The knee is a complex joint made up of different structures including bones, tendons, ligaments and muscles. They all work together to maintain normal function and provide stability to the knee during movement.
Having a well-functioning healthy knee is essential for our mobility and ability to participate in various activities. Understanding the anatomy of the knee enhances your ability to discuss and choose the right treatment procedure for knee problems with your doctor.
The Knee is a hinge joint made up of two bones, the thigh bone (femur) and the shinbone (tibia). There are two round knobs at the end of the femur called femoral condyles which articulate with the flat surface of the tibia called the tibial plateau. The tibia plateau on the inside of the leg is called the medial tibial plateau, and on the outside of the leg it is called the lateral tibial plateau.
The two femoral condyles form a groove on the front (anterior) side of the knee called the patellofemoral groove. A small bone called the patella sits in this groove and forms the knee cap. It acts as a shield and protects the knee joint from direct trauma.
A fourth bone called the fibula is the other bone of the lower leg. This form a small joint with the tibia. This joint has very little movement and is not considered a part of the main joint of the knee.
Articular Cartilage and Menisci
Movement of the bones causes friction between the articulating surfaces. To reduce this friction, all articulating surfaces involved in movement are covered with a white, shiny, slippery layer called articular cartilage. The articulating surface of the femoral condyles, tibial plateaus and the back of the patella are covered with this cartilage. The cartilage provides a smooth surface that facilitates easy movement.
To further reduce friction between the articulating surfaces of the bones, the knee joint is lined by a synovial membrane which produces a thick clear fluid called synovial fluid. This fluid lubricates and nourishes the cartilage and bones inside the joint capsule.
Within the knee joint between the femur and tibia there are two C shaped cartilaginous structures called menisci. Menisci function to provide stability to the knee by spreading the weight of the upper body across the whole surface of the tibial plateau. The menisci help in load bearing by preventing the weight from concentrating onto a small area, which could damage the articular cartilage. The menisci also act as a cushion between the femur and tibia by absorbing the shock produced by activities such as walking, running and jumping.
Ligaments are tough bands of tissue that connect one bone to another bone. The ligaments of the knee function to stabilize the knee joint. There are two important groups of ligaments that hold the bones of the knee joint together, collateral ligaments and the cruciate ligament.
Collateral ligaments are present on either side of the knee. They function to prevent the knee from moving too far during side to side motion. The collateral ligament on the inside is called the medial collateral ligament (MCL) and the collateral ligament on the outside is called the lateral collateral ligament (LCL).
Cruciate ligaments- This group of ligaments, present inside the knee joint, control the back and forth motion of the knee. The Cruciate ligament in the front of the knee is called anterior cruciate ligament or ACL and the cruciate ligament in the back of the knee is called posterior cruciate ligament or PCL.
Muscles: There are two major muscles, the quadriceps and the hamstrings, which enable movement of the knee joint. The quadriceps muscles are in the front of the thigh. When the quadriceps muscles contract, the knee straightens. The hamstrings are in the back of the thigh. When the hamstring muscles contract, the knee bends.
Tendons are structures that attach muscles to the bone. The quadriceps muscles of the knee meet just above the patella and attach to it through a tendon called the quadriceps tendon. The patella further attaches to the tibia through a tendon called the patella tendon. The quadriceps muscle, quadriceps tendon and patellar tendon all work together to straighten the knee. Similarly, the hamstring muscles at the back of the leg are attached to the knee joint with the hamstring tendon.
- Knee Pain
- Anterior Knee Pain
- Runner's Knee
- Osgood Schlatter Disease
- Chondromalacia Patella
- Jumper’s Knee
- Baker’s Cyst
- Iliotibial Band Syndrome
- Lateral Patellar Compression Syndrome
- Osteochondritis Dissecans
- Shin Splints
- Knee Injury
- Unstable Knee
- Goosefoot Bursitis of the Knee
- Knee Sprain
- ACL Tear
- MCL Tear
- MCL Sprain
- Meniscal Injuries
- Meniscal Tears
- Ligament Injuries
- Multiligament Instability
- Knee Arthritis
- Patellar Dislocation/Patellofemoral Dislocation
- PCL Injuries
- Chondral (Articular Cartilage Defects)
- Patellar Instability
- Patellofemoral Instability
- Patella Fracture
- Recurrent Patella Dislocation
- Quadriceps Tendon Rupture
- Patella Tendon Rupture
- Lateral Meniscus Syndrome
- Medial Meniscus Syndrome
- Tibial Eminence Spine Avulsions
- Osteonecrosis of the Knee
- Knee Angular Deformities
Knee Replacement and Reconstruction
- Knee Osteotomy
- High Tibial Osteotomy
- Tibial Tubercle Osteotomy
- Unicompartmental Knee Replacement
- Patellofemoral Knee Replacement
- What is new in Knee Replacement
- Computer Navigation for Total Knee Replacement
- Total Knee Replacement
- Revision Knee Replacement
- Minimally Invasive Knee Joint Replacement
- Robotic Assisted Partial Knee Surgery
- Medial Patellofemoral Ligament Reconstruction
- Distal Realignment Procedures
- Arthroscopic Reconstruction of the Knee for Ligament Injuries
- PCL Reconstruction
- LCL Reconstruction
- ACL Reconstruction
- Outpatient Total Knee Replacement
- Tricompartmental Knee Replacement
- After Knee Replacement
Patient Specific Knee Options
- Patellar Tendon Repair
- Knee Ligament Reconstruction
- Cartilage Replacement
- Cartilage Repair and Transplantation
- Autologus Chondrocyte Implantation
- Partial Meniscectomy
- Meniscal Surgery
- Limb Lengthening