Knee Overview Summary PDF

Summary

This document provides a comprehensive overview of the knee joint, including its function, anatomy, and biomechanics. It covers the various motions of the knee, the roles of ligaments and muscles, and the different types of knee injuries.

Full Transcript

6.1 Knee Overview

Knee Fxn
•

lower/elevate body weight

ex: sitting, squatting, climbing
•
•

joints of knee
•

tibiofemoral

•

patellofemoral

•

rot of body over planted foot
walking & running sustaining vertical forces 4x6 bw

knee jt motions
•

hinge jt (2 DOF)

•

2 planes (flex/ext, IR, ER)

•

combination of motions

•

driven by geometry of jt, soft tissue, muscle actions (distal femur/prox tibia)

•

influences jts above and below

knee open chain = distal end free
ex: kick leg out while sitting
-

knee closed chain = distal end fixed
ex: sit to stand

knee angle

normal angle of inclination of prox femur: 125 degrees
normal angle of lateral knee: 170-175 degree
NORMAL GENU VALGUM!!

Genu valgum: angle less than 170
Genu varum: angle greater than 180

Line of Force
•

weight bearing down lower extremity: center of hip to center of ankle jt

•

lets weight bearing be equally distributed b/w medial & lat condyles of knee

mechanical axis goes down head of femur & condyles

Intercondylar notch
ligaments found here

•

ACL/PCL
size of notch can vary

•

proximal tibia
•

med/lat epicondyle

•

intercondylar area: cruciate ligament attachment

•

tibial tuberosity: distal attachment for quadriceps femoris
muscle via patellar tendon

meniscus: shape
•
•

crescent shaped fibrocartilage
lateral meniscus
- deeper
- more circular
- more mobile
- o shape

•

medial meniscus
- more oval/semi lunar (C shape)
- less mobile
- gets injured more

blood supply/ attachments
•

greater near outer border

•

medial meniscus: attachments to MCL & jt capsule

•

lat meniscus: attachment to jt capsule & popliteal
tendon passing b/w lat meniscus and LCL

ex: tear on inner 3rd, wont repair bc can’t heal as much

meniscus fxn:
•

accept/disperse compression in tibfemoral jt

•

assist w/ jt stab

•

lubricate art cart

•

assist w/ arthrokinematics of knee

Ligaments
collateral: medial collateral ligament/lat collateral
cruciate: ant/post cruciate

medial collateral ligament
•

cross med aspect of knee

•

broad & flat fan shaped

•

blend w/ medial patella reticular fibers

•

attaches to medial meniscus

•

resist valgus stress

lat collateral ligament
•

crosses lat aspect

•

long rope like

•

distal blend w/ tendon of biceps femoris

•

resist varus stress

collateral ligaments
•

taut in ext

•

slack in flexion

•

allows axial rot of knee in flexion

cruciate ligament (ACL & PCL)
•

cros in intercondylar notch

•

named according to attachment to tibia

•

resist forces in all planes of knee for stab

•

resist ant/post motion of tibiofemoral jt

•

less taut in 30-50 degrees flexion

ex: shear in everyday activities (walking, running, squatting & jumping
can do lachman test

Anterior Cruciate Ligament
1.

extends from med to lat femoral condyle

2. runs oblique/med to attach to anterior intercondylar area of tibial plateau
3.

primary fxn resist ant translation of tibia on femur

4. becomes taut near full ext
anterior translation on femur

Posterior cruciate ligament (PCL)
•

extends from lat side of med femoral condyle to post intercondylar area of tibia

•

thicker than ACL

•

taut w/ greater flexion of knee (90-120)

•

prevents excessive ant translation of femur on tibia or posterior tib translation on femur

summary: knee jt largest jt w/ congruency bc geometry, meniscus provide shock/absorption & increase
stab, provide stab through all motions

6.2 Knee Biomechanics
Patellofemoral Joint (PFJ)

PFJ Joint: Function
-protects knee jnt
-mechanical advantage for
quadriceps

Patella
-triangular bone embedded in quadriceps

Medial facet is larger in size w

tendon

extra facet on the edge

-biggest sesamoid bone in the body
-covered w thick layer of cartilage; ideal for
compressive forces
-vertical ridge & medial/lateral facet

Role of the Muscles: Quadriceps
4 muscles
1. Vastus lateralis (VL)
2. Vastus intermedius (VI)
3. Rectus femoris (RF)
4. Vastus medialis (VM)
•

net force on VL and VM result in compression of the
patella

Patellofemoral Motion
-medial/Lateral slide
-medial/Lateral Tilt
-superior/Inferior slide
flex

ex

-medial/Lateral Rotation

Biomechanics of the Patella
Important because of the moment arm from
the axis of the femur it creates a longer
movement arm
Someone without a patella would
require greater force of the quads
to extend the knee

