wrisberg; courses obliquely from lateral aspect of medial femoral condyle to posterior horn of lateral meniscus,
remains posterior to PCL.

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Figure 105. Arrow indicates �Wrisberg pseudo-tear�; intermediate signal
intensity line at junction of
Ligament of Wrisberg and normal posterior horn of lateral meniscus; often mistaken for a meniscal tear.

The patellar ligament is the connection between the patella and the tibia, extending from the apex (inferior aspect) of the patella to the tibial tuberosity. Technically, it is connecting two bones, so it is a ligament. However, it is most often referred to as the patellar tendon, because the superficial fibers that cover the front of the patella and extend to the tibia are continuous with the central portion of the common tendon of the quadriceps femoris muscle. The posterior surface of the patellar ligament is separated from the synovial membrane of the knee joint by a large infrapatellar pad of fat. Injuries to the patellar ligament can occur from overuse, such as sports that involve jumping and quick directional changes, as well as running-related sports. This is the ligament that is injured in jumper�s knee (or patellar tendonitis), which begins with inflammation, and can lead to degeneration or rupture of the patellar ligament and the tissue around it (Figure 106). Patients with patellar ligament injuries typically complain of pain in the area below the kneecap, which will increase with walking, running, squatting, etc. They can often be treated in the same manner as other soft tissue injuries- with rest, ice, compression and elevation. The patellar ligament attachment at the tibial tuberosity is the site of Osgood-Schlatter disease, which was discussed previously.

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Figure 106. Patellar tendonitis (jumper�s knee).

Along the sides of the patella and the patellar ligament are the medial and lateral patellar retinacula (Figure 107). They are fibrous tissue stabilizers for the patella that form from the medial and lateral portions of the quad tendons as they pass down to insert on either side of the tibial tuberosity. The lateral retinaculum is the thicker of the two, but both have superficial and deep layers. Within the deep layers are various ligaments (whose names indicate the structures they connect) that help support the patella in its position, relative to the femur below it. The deep layer of the lateral patellar retinaculum is the location where the lateral patellofemoral ligament meets the iliopatellar band, which is a tract of fibers from the iliotibial (IT) band that connects to the patella. The deep layer of the medial patellar retinaculum has three focal capsular thickenings, referred to as the medial patellofemoral, medial patellomeniscal, and medial patellotibial ligaments. The medial patellofemoral ligament is strong enough to influence patellar tracking, and acts as a major medial restraint. Imbalances in the forces that control patellar tracking during flexion and extension of the knee can lead to patellofemoral pain syndrome (runner�s knee), one of the most common causes of knee pain. This can result from overuse, trauma, muscle dysfunction, patellar hypermobility, and poor quadriceps flexibility. Typical symptoms include pain behind or around the patella that is increased with running, and activities that involve knee flexion. MRI is typically not necessary for this diagnosis. Physical therapy has been found to be effective for the treatment of patellofemoral pain syndrome.

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Figure 107. Lateral and medial retinaculum.

Muscles & Tendons Of The Knee

The flexor and extensor muscles of the knee have been discussed previously, as the majority of them are the anterior and posterior muscles of the thigh. We will review the thigh muscles involved in knee movement, and add two muscles of the lower leg that also affect the knee. The quadriceps femoris muscles of the anterior thigh are the main knee extensors (Figure 108). As these muscles contract, the knee joint straightens. The tendons of the vastus medialis, vastus intermedius, vastus lateralis, and rectus femoris join at the superior aspect (base) of the patella to form the patellar tendon. This tendon continues over the patella and attaches it to the tibial tuberosity (since it is connecting bone to bone, it is sometimes called the patellar ligament). The quadriceps, along with the gluteal muscles, are responsible for the thrusting forces necessary for walking, running, and jumping. The quads also help control movement of the patella, as they are attached to it by the quadriceps tendons (Figure 109). The patella increases the force exerted by the quadriceps muscles as the knee is straightened.

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Figure 108. Anterior thigh muscles – knee extensors.

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Figure 109. Quadriceps controlling the patella.

