1. Chapter 20: The Knee and Related Structures

2. Complex joint that endures great amounts of trauma due to extreme amounts of stress that are regularly applied
Hinge joint w/ a rotational component
Stability is due primarily to ligaments, joint capsule and muscles surrounding the joint
Designed for stability w/ weight bearing and mobility in locomotion

12. Functional Anatomy
Movement of the knee requires flexion, extension, rotation and the arthrokinematic motions of rolling and gliding
Rotational component involves the “screw home mechanism”
As the knee extends it externally rotates because the medial femoral condyle is larger than the lateral
Provides increased stability to the knee
Popliteus “unlocks” knee allowing knee to flex

13. Capsular ligaments are taut during full extension and relaxed w/ flexion
Allows rotation to occur
Deeper capsular ligaments remain taut to keep rotation in check
PCL prevents excessive internal rotation, guides the knee in flexion, and acts as drag during initial glide phase of flexion
ACL stops excessive internal rotation, stabilizes the knee in full extension and prevents hyperextension

14. Range of motion includes 140 degrees of motion
Limited by shortened position of hamstrings, bulk of hamstrings and extensibility of quads
Patella aids knee during extension, providing a mechanical advantage
Distributes compressive stress on the femur by increasing contact between patellar tendon and femur
Protects patellar tendon against friction
When moving from extension to flexion the patella glides laterally and further into trochlear groove

15. Kinetic Chain
Directly affected by motions and forces occurring at the foot, ankle, lower leg, thigh, hip, pelvis, and spine
With the kinetic chain forces must be absorbed and distributed
If body is unable to manage forces, breakdown to the system occurs
Knee is very susceptible to injury resulting from absorption of forces

16. Assessing the Knee Joint
Determining the mechanism of injury is critical
History- Current Injury
Past history
Mechanism- what position was your body in?
Did the knee collapse?
Did you hear or feel anything?
Could you move your knee immediately after injury or was it locked?
Did swelling occur?
Where was the pain

17. History - Recurrent or Chronic Injury
What is your major complaint?
When did you first notice the condition?
Is there recurrent swelling?
Does the knee lock or catch?
Is there severe pain?
Grinding or grating?
Does it ever feel like giving way?
What does it feel like when ascending and descending stairs?
What past treatment have you undergone?

18. Observation Walking, half squatting, going up and down stairs
Swelling, ecchymosis,
Leg alignment
Genu valgum and genu varum
Hyperextension and hyperflexion
Patella alta and baja
Patella rotated inward or outward
May cause a combination of problems
Tibial torsion, femoral anteversion and retroversion

19. Femoral Anteversion and Retroversion
Tibial torsion
An angle that measures less than 15 degrees is an indication of tibial torsion
Femoral Anteversion and Retroversion
Total rotation of the hip equals ~100 degrees
If the hip rotates >70 degrees internally, anteversion of the hip may exist
INSERT 20-9

21. Knee Symmetry or Asymmetry
Do the knees look symmetrical? Is there obvious swelling? Atrophy?
Leg Length Discrepancy
Anatomical or functional
Anatomical differences can potentially cause problems in all weight bearing joints
Functional differences can be caused by pelvic rotations or mal-alignment of the spine

22. Palpation - Bony Medial tibial plateau Medial femoral condyle
Adductor tubercle
Gerdy’s tubercle
Lateral tibial plateau
Lateral femoral condyle
Lateral epicondyle
Head of fibula
Tibial tuberosity
Superior and inferior patella borders (base and apex)
Around the periphery of the knee relaxed, in full flexion and extension

23. Palpation - Soft Tissue
Medial and lateral collateral ligaments
Pes anserine
Medial/lateral joint capsule
Semitendinosus
Semimembranosus
Gastrocnemius
Popliteus
Biceps Femoris
Vastus medialis
Vastus lateralis
Vastus intermedius
Rectus femoris
Quadriceps and patellar tendon
Sartorius
Medial patellar plica
Anterior joint capsule
Iliotibial Band
Arcuate complex