PFJ: Squats
PF compression is a resultant vector
between the patella and femur
•

little compression

•

compression increases

•

significant compression with squats to
90°

PFJ: Compression
-bw 90-60° flexion the patella is in contact w
femoral intracondylar groove
•

considered area or degrees of greatest

compression or contact area
•

bw 30-20° flexion the patella begins to lose
contact w the intracondylar groove

Knee Joint: Axis
-since femur slides as it moves into flex & ex the axis
of motion changes during the range of motion.
-instantaneous center of rotation or ‘evolute’
Makes it difficult to develop total knee replacements
that replicate the knee in a mechanical situation or
even braces that can say they can control the
rotation or the axis of the knee

Axial Rotation of the Knee
•

rotation increases w increased flex

•

greatest rotation at 90°

•

ER exceeds IR w a ratio of 2:1

•

rotation restricted at full ex

Axial Rotation of the Knee
-occurs in open chain & in close chain
-consider tibia moving on femur or femur
moving on fixed tibia

Arthrokinematics: OKC knee ex
Tibia on Femur leg ex
•

Tibia slides anteriorly on the femoral
condyles
-anterior roll and slide

Menisci are pulled ant by the quadriceps
Open chain- concave tibia on a convex
femur

Arthrokinematics: CKC knee extension
Femur on Tibia leg ex
- femoral condyles roll anteriorly and
slide posteriorly
-Quadriceps stabilize menisci against shear

Screw Home’ Mechanism: OKC
•

‘Conjunct rotation’ meaning is cannot occur
exclusively by itself.

•
•
•

Combo of rotation & flex-extension
Optimizes congruency and increases stability
Locking the knee requires about 10 degrees ER

Arthrokinematics: OKC Knee Joint
Flexion
•

tibia moving on femur

femur will internally rotate on a

•

Menisci

relative external rotated tibia to

•

Pulled posterior by hamstrings/

post roll and glide

Screw Home Mechanism: CKC
•

popliteus contraction

cause screw home locking
mechanism

Role of the Popliteus
-Laterally rotates the femur on the tibia
(to ‘unlock’ the knee in order to....ie squat)

Role of the Hamstrings
•

Assists in medial rotation of the tibia & flex at

Flex of the knee in OKC: assists w
post tibial glide

the knee
-Assists in pulling the lateral meniscus
posterior
-Assists in unlocking an extended knee
-Provides some lateral knee stability

Arthrokinematics: CKC Knee Joint Flexion
Femur moving on tibia
-post roll/anterior glide
Menisci
-move posterior (lateral >medial)

Summary
• convex femur & concave tibia create arthrokinematics of the knee joint
• patella glides along the femur and is compressed by tension in the quadriceps
• conjunct rotation occurs at the tibial-femoral joint to create a screw home mechanism
for locking in ex

6.3 Ankle & Foot Overview
1.

Primarily shock absorption & conforming to forces that occur when striking the ground

(also protects & sends feedback to muscles of LE)
2. walking, running
3. changing dir/pivot
4. propulsion forces to jump & leap
5. proprioceptive to maintain balance

Ankle joint: talocrural jt
•

talus, tibia, and fibula

•

aka mortise joint

Weight bearing
•

mortise = 90% of load transferred through limb

•

lateral structures/talus/fibula = 10%

Foot joints
•

subtalar jt - INV/EV, predicts pronation/supination!!

•

transverse tarsal jt

•

tarsometatarsal jt

•

metatarsophalangeal jt

•

interphalangeal jt

3 foot sections
1.

rearfoot: talus & calcaneus

2. mid-foot: tarsal bones
3.