 

 

 

 

 

 

 

 

 

 

 

 

 

The posterior thigh muscles, also known as the hamstrings, are the main knee flexors, with assistance from the sartorius, gracilis, gastrocnemius, and popliteus muscles. The knee bends when the hamstrings contract. The hamstring muscles give the knee joint the strength needed for propulsion in running and jumping. They also help to stabilize the knee by protecting the collateral and cruciate ligaments, especially when the knee twists. The three hamstring muscles have varying attachment sites around the knee joint (Figure 110). The biceps femoris attaches to the head of the fibula and the superolateral aspect of the tibia. The semitendinosus attaches on the anterior aspect of the tibia, medial to the tibial tuberosity, crossing over the medial collateral ligament. The tendon of the semitendinosus muscle is sometimes used for cruciate ligament reconstruction. The semimembranosus attaches at the posteriomedial aspect of the medial tibial condyle. The sartorius muscle is also a knee flexor, although it is an anterior thigh muscle. It inserts on the anterior medical aspect of the tibia. The gracilis muscle of the medial thigh is one of the hip adductors, but also plays a part in knee flexion. Like the semitendinosus tendon, the tendon of the gracilis is sometimes used for cruciate ligament reconstructions. The gracilis attaches to the medial aspect of the proximal tibia.

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Figure 110. Posterior knee
muscles – knee flexors.

Additional flexors of the knee joint include some of the posterior muscles of the lower leg. The large superficial gastrocnemius muscle has a medial and a lateral head, which originate from the medial and lateral femoral condyles, respectively. It runs the length of the posterior lower leg, attaching to the calcaneus by the Achilles tendon. The gastrocnemius gives us the ability to flex our knee while our foot is flexed, as it connects to both joints. It is involved in standing, walking, running, and jumping. The popliteus is a deep posterior lower leg muscle that helps with knee flexion, and also rotates the tibia medially, which aids in knee stability. The popliteus originates from the outer margin of the lateral meniscus of the knee joint. It extends posteriorly and inserts on the medial aspect of the tibia, inferior to the medial tibial epicondyle.

The important tendons of the knee include the quadriceps, patellar, and hamstring tendons, and the iliotibial band (Figure 111). Tendons attach muscles to bones. These major knee tendons have all been discussed with either the bones or the muscles that they attach. The quadriceps tendon was mentioned with the quadriceps muscle as the muscle�s attachment to the patella. The quad tendon continues over the patella, then attaches the apex of the patella to the tibial tuberosity. It is then called the patellar tendon (or ligament). Hamstring tendons were discussed with the hamstring muscles, the posterior muscles that are flexors of the knee. Hamstring tendons are sometimes used for cruciate ligament reconstructions. Tendonitis, which is the inflammation of a tendon, is a common knee injury amongst athletes in a variety of sports. The iliotibial band (or IT tract) functions like a tendon, as it attaches the knee to the tensor fasciae latte muscle. The band is actually a fibrous reinforcement of the fascia lata, or deep tissue of the thigh. It runs from the ilium to the tibia. Proximally, it acts as a hip abductor, while distally it acts as lateral stabilization for the knee, and aids with medial rotation of the tibia. The IT band is in constant use during walking and running, which can lead to irritation at the point where it passes over the lateral femoral epicondyle. A �tight� IT band can cause inflammation and/or irritation at the femoral epicondyle, or at the point of insertion on the lateral tibial condyle. This condition is called IT band friction syndrome. It is common amongst runners, hikers, and cycling enthusiasts.

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Figure 111. Tendons of the knee.

Nerves Of The Knee

The main nerves to the knee that come from the sacral plexus of nerves are the tibial nerve and the common peroneal nerve (Figure 112). Both are branches of the sciatic nerve, and begin posteriorly, slightly above the actual knee joint. Both of these nerves, or their branches, continue through the lower leg and foot, providing sensation and muscle control. The tibial and common peroneal nerves are also both involved in cutaneous innervation, which is the supply of nerves to the skin of the knee. The tibial nerve remains posterior and more medial, branching at the medial ankle to innervate the foot. The common peroneal nerve begins posterolaterally, moving anteriorly near the neck of the fibula. It then branches into the superficial and deep peroneal nerves, which continue their anterior descent to the foot. The tibial and common peroneal nerves are the most commonly injured nerves when a knee is dislocated. Nerves can grow back, but they do so at a rate of approximately � inch per month.