24. Palpation of Swelling Intra vs. extracapsular swelling
Intracapsular may be referred to as joint effusion
Swelling w/in the joint that is caused by synovial fluid and blood is a hemarthrosis
Sweep maneuver
Ballotable patella - sign of joint effusion
Extracapsular swelling tends to localize over the injured structure
May ultimately migrate down to foot and ankle

25. Special Tests for Knee Instability
Use endpoint feel to determine stability
MRI may also be necessary for assessment
Classification of Joint Instability
Knee laxity includes both straight and rotary instability
Translation (tibial translation) refers to the glide of tibial plateau relative to the femoral condyles
As the damage to stabilization structures increases, laxity and translation also increase
Valgus and Varus Stress Tests
Used to assess the integrity of the MCL and LCL respectively
Testing at 0 degrees incorporates capsular testing while testing at 30 degrees of flexion isolates the ligaments

27. Anterior Cruciate Ligament Tests
Drawer test at 90 degrees of flexion
Tibia sliding forward from under the femur is considered a positive sign (ACL)
Should be performed w/ knee internally and externally to test integrity of joint capsule

28. Lachman Drawer Test
Will not force knee into painful flexion immediately after injury
Reduces hamstring involvement
At 30 degrees of flexion an attempt is made to translate the tibia anteriorly on the femur
A positive test indicates damage to the ACL

29. Pivot Shift Test Used to determine anterolateral rotary instability
Position starts w/ knee extended and leg internally rotated
The thigh and knee are then flexed w/ a valgus stress applied to the knee
Reduction of the tibial plateau (producing a clunk) is a positive sign

30. Flexion-Rotation Drawer Test
Jerk Test
Reverses direction of the pivot shift
Moves from position of flexion to extension
W/out and ACL the tibia will sublux at 20 degrees of flexion
Flexion-Rotation Drawer Test
Knee is taken from a position of 15 degrees of flexion (tibia is subluxed anteriorly w/ femur externally rotated)
Knee is moved into 30 degrees of flexion where tibia rotates posteriorly and femur internally rotates

31. Posterior Cruciate Ligament Tests
Posterior Drawer Test
Knee is flexed at 90 degrees and a posterior force is applied to determine translation posteriorly
Positive sign indicates a PCL deficient knee
External Rotation Recurvatum Test
With the athlete supine, the leg is lifted by the great toe
If the tibia externally rotates and slides posteriorly there may be a PCL injury and damage to the posterolateral corner of the capsule

32. Posterior Sag Test (Godfrey’s test)
Athlete is supine w/ both knees flexed to 90 degrees
Lateral observation is required to determine extent of posterior sag while comparing bilaterally

33. Instrument Assessment of the Cruciate Ligaments
A number of devices are available to quantify AP displacement of the knee
KT-2000 arthrometer, Stryker knee laxity tester and Genucom can be used to assess the knee
Test can be taken pre & post-operatively and through rehab

34. Meniscal Tests McMurray’s Meniscal Test
Used to determine displaceable meniscal tear
Leg is moved into flexion and extension while knee is internally and externally rotated in conjunction w/ valgus and varus stressing
A positive test is found w/ clicking and popping response

36. Apley’s Compression Test
Hard downward pressure is applied w/ rotation
Pain indicates a meniscal injury
Apley’s Distraction Test
Traction is applied w/ rotation
Pain will occur if there is damage to the capsule or ligaments
No pain will occur if it is meniscal

37. Girth Measurements Subjective Rating
Changes in girth can occur due to atrophy, swelling and conditioning
Must use circumferential measures to determine deficits and gains during the rehabilitation process
Measurements should be taken at the joint line, the level of the tibial tubercle, belly of the gastrocnemius, 2 cm above the superior border of the patella, and 8-10 cm above the joint line
Subjective Rating
Used to determine patient’s perception of pain, stability and functional performance

38. Functional Examination
Must assess walking, running, turning and cutting
Co-contraction test, vertical jump, single leg hop tests and the duck walk
Resistive strength testing
Q-Angle
Lines which bisects the patella relative to the ASIS and the tibial tubercle
Normal angle is 10 degrees for males and 15 degrees for females
Elevated angles often lead to pathological conditions associated w/ improper patella tracking