Forefoot: metatarsals, phalanges

transverse tarsal jt
Talonavicular & Calcaneocuboid
•

connects rear foot to midfoot

•

tells us what happens at subtalar jt (stability depends on
position of this)

•

allows foot to adapt to all types of surfaces via pro/sup

midfoot to forefoot
•

distal intertarsal jts assist w/ pro/sup

•

tarsometatarsal jts: 2nd & 3rd provide stab while rest provide mob

•

metatarsalphalangeal jts: ext (DF) flex (PF), abd, add (CONCAVE/
CONVEX)
ex: first/first toe want to reach ground so want it mobile to
propel forward

deltoid/medial collateral ligaments

lateral collateral ligaments

inner intertarsal ligaments: soft tissue restraint

medial longitudinal arch of foot
•

primary load bearing & shock absorbing structure

•

helps foot adapt to surfaces

•

rigid lever for propulsion

Windlass Mechanism
plantar aponeurosis assists in arch support as well as

•

intrinsic muscles
•

when the MTP hyperextends tension occurs on aponeurosis

•

causes longitudinal arch to rise

•

rigid lever for propulsion

ex: ant/post strut
(is idk what)
tie rod = intrinsic
muscles & plantar
fascia
Distal tibiofibular jt
interosseuos membrane b/w tibia and fibula

•
•

distal TF jt is syndesmosis jt

•

stabilized mortis and hold distal tibia and fibula together

lower extremity kinematics
•

pronation @ foot leads to med rot @ tibia/fibula/femur

•

supination @ foot leads to rot of adjacent structures

why sup important?
•

closed pack position

•

helps with arch during push off in windlass

•

allows to propel

Summary
•

ankle jt accepts majority of forces in closed chain activities

•

motion at foot determined by position of hind foot

•

foot adapts to surfaces and helps w/ propulsion

6.4 Ankle & Foot Biomechanics
Foot Motions
-dorsi & plantaflexion occur in sag plane
around a medial-lateral axis
-inversion & eversion occur in a frontal plane
around a anterior-posterior axis
-ABD & ADD occur in a transverse plane
around a vertical axis

Pronation & Supination
•

motions occur in all 3 planes so they are
triaxial motions

•

this is due to the oblique angles at both
talocrural jnt & subtalar jnt

•

these motions can be described in both
open & close chain

Supination & Pronation: Components
Supination
-combo of inversion, plantarflexion & ADD
Pronation
-combo of eversion, dorsiflexion & ABD

Close/Loose Packed Position
Close-packed position of foot is supination
- Provides a rigid foot structure
Loose-packed position is pronation
- foot is supple & flexible

Talocrural Joint: axis
-talocrural jnt- 1 degree of
freedom
-axis passes through talus
through tips of malleoli

Arthrokinematics: Dorsiflexion
Convex talus rolls forward relative
to the leg while gliding posteriorly
on a concave tibia
•

convex on concave

Arthrokinematics : Gait
•

Main jnts active: talo-Crural & transverse
tarsal

•

Heel Strike: rapid DF->PF
- ant tib works to prevent foot slap

•

Early foot flat: foot must pronate to absorb
shock

•

Late foot flat: foot must supinate (rigid lever)
for push off
-Knee comes into ext, with relative ext tib

rotation...
•

Heel rise: moving into PF on supinated foot

Closed Kinetic Chain: Gait
1. Ankle rapidly plantar flexes to reach the
ground
2. During flat foot phase of gait, leg starts to
rotate forward over foot (dorsiflexion) pro
3. Dorsiflexion continues until just after heel
off tibia moves over ankle pro
4. The ankle becomes very stable at push off
as the talus wedges into the mortise with
weight bearing

Subtalar Joint
Small changes occur to allow arch to
adapt to absorb forces during wt
acceptance

Arthrokinematics: Plantarflexion
Convex talus rolls posteriorly while
gliding anteriorly on a concave tibia
•

convex on concave

Subtalar Joint: Axis
Multiplanar motion comes
from an oblique axis

Subtalar Joint Surfaces
•

3 articulations between talus &
calcaneus

•

concave posterior facet of talus on
convex calcaneus responsible for
majority of the articulation

•

2 ant flat articulations

Arthrokinematics: Subtalar
-Roll & slide are in opposite
directions in an open chain

Pathomechanics of Gait

Convex calcaneus on a concave

- When foot fails to supinate

talus

in late stance, the foot is too

-subtalar eversion

supple to provide a rigid lever

-subtalar inversion

for push off
-Wt is transmitted medially &
carried through toe off
- medial side of the great toe
is the last point of contact.

Transverse Tarsal Joint
•

Hallux valgus develops.

roll and slide are in the
same direction for
plantarflexion and
dorsiflexion

Practical Application

In CKC

Pronation
-calcaneal eversion
-talar adduction &
plantarflexion
-tibiofibular medial
rotation

Summary
• ankle & foot have oblique axes
allowing foot to move in 3 planes
• subtalar joint dictates motion at the
midfoot in a close chain position
• alteration of the mechanics of the
ankle & foot can lead to pathology &
altered gait

in the review can u explain why moment arm plays a part in putting bag on ipsi side