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Figure 112. Sacral plexus nerves of knee.

Nerves from the lumbar plexus that affect the knee include the lateral femoral cutaneous, and the saphenous, which is a branch of the femoral nerve (Figure 113). The saphenous nerve travels more medially and gives off infrapatellar branches around the knee joint. Below the knee, the saphenous nerve sends branches to the skin of the anterior and medial lower leg. The lateral femoral cutaneous nerve sends an anterior branch to the skin of the anterior and lateral thigh, down to the area of the knee. Terminal filaments of this nerve communicate with the infrapatellar branch of the saphenous nerve, forming the peripatellar plexus.

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Figure 113. Lumbar plexus nerves of knee.

Arteries & Veins Of The Knee

The popliteal artery, a branch of the superficial femoral artery, is the main arterial supply to the knee joint. It runs along the posterior aspect of the distal femur, behind the knee joint. At the supracondylar ridge, the popliteal artery gives off the blood supply to the knee, which consists of various genicular arteries (Figure 114). Inferior to the knee joint, the popliteal branches into the anterior and posterior tibial arteries, which supply the lower leg. The popliteal artery is a common site for both atherosclerosis and aneurysms, and is listed as the most common site for peripheral arterial aneurysms. Approximately 50% of these aneurysms are bilateral. Although they rarely rupture, popliteal aneurysms may serve as a focus for abrupt thrombotic occlusion of the involved popliteal artery, which can affect the foot on the same side. A thrombus within an aneurysm can also lead to a distal embolism. The genicular arteries are sources of continued blood flow to the knee and lower limb, in case of an obstructed popliteal artery. The descending genicular, also called the highest or supreme genicular, branches from the femoral artery, just superior to the popliteal branch. It supplies the adductor magnus and hamstring muscles, then joins with the network of genicular arteries around the knee joint. The middle genicular pierces the oblique popliteal ligament, and supplies the ligaments and synovial membrane inside the knee articulation (including the ACL and PCL). The sural artery joins the anastomoses of the genicular arteries, and also supplies muscles of the lower leg, including the large gastrocnemius muscle. The anastomotic pattern around the knee joint is supplied by the popliteal artery posteriorly, the descending genicular artery medially, and the descending branch of the lateral circumflex femoral artery laterally. The genicular arteries involved in the anastomosis are labeled as the medial and lateral superior geniculars, and the medial and lateral inferior geniculars.

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Figure 114. Arteries of knee.

The major deep veins around the knee joint are the popliteal vein, and the anterior and posterior tibial veins (Figure 115). The popliteal vein begins at the junction of the tibial veins in the posterior aspect of the lower leg, just inferior to the knee joint. It ascends posteriorly, continuing as the femoral vein about halfway up the thigh. As deep veins typically follow the arteries, the genicular veins accompany the genicular arteries around the knee joint, then drain into the popliteal vein. The important superficial veins around the knee joint are the small and great saphenous veins. Superficial veins typically do not follow arteries, but rather travel with cutaneous nerves. The small saphenous ascends the lower leg posteriorly, angling from lateral to medial. It merges with the popliteal vein at a position slightly superior to the knee joint. The great saphenous vein, the longest vein in the body, has a medial and anterior course in the lower leg. It moves to a posterior position, but stays medial along the knee joint, moving alongside the medial epicondyle of the femur. The great saphenous then moves anteriorly again through the thigh.

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Figure 115. Veins of knee.