39. Palpation of the Patella
The A Angle
Patellar orientation to the tibial tubercle
Quantitative measure of the patellar realignment after rehabilitation
An angle greater than 35 degrees is often correlated w/ patellofemoral pathomechanics
Palpation of the Patella
Must palpate around and under patella to determine points of pain
Patella Grinding, Compression and Apprehension Tests
A series of glides and compressions are performed w/ the patella to determine integrity of patellar cartilage

40. Prevention of Knee Injuries
Physical Conditioning and Rehabilitation
Total body conditioning is required
Strength, flexibility, cardiovascular and muscular endurance, agility, speed and balance
Muscles around joint must be conditioned (flexibility and strength) to maximize stability
Must avoid abnormal muscle action through flexibility
In an effort to prevent injury, extensibility of hamstrings, erector spinae, groin, quadriceps and gastrocnemius is important

41. ACL Prevention Programs
Focus on strength, neuromuscular control, balance
Series of different programs which address balance board training, landing strategies, plyometric training, and single leg performance
Can be implemented in rehabilitation and preventative training programs
Shoe Type
Change in football footwear has drastically reduced the incidence of knee injuries
Shoes w/ more shorter cleats does not allow foot to become fixed while still allowing for control w/ running and cutting

42. Functional and Prophylactic Knee Braces
Used to prevent and reduce severity of knee injuries
Used to protect MCL, or prevent further damage to grade 1 & 2 sprains of the ACL or to protect the ACL following surgery
Can be custom molded and designed to control rotational forces

43. Recognition and Management of Specific Injuries
Medial Collateral Ligament Sprain
Etiology
Result of severe blow or outward twist
Signs and Symptoms - Grade I
Little fiber tearing or stretching
Stable valgus test
Little or no joint effusion
Some joint stiffness and point tenderness on lateral aspect
Relatively normal ROM

44. Management RICE for at least 24 hours Crutches if necessary
Follow-up care will include cryokinetics w/ exercise
Move from isometrics and STLR exercises to bicycle riding and isokinetics
Return to play when all areas have returned to normal
May require 3 weeks to recover

45. Signs and Symptoms (Grade II)
Complete tear of deep capsular ligament and partial tear of superficial layer of MCL
No gross instability; laxity at 5-15 degrees of flexion
Slight swelling
Moderate to severe joint tightness w/ decreased ROM
Pain along medial aspect of knee
Management
RICE for hours; crutch use until acute phase has resolved
Possibly a brace or casting prior to the initiation of ROM activities
Modalities 2-3 times daily for pain
Gradual progression from isometrics (quad exercises) to CKC exercises; functional progression activities

46. Signs and Symptoms (Grade III)
Complete tear of supporting ligaments
Complete loss of medial stability
Minimum to moderate swelling
Immediate pain followed by ache
Loss of motion due to effusion and hamstring guarding
Positive valgus stress test
Management
RICE
Conservative non-operative versus surgical approach
Limited immobilization (w/ a brace); progressive weight bearing for
Rehab would be similar to Grade I & II injuries

47. Lateral Collateral Ligament Sprain
Etiology
Result of a varus force, generally w/ the tibia internally rotated
Direct blow is rare
If severe enough damage can also occur to the cruciate ligaments, ITB, and meniscus, producing bony fragments as well
Signs and Symptoms
Pain and tenderness over LCL
Swelling and effusion around the LCL
Joint laxity w/ varus testing
May cause irritation of the peroneal nerve
Management
Following management of MCL injuries depending on severity

48. Anterior Cruciate Ligament Sprain
Etiology
MOI - tibia externally rotated and valgus force at the knee (occasionally the result of hyperextension from direct blow)
May be linked to inability to decelerate valgus and rotational stresses - landing strategies
Male versus female
Research is quite extensive in regards to impact of femoral notch, ACL size and laxity, malalignments (Q-angle) faulty biomechanics
Extrinsic factors may include, conditioning, skill acquisition, playing style, equipment, preparation time
Also involves damage to other structures including meniscus, capsule, MCL

