Mäurer Imaging Strategies for the Knee

M. L. Pretterklieber, F. Kainberger, and N. Leneva 1    Functional Anatomy of the Knee Joint The knee joint (articulatio genus) is the largest synovial joint in the human body. Joint articulation is formed by the pairs of femoral and tibial condyles together with the menisci between them. In terms of arthrokinematics, this creates a joint with two axes that may be divided functionally into a meniscotibial and a meniscofemoral compartment. The saddle joint located between the patellar surface of the femur and the patella completes the knee joint (Fig. 1.1). Joint Mechanics Flexion, Extension, Rotation The knee joint can be flexed or extended around a transversal axis passing through the femoral condyles. These movements occur primarily in the meniscofemoral compartment of the joint. At flexion of about 30° and greater, the knee joint can be rotated inwardly or outwardly. Compared to the range of motion possible in flexion and extension, however, this degree of arbitrary rotation, occurring chiefly in the meniscotibial compartment, is low. The rotational axis connects the centers of the medial femoral condyle and medial tibial condyle. The “Screw-home Mechanism” There is a second, fundamental rotation that occurs automatically during the last 30° of extension. The so-called “screw-home mechanism” (knee-locking mechanism), produced by the varying diameters of the femoral condyles, causes an inward rotation of the femur of the standing leg of around 5° against the tibia, which is held in place by the weight of the body. This holds the knee joint in a locked position, i.e., the articular surfaces obtain a position of almost complete congruence. The fully extended knee is thus held in place only by the action of the joint, i.e., without any muscular activity, forming an integral component in the so-called amuscular standing posture. “Unlocking” the knee from this position and resuming flexion requires the action of the popliteus muscle (see Figs. 1.6, 1.7, 1.9), a small and almost trivial muscle. Located deep in the hollow behind the knee (popliteal fossa), this muscle arises from the medial two-thirds of the dorsal aspect of the tibia, proximal to the soleal line. It attaches to the lateral and dorsal rim of the lateral meniscus and to the lateral femoral epicondyle. When the popliteus muscle contracts at the beginning of knee flexion, it pulls the lateral meniscus slightly dorsally while rotating the femur outwardly. This motion eliminates the congruence between the joint surfaces, freeing the femoral and tibial condyles to move against one another and the menisci. Bony Structures Femur (Fig. 1.1)   joint surfaces on the medial and lateral condyles, as well as on the patellar surface of the femur, are covered with hyaline cartilage   larger diameter of medial condyle (anteroposteriorly and proximodistally) than lateral condyle, the former serving as the center of voluntary rotation in the flexed knee   the nonarticular condylar surfaces facing the intercondylar fossa serve as attachment sites for the cruciate ligaments (see below)   medial and lateral epicondyles as attachment sites for the collateral ligaments and the lateral epicondyle as insertion site of the popliteus muscle Fig. 1.1 a–c Osteology of the femur and patella. Knee joint structures and surrounding structures demonstrated on elements of the lower limb skeleton of an adult male. a, b View from anterior c  View from posterior. AT adductor tubercle FH fibular head CT Gerdy tubercle IE intercondylar eminence IF intercondylar fossa IL intercondylar line LC lateral femoral (tibial) condyle LFE lateral femoral epicondyle LSL lateral supracondylar line MC medial femoral (tibial) condyle MFE medial femoral epicondyle MSL medial supracondylar line PaS patellar surface PIA posterior intercondylar area PS popliteal surface TT tibial tuberosity Tibia (Figs. 1.1, 1.2)   articular surfaces on medial and lateral condyles covered with hyaline cartilage   anterior intercondylar area as attachment site for the anterior cruciate ligament (ACL) as well as for the infra-patellar fat pad (Hoffa's fat pad)   intercondylar eminence as site of attachment for the anterior and posterior meniscal horns: medial meniscus at the medial intercondylar tubercle and lateral meniscus at the lateral intercondylar tubercle   posterior intercondylar area and upper central posterior surface of tibia as attachment sites of the posterior cruciate ligament (PCL)   tibial tuberosity as an insertion site for the patellar ligament, the distal prolongation of the quadriceps aponeurosis   Gerdy tubercle on the anterior side of the lateral condyle anchoring the iliotibial tract, the reinforced part of the fascia lata   “tuberculum tendinis” on the posterior aspect of the medial condyle: main attachment of the semimembranosus muscle (see Figs. 1.7, 1.8) Fig. 1.2 a, b Osteology of the tibia and fibula. Knee joint structures and surrounding structures demonstrated on elements of the lower limb skeleton of an adult male. Note the clearly visible “tuberculum tendinis” (asterisk) on the posterior surface and the groove (broad arrow) on the medial aspect of the medial condyle: both structures are caused by the insertion tendon of the semimembranosus (see also Figs. 1.7, 1.8) a  View from anterior. b  View from posterior. AFH apex of the fibular head AIA anterior intercondylar area FH fibular head LC lateral tibial condyle LIT lateral intercondylar tubercle MC medial tibial condyle MIT medial intercondylar tubercle PIA posterior intercondylar area SL soleal line TT tibial tuberosity Patella (Figs. 1.1, 1.3)   largest sesamoid bone in the human body, embedded in the quadriceps aponeurosis   anterior (nonarticular) surface is grooved from the pulling forces exerted by the superficial fibers of the quadriceps tendon, which pass directly into the patellar ligament; not infrequently, chamberlike bony processes guiding the tendon fibers may occur as an anatomic variant   posterior (articular) surface of the patella covered by a thick layer of hyaline cartilage   the base of the patella is directed proximally, while the apex, which also serves as attachment for the deep fibers of the patellar ligament, is pointed distally Fig. 1.3 a–h Anterior components of the fibrous capsule, patellofemoral joint, and infrapatellar fat pad. a  Superficial structures of the fibrous capsule. The nonreinforced parts of the fibrous capsule between the patellar retinacula and the patellar ligament have been removed to expose the underlying infrapatellar fat pad (IFP; Hoffa's fat pad). b  Specimen of the right knee. All capsule-reinforcing muscular tendons were removed in order to demonstrate the main ligaments in relation to the menisci. Note the large distance between the lateral meniscus and the fibular collateral ligament, which runs outside of the fibrous capsule. c  Specimen of the right knee, opened from anterior. On the anterior wall of the joint, the infrapatellar fat pad (AF/IPP) creates a large gliding surface for both femoral condyles. Note the course of the infrapatellar plica (IPP),...