Varicose and �spider� veins are often seen in the leg in the posterior aspect of the knee joint. As mentioned previously, in the femoral vein discussion, veins have valves to ensure the �one-way� uphill flow of blood back to the heart (Figure 116). Communicating vessels, also called perforating veins, exist between the deep and superficial veins to help compensate for valves that may be incompetent, and are allowing blood reflux. If venous walls are weakened or dilated, the cusps of the valves can no longer close properly, and the valves can become incompetent. This leads to an increase in the weight of the column of blood for the veins that are �downstream� from the bad valve. Blood can pool in these veins, causing them to become varicose, where the veins swell, become tortuous, and even bulge through the skin surface. Reticular veins, which are smaller varicose veins that do not bulge through the skin, as well as very small �spider� veins are both typically less severe conditions, but both still involve the backwards flow of blood. Removal of severe varicose veins will actually help blood flow, as the blood will no longer be stagnant in the pooled areas.

the knee

Figure 116. Varicose veins around knee.

Bursae Of The Knee

The synovial knee joint is home to a large number of bursae (Figure 117). These are fluid sacs and synovial pockets that surround and sometimes communicate with the joint cavity. They facilitate friction-free movement between the bones and moving structures (tendon, muscle). Fluid or debris can collect in the bursa, or fluid can extend into the bursa from the adjacent joint in situations such as excessive friction, infection or direct trauma. This type of pathological enlargement of the bursa is referred to as bursitis, which can mimic several peripheral joint and muscle abnormalities. Radiologists must be able to accurately identify bursal pathology, especially amongst the numerous knee bursae (14 reported in some literature). We will identify a few of the more common bursa, beginning with the suprapatellar bursa. This bursa lies between a quadriceps tendon and the femur, superior to the patella (Figure 118). Fluid is commonly found here when patients have a joint effusion. Bursitis of the prepatellar bursa is also known as �housemaid�s knee�. It occurs from repetitive trauma from kneeling, as seen with housemaids, wrestlers, and carpet-layers. This bursa is found between the patella and the skin (Figure 119). Inflammation of the superficial infrapatellar bursa may be called �Clergyman�s knee�, another bursitis that can occur from excessive kneeling. This bursa is located between the distal third of the patellar tendon and the overlying skin (Figure 120).

the knee

Figure 117. Bursae in the knee.

the knee

Figure 118. T2 gradient
displaying suprapatellar
bursa.

the knee

Figure 119. T2
fatsat displaying
prepatellar bursa.

the knee

Figure 120. T2 fatsat
displaying infrapatellar
bursa.

 

The synovial sac of the knee joint sometimes forms a posterior bulge, known as a Baker�s cyst or popliteal cyst (Figure 121). It typically forms between the tendons of the medial head of the gastrocnemius muscle and the semimembranosus muscle, posterior to the medial femoral condyle. Baker�s cysts are not true cysts, as they typically maintain open communication with the synovial sac. However, they can pinch off, and they can rupture. They are usually asymptomatic, but can be indicative of another problem of the knee, such as arthritis or a meniscal tear. Aspiration of the synovial fluid can be performed if the cyst becomes problematic. Treatment is usually necessary if a Baker�s cyst ruptures, as it can cause acute pain behind the knee, and swelling of the calf muscles. A ruptured cyst can also mimic a DVT or thrombophlebitis. Ultrasound and MRI can both be used for confirmation of a Baker�s cyst (Figure 122).

the knee

Figure 121. Lateral view of Baker�s cyst.

the knee

Figure 122. Sagittal image of Baker�s cyst on MRI.

Scan Setups

The following are HMSA suggestions for knee imaging. Knee protocols should be designed to yield diagnostic images of the menisci, bones, articular cartilage, and all ligamentous structures of the knee. While many radiologists may require additional imaging of the ACL, protocols that are designed for optimal imaging of the cartilage and menisci should also produce adequate images of the ACL. Always check with your radiologist for his/her imaging preferences.

Axial Scans

When positioning axial slices for the knee, sagittal and coronal images can be used to insure inclusion of all pertinent anatomy. The slices should extend superiorly to include the entire patella, and inferiorly to include the tibial tuberosity and patellar tendon insertion. A presat can be placed over the unaffected lower extremity to reduce the possibility of wrap-around artifact, as seen in the coronal image in Figure 139.

the knee

Figure 139. Axial slice setup using sagittal and coronal images.