49. Signs and Symptoms Management
Experience pop w/ severe pain and disability
Rapid swelling at the joint line
Positive anterior drawer and Lachman’s
Other ACL tests may also be positive
Management
RICE; use of crutches
Arthroscopy may be necessary to determine extent of injury
Could lead to major instability in incidence of high performance
W/out surgery joint degeneration may result
Age and activity may factor into surgical option
Surgery may involve joint reconstruction w/ grafts (tendon), transplantation of external structures
Will require brief hospital stay and 3-5 weeks of a brace
Also requires 4-6 months of rehab

50. Posterior Cruciate Ligament Sprain
Etiology
Most at risk during 90 degrees of flexion
Fall on bent knee is most common mechanism
Can also be damaged as a result of a rotational force
Signs and Symptoms
Feel a pop in the back of the knee
Tenderness and relatively little swelling in the popliteal fossa
Laxity w/ posterior sag test
Management
RICE
Non-operative rehab of grade I and II injuries should focus on quad strength
Surgical versus non-operative
Surgery will require 6 weeks of immobilization in extension w/ full weight bearing on crutches
ROM after 6 weeks and PRE at 4 months

51. Meniscal Lesions Etiology Signs and Symptoms
Medial meniscus is more commonly injured due to ligamentous attachments and decreased mobility
Also more prone to disruption through torsional and valgus forces
Most common MOI is rotary force w/ knee flexed or extended
Can be longitudinal, oblique or transverse tears
Signs and Symptoms
Effusion developing over hour period
Joint line pain and loss of motion
Intermittent locking and giving way
Pain w/ squatting
Portions may become detached causing locking, giving way or catching w/in the joint
If chronic, recurrent swelling or muscle atrophy may occur

53. Management
If the knee is not locked, but indications of a tear are present further diagnostic testing may be required
If locking occurs, anesthesia may be necessary to unlock the joint w/ possible arthroscopic surgery follow-up
W/ surgery all efforts are made to preserve the meniscus -- will full healing being dependent on location
Menisectomy rehab allows partial weight bearing and quick return to activity
Repaired meniscus will require immobilization and a gradual return to activity over the course of 12 weeks

54. Knee Plica Etiology Signs and Symptoms Management
Irritation of the plica (generally, mediopatellar plica and often associated w/ chondromalacia
Signs and Symptoms
Possible history of knee pain/injury
Recurrent episodes of painful pseudo-locking
Possible snapping and popping
Pain w/ stairs and squatting
Little or no swelling, and no ligamentous laxity
Management
Treat conservatively w/ RICE and NSAID’s if the result of trauma
Recurrent conditions may require surgery

55. Osteochondral Knee Fractures
Etiology
Same MOI as collateral/cruciate ligaments or meniscal injuries
Twisting, sudden cutting or direct blow
Signs and Symptoms
Hear a snap and feeling of giving way
Immediate swelling and considerable pain
Management
Diagnosis confirmed through arthroscopic exam, w/ surgery to replace fragment to avoid joint degeneration and arthritis

56. Osteochondritis Dissecans
Etiology
Partial or complete separation of articular cartilage and subchondral bone
Cause is unknown but may include blunt trauma, possible skeletal or endocrine abnormalities, prominent tibial spine impinging on medial femoral condyle, or impingement due to patellar facet
Signs and Symptoms
Aching pain with recurrent swelling and possible locking
Possible quadriceps atrophy and point tenderness
Management
Rest and immobilization for children
Surgery may be necessary in teenagers and adults (drilling to stimulate healing, pinning or bone grafts

57. Loose Bodies w/in the Knee
Etiology
Result of repeated trauma
Possibly stem from osteochondritis dissecans, meniscal fragments, synovial tissue or cruciate ligaments
Signs and Symptoms
May become lodged, causing locking or popping
Pain and sensation of instability
Management
If not surgically removed it can lead to conditions causing joint degeneration