Coronal Scans

Coronal slices of the knee should include the anatomy from the posterior femoral condyles to the anterior portion of the patella. Visualize a line connecting the lateral and medial condyles of the femur. Typically, the coronal slices are angled so that they are parallel to that line, as seen in the axial image in Figure 140.

the knee

Figure 140. Coronal slice setup using axial and sagittal images.

Sagittal Scans

Sagittal slices should include the anatomy from the medial condyle to the lateral condyle. The slice group may be angled per your radiologist�s preference, but should remain perpendicular to the coronal slices. Typically, the slice group is angled so that it is parallel to the medial border of the femoral condyle, as seen in the axial image in Figure 141.

the knee

Figure 141. Sagittal slice setup using axial and coronal images.

In addition to routine oblique sagittal images, some radiologists prefer an additional sagittal scan of the ACL with thin slices and high spatial resolution. Axial and coronal images can be used for slice setup. Referenced literature recommends that the angle of the slice group should not exceed 10� from a line drawn perpendicular to the bicondylar line (line that connects the posterior femoral condyles), as seen in Figure 142.

the knee

Figure 142. Sagittal ACL slice setup using axial and coronal images.

 

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Figures 150, 151- www.gla.ac.uk/ibls/US/fab/tutorial/anatomy/jiet.html

Figure 153- www.athletictapeinfo.com/?s=tennis+leg

Figure 154- radsource.us/clinic/0608

Figure 155- www.eorthopod.com/content/achilles-tendon-problems

Figure 156- achillesblog.com/assumptiondenied/not-a-rupture/

Figure 181- www.orthopaedicclinic.com.sg/ankle/a-patients-guide-to-ankle-anatomy/

Figure 182- www.activemotionphysio.ca/article.php?aid=47

Figure 183- www.ajronline.org/content/193/3/687.full

Figures 184, 186- www.eorthopod.com/content/ankle-anatomy

Figure 185- www.crossfitsouthbay.com/physical-therapy/learn-yourself-a-quick-anatomy-reference/ankle/

Figures 187, 227- www.activemotionphysio.ca/Injuries-Conditions/Foot/Foot-Anatomy/a~251/article.html

Figure 188- inmotiontherapy.com/article.php?aid=124

Figures 189, 190- home.comcast.net/~wnor/ankle.htm

Figure 191- skillbuilders.patientsites.com/Injuries-Conditions/Ankle/Ankle-Anatomy/a~47/article.html

Figure 192- metrosportsmed.patientsites.com/Injuries-Conditions/Foot/Foot-Anatomy/a~251/article.html

Figure 193- musc.edu/intrad/AtlasofVascularAnatomy/images/CHAP22FIG30.jpg

Figure 194- musc.edu/intrad/AtlasofVascularAnatomy/images/CHAP22FIG31B.jpg

Figure 195- veinclinics.com/physicians/appearance-of-vein-disease/

Figure 196- mdigradiology.com/services/interventional-services/varicose-veins.php

Figure 216- kidport.com/RefLib/Science/HumanBody/SkeletalSystem/Foot.htm

Figure 217- www.joint-pain-expert.net/foot-anatomy.html

Figure 218- www.thetoedoctor.com/turf-toe-symptoms-and-treatment/

Figures 219, 220- radsource.us/clinic/0303

Figure 221- www.ajronline.org/content/184/5/1481.full

Figure 222- www.answers.com/topic/arches

Figure 223- www.mayoclinic.com/health/medical/IM00939

Figure 224- radsource.us/clinic/0904

Figure 225- www.ortho-worldwide.com/anfobi.html

Figure 226- www.coringroup.com/lars_ligaments/patientscaregivers/your_anatomy/foot_and_ankle_anatomy/