58. Joint Contusions Etiology Signs and Symptoms Management
Blow to the muscles crossing the joint (vastus medialis)
Signs and Symptoms
Present as knee sprain, severe pain, loss of movement and signs of acute inflammation
Swelling, discoloration
Possible capsular damage
Management
RICE initially and continue if swelling persists
Gradual progression to normal activity following return of ROM and padding for protection
If swelling does not resolve w/in a week a chronic condition (synovitis or bursitis) may exist requiring more rest

59. Peroneal Nerve Contusion
Etiology
Compression of peroneal nerve due to a direct blow
Signs and Symptoms
Local pain and possible shooting nerve pain
Numbness and paresthesia in cutaneous distribution of the nerve
Added pressure may exacerbate condition
Generally resolves quickly -- in the event it does not resolve, it could result in drop foot
Management
RICE and return to play once symptoms resolve and no weakness is present
Padding for fibular head is necessary for a few weeks

60. Bursitis Etiology Signs and Symptoms Management
Acute, chronic or recurrent swelling
Prepatellar = continued kneeling
Infrapatellar = overuse of patellar tendon
Signs and Symptoms
Prepatellar bursitis may be localized swelling above knee that is ballotable
Swelling in popliteal fossa may indicate a Baker’s cyst
Associated w/ semimembranosus bursa or medial head of gastrocnemius
Commonly painless and causing little disability
May progress and should be treated accordingly
Management
Eliminate cause, RICE and NSAID’s
Aspiration and steroid injection if chronic

61. Patellar Fracture Etiology Signs and Symptoms Management
Direct or indirect trauma (severe pull of tendon)
Forcible contraction, falling, jumping or running
Signs and Symptoms
Hemorrhaging and joint effusion w/ generalized swelling
Indirect fractures may cause capsular tearing, separation of bone fragments and possible quadriceps tendon tearing
Little bone separation w/ direct injury
Management
X-ray necessary for confirmation of findings
RICE and splinting if fracture suspected
Refer and immobilize for 2-3 months

62. Acute Patella Subluxation or Dislocation
Etiology
Deceleration w/ simultaneous cutting in opposite direction (valgus force at knee)
Quad pulls the patella out of alignment
Some athletes may be predisposed to injury
Repetitive subluxation will impose stress to medial restraints
Signs and Symptoms
W/ subluxation, pain and swelling, restricted ROM, palpable tenderness over adductor tubercle
Dislocations result in total loss of function

63. Management
Reduction is performed by flexing hip, moving patella medially and slowly extending the knee
Following reduction, immobilization for at least 4 weeks w/ use of crutches and isometric exercises during this period
After immobilization period, horseshoe pad w/ elastic wrap should be used to support patella
Muscle rehab focusing on muscle around the knee, thigh and hip are key (STLR’s are optimal for the knee)
Possible surgery to release tight structures
Improve postural and biomechanical factors

64. Injury to the Infrapatellar Fat Pad
Etiology
May become wedged between the tibia and patella
Irritated by chronic kneeling, pressure or trauma
Signs and Symptoms
Capillary hemorrhaging and swelling
Chronic irritation may lead to scarring and calcification
Pain below the patellar ligament (especially during knee extension)
May display weakness, mild swelling and stiffness during movement
Management
Rest from irritating activities until inflammation has subsided and therapeutic use of cold
Heel lift to prevent irritation during extension
Hyperextension taping to prevent full extension

65. Chondromalacia patella
Etiology
Softening and deterioration of the articular cartilage
Possible abnormal patellar tracking due to genu valgum, external tibial torsion, foot pronation, femoral anteversion, patella alta, shallow femoral groove, increased Q angle, laxity of quad tendon
Signs and Symptoms
Pain w/ walking, running, stairs and squatting
Possible recurrent swelling, grating sensation w/ flexion and extension
Pain at inferior border during palpation
Management
Conservative measures
RICE, NSAID’s, isometrics, orthotics to correct dysfunction
Surgical possibilities