Figure 228- www.stepbystepfootcare.ca/anatomy.html

Figure 229- iupucbio2.iupui.edu/anatomy/images/Chapt11/FG11_18aL.jpg

Figure 230- www.ajronline.org/content/184/5/1481.full.pdf

Figure 231- metrosportsmed.patientsites.com/Injuries-Conditions/Foot/Foot-Anatomy/a~251/article.html

Figure 232- www.painfreefeet.com/nerve-entrapments-of-the-leg-and-foot.html

Figures 233, 234- emedicine.medscape.com/article/401417-overview

Figure 235- web.squ.edu.om/med-Lib/MED_CD/E_CDs/anesthesia/site/content/v03/030676r00.HTM

Figure 236- www.nysora.com/peripheral_nerve_blocks/classic_block_tecniques/3035-ankle_block.html

Figure 237- ultrasoundvillage.net/imagelibrary/cases/?id=122&media=464&testyourself=0

Figure 238- www.joint-pain-expert.net/foot-anatomy.html

Figure 239- jap.physiology.org/content/109/4/1045.full

Figure 240- microsurgeon.org/secondtoe

Figure 241- elu.sgul.ac.uk/rehash/guest/scorm/406/package/content/common_iliac_veins.htm

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Diagnostic Outpatient Imaging

Diagnostic Outpatient Imaging

Dr. Alex Jimenez collaborates with top rated diagnosticians and imaging specialists. We are blessed to have in our association, imaging specialists that provide fast, courteous & premiere board certified specialists. In collaboration with our offices we can provide the quality of service our patients mandate and deserve.

Who We Are

Diagnostic Outpatient Imaging (DOI) is a state-of-the-art Radiology center in El Paso, TX. It is the only center of its kind in El Paso, owned and operated by a Radiologist.

This means when you come to DOI for a radiologic exam, every detail, from the design of the rooms, the choice of the equipment, the hand-picked technologists, and the software which runs the office, is carefully chosen or designed by the Radiologist and not by an accountant.

Our market niche is one center of excellence. Our values related to patient care are: We believe in treating patients the way we would treat our family and we will do our best to ensure that you have a good experience at our clinic.

Dear Doctors,

We are pleased to inform you of the arrival of our Titan 3-Tesla MRI at Diagnostic Outpatient Imaging. This is El Paso’s only radiology imaging center that offers this technology. Patients do not always realize how important image quality is: It can make the difference in the diagnosis.

3-Tesla MRI is like HD TV and once you try it, you will not want to go back. The increased magnet strength gives us many benefits at no additional expense to the patient. It gives us the ability to scan faster or to scan with higher detail. An MRI of the brain can take 20 minutes and have exceptional quality, or we can perform the scan in less time, with better quality that is achieved on most 1.5 Tesla “high field” MRIs. This is incredibly useful for children.

Our 3T MRI can perform Diffusion Tensor Imaging, MRI Spectroscopy and CSF flow studies to name just a few of its possibilities.

This scanner is not only very fast, it is very large. Our open MRI has a clearance of 35 cm. The 3T has a diameter of 71 cm! This is welcome news for nervous or claustrophobic patients, and combined with its speed, it can actually eliminate the need for sedation for some patients. 3T MRI is faster, clearer, and has more diagnostic possibilities. We are certain you and your patients will notice the difference.

Our Services

MRI’s:

DOI has three MRI’s under one roof. All are American College of Radiology (ACR) Certified.

Good

Open MRI (0.35 Tesla): This MRI perfect for claustrophobic and very large patients. There is no table weight limit on this MRI

Better

High Field 1.5 Tesla MRI- This is a eight channel MRI with high end image quality. It is in a beautiful room and has ‘pianissimo’ technology, which makes the MRI relatively quiet. This machine has been the best MRI in private practice in El Paso for years. It will soon be eclipsed by our new 3.0 Tesla MRI.

Best

High Field 3.0 Tesla MRI- This is the only 3.0 Tesla MRI in private practice in El Paso. This technology can deliver stunning image quality, which can actually make a difference in your diagnosis. The increased magnet strength gives us many benefits at no additional expense to the patient.�??It gives us the ability to scan faster, or to scan with higher detail. This is welcome news for nervous or claustrophobic patients, and as well as for children as it can actually eliminate the need for sedation in some patients. 3T is faster, clearer, more diagnostic for a better for MRI. It is like HD TV. Once you have tried it, you won’t want to go back. This MRI effectively doubles our MRI capacity. If needed most exams can be completed in under 5 minutes, instead of the normal 30-45 minutes.

Breast MRI:

DOI began Breast MRI in July 2007, being the first facility in El Paso to perform the exam. We have now performed over 2500 breast MRI’s and many MRI-guided breast biopsies. All have been interpreted and/or performed by Dr. Boushka, making him the most experienced radiologist in the city with this exam. This is the most powerful tool for the detection of Breast cancer to date.

Hours:
Monday to Thursday 7 am to 9 pm
Friday 7 am to 5 pm
Saturday 8 am to 4 pm

Prostate MRI:

Guys, you need great medical care also. We are the only facility in El Paso performing this leading edge exam. MRI can see cancers when other imaging methods cannot. Not only can we see prostate cancers with MRI, we can perform MRI-guided prostate biopies for pathologic (definitive) diagnosis.

 

Monday to Thursday 7 am to 9 pm
Friday 7 am to 5 pm
Saturday 8 am to 4 pm

CT:

We have a 16 slice Toshiba Aquillion CT scanner, with newly updated in Dec 2013. The upgrade allows for reduced X-ray dose, higher resolution, more patient comfort, shorter breath holds and doubles the speed of the scanner. This scanner performs CT X-ray exams as helical volume acquisitions in 3D from a single patient exam. Most exams are finished in under 60 seconds, unless delayed images with contrast are indicated. Additionally we have a powerful 3D post processing workstation.

Hours
Monday to Friday 7 am to 6 pm

Ultrasound:

DOI has just doubled our Ultrasound capacity with newly purchased Philips 34 XRL scanner. We have Three certified Ultrasonographers with cumulative experience of 45 years. We are confident you will find them professional and compassionate. Beverly Bruner RDMS, Sonographer, formally of Desert Imaging has joined our team.

3D OB Ultrasounds:

You better believe it. Available whenever our US department is open. No referral necessary. Images are reviewed by an actual radiologist.

Ultrasound Hours:
Monday, Tuesday, Thursday 8 am to 5 pm
Wednesday 8 am to 8 pm
Friday 8 am to 5 pm
Saturday 8 am to 12 pm

Digital Mammography

DOI was the first facility in El Paso to acquire Hologic Full Field Digital Mammography and thus we have more experience with this technology than any facility in El Paso. Our Mammographer has 20 years of experience and has her own following of patents who seek her out to perform their mammograms because of her excellent and compassionate care. Our private pay screening mammography price of $90, including the interpretation is an unbeaten price in El Paso.

Hours
Mon – Fri 8am to 4pm
Extended hours Wednesday until 8pm)
Saturdays 8am to 12pm

Bone Denisity (DEXA)

We have a brand new, Hologic Discovery CI bone densitometer scanner. This is the latest technology.

X-Ray

Our digital computed radiography was just updated February 2014. No appointments are necessary.

We look forward to serving you.

 

 

Sincerely,
William M Boushka, MD

Contact Us

Get in touch with us!

Please note that we can answer general questions, but anything specific to your medical case should be discussed with your physician.

Referral Form

New Patient Forms:
New Patient Form – English
New Patient Form – Spanish

Patient History Form:
Patient History – English
Patient History – Spanish

Patient Release Form:
Patient Release Form

Diagnostic Outpatient Imaging
6065 Montana, Suite A6
El Paso, TX 79925
Tel: (915) 881-1900
Fax: (915) 771-9345

Scheduling:
Tel: (915) 881-1900

Billing & Payments:
Medical Billing Unlimited
5959 Gateway West Suite 120
El Paso, TX 79925
(915) 779-1716

Email:�mail@dximaging.com