66. Patellofemoral Stress Syndrome
Etiology
Result of lateral deviation of patella while tracking in femoral groove
Tight structures, pronation, increased Q angle, insufficient medial musculature
Signs and Symptoms
Tenderness of lateral facet of patella and swelling associated w/ irritation of synovium
Dull ache in center of knee
Patellar compression will elicit pain and crepitus
Apprehension when patella is forced laterally
Management
Correct imbalances (strength and flexibility)
McConnell taping
Lateral retinacular release if conservative measures fail

67. Osgood-Schlatter Disease and Larsen-Johansson Disease
Etiology
Osgood Schlatter’s is an apophysitis occurring at the tibial tubercle
Begins cartilagenous and develops a bony callus, enlarging the tubercle
Resolves w/ aging
Common cause = repeated avulsion of patellar tendon
Larsen Johansson is the result of excessive pulling on the inferior pole of the patella
Signs and Symptoms
Both elicit swelling, hemorrhaging and gradual degeneration of the apophysis due to impaired circulation

69. Signs and Symptoms (continued)
Pain w/ kneeling, jumping and running
Point tenderness
Management
Conservative
Reduce stressful activity until union occurs (6-12 months)
Possible casting, ice before and after activity
Isometerics

70. Patellar Tendinitis (Jumper’s or Kicker’s Knee)
Etiology
Jumping or kicking - placing tremendous stress and strain on patellar or quadriceps tendon
Sudden or repetitive extension
Signs and Symptoms
Pain and tenderness at inferior pole of patella
3 phases - 1)pain after activity, 2)pain during and after, 3)pain during and after (possibly prolonged) and may become constant
Management
Ice, phonophoresis, iontophoresis, ultrasound, heat
Exercise
Patellar tendon bracing
Transverse friction massage

72. Patellar Tendon Rupture
Etiology
Sudden, powerful quad contraction
Generally does not occur unless a chronic inflammatory condition persist resulting in tissue degeneration
Occur primarily at point of attachment
Signs and Symptoms
Palpable defect, lack of knee extension
Considerable swelling and pain (initially)
Management
Surgical repair is needed
Proper conservative care of jumper’s knee can minimize chances of occurring
If steroids are being used, intense knee exercise should be avoided due to weakening of collagen

73. Runner’s Knee (Cyclist’s Knee)
Etiology
General expression for repetitive/overuse conditions attributed to mal-alignment and structural asymmetries
Signs and Symptoms
IT Band Friction Syndrome
Irritation at band’s insertion - commonly seen in individual that have genu varum or pronated feet
Pes Anserine Tendinitis or Bursitis
Result of excessive genu valgum and weak vastus medialis
Due to running w/ one leg higher than the other
Management
Correction of mal-alignments
Ice before and after activity, proper warm-up and stretching
Avoidance of aggravating activities
NSAID’s and orthotics

74. Knee Joint Rehabilitation
General Body Conditioning
Must be maintained with non-weight bearing activities
Weight Bearing
Initial crutch use, non-weight bearing
Gradual progression to weight bearing while wearing rehabilitative brace
Knee Joint Mobilization
Used to reduce arthrofibrosis
Patellar mobilization is key following surgery
CPM units

75. Neuromuscular Control
Flexibility
Must be regained, maintained and improved
Muscular Strength
Progression of isometrics, isotonic training, isokinetics and plyometrics
Incorporate eccentric muscle action
Open versus closed kinetic chain exercises
Neuromuscular Control
Loss of control is generally the result of pain and swelling
Through exercise and balance equipment proprioception can be enhanced

76. Functional Progression
Bracing
Variety of braces for a variety of injuries and conditions
Typically worn for 3-6 weeks after surgery --used to limit ranges for a period of time
Some are used to control for specific injuries while others are designed for specific forces and stability
Functional Progression
Gradual return to sports specific skills
Progress w/ weight bearing, move into walking and running, and then onto sprinting and change of direction

77. Return to Activity
Based on healing process - sufficient time for healing must be allowed
Objective criteria include strength and ROM measures as well as functional performance tests