ME5200 - Orthopaedic Biomechanics:
Lecture 15
Tendon and ligament mechanics
Tendon and Ligament: Anatomy, Function and Mechanics
Jim Jastifer M.D.
Tendon vs. Ligament
Tendon: muscle to bone Ligament: bone to bone
Provide joint stability
Compositional differences between tendons and ligaments:
Tendon: Basic Structure
Transmits forces created in the muscle to the bone Composed of collagen and elastin embedded in a matrix of proteoglycan and water Synthesized by tenocytes and tenoblasts Each muscle has proximal and distal tendon
myotendinous junction: tendonmuscle osteotendinous junction: tendonbone origin: proximal tendon-bone insertion: distal tendon-bone
(From “Human Tendons” by Józsa and Kannus)
Tendon: Macroscopic Structure
60% water Composition (% of dry mass):
65-75% collagen (mostly type I, some type III) 2-3% elastin 2% proteoglycan
White in color Varies in shape (wide and flat, cylindrical, ribbon shaped) Powerful muscles have short and broad tendons (e.g. quadriceps) Muscles carrying delicate and subtle movements have long and thin tendons (finger flexors)
Tendon: Surrounding Structures
Tendons have to help a force (produced by muscle) act (on the bone).
Requires lots of structures to efficiently do so
Sheaths Pulleys Linings
Tendon: Surrounding Structures
Synovial sheaths
closed duct around tendons gliding on bone surfaces frequently observed in tendons of hand and feet the sheath is formed of two membranes: inner (visceral) and outer (parietal) sheets
Tendon: Surrounding Structures (From “Human Tendons” by Józsa and Kannus)
Epitenon fibers at 60 to the tendon axis. Reorient to 30 after stretching
Tendon: Surrounding Structures
Endotenon:
Thin network of crisscross collagen fibrils Envelopes the primary, secondary and tertiary fiber bundles together Proteoglycans are present between endotenon and tendon fibers hydration Allows fiber bundles to glide with respect to each other Carry blood vessels, nerves and lymphatics to tendon (From “Human Tendons” by Józsa and Kannus)
Tendon: Internal Architecture (From “Human Tendons” by Józsa and Kannus)
Blood Supply
Tendon: Internal Architecture
Crimping of tendons:
Wavy formation within fascicles Believed to result from crosslinking of proteoglycans Disappears when stretched and reappears when unloaded Removal of crimp dominates low strain range (<4%)
(From “Human Tendons” by Józsa and Kannus)
Tendon: Other components
Proteoglycans of tendon
Glucosaminoglycan’s (GAGs) of tendon
Function similar to cartilage Tensional zones of tendon have 0.2% GAG (mostly dermatan sulphate) Pressure zones have 5% GAG (mostly chondroitin sulphate)
Glycoproteins of tendon
“adhesive” function fibronectin (involved in repair processes) thrombospondin (cell-matrix adhesion) laminin (observed in myotendinous junction)
Tendon: Other Components
(From “Human Tendons” by Józsa and Kannus)
Tenocytes: Tendon-cells
Direct maintenance
Tendon: Biomechanics
Tendon and ligament are similar
Tendon generally stronger in tension because of more focused function Nonlinear behavior “Toe region”
Longer for ligaments because less organized
Properties not as sensitive to loading rates as other tissues (ALL) Strength highly age dependent (ACL)
Tendon: Mechanical Properties Tangent Modulus
Stress
B
C III
FAILURE
II
LINEAR
I
TOE
A
2
4
6
8
Strain (%)
Tendon: Biomechanics Force
Extension
Effect of increasing tissue cross-sectional area on loadextension: greater load, greater stiffness
This is how your body solves force-extension problems…or…
Tendon: Biomechanics Force
Extension
Effect of increasing tendon length on load-extension: less stiff, similar strength
Tendon: Biomechanics
Secondary biomechanical functions of tendons:
Eliminates unnecessary length of muscleallows body to optimize muscle fiber length Enables muscle belly to act at a distance from the joint Absorbs energy: limits damage to muscles and bone
Tendon: Mechanical Properties
Parameters measurable from loadextension curve:
Slope in region II: tangent stiffness/modulus linear load: load at the end of region II maximum load strain at maximum load strain to failure energy to failure (area under the curve)
Tendon: Mechanical Properties
In vitro tensile strength: 50-100 MPa
Tendon with 1cm2 area can carry 0.5-1 tons
Tensile strength of tendon is about twice the strength of the muscle it is attached to
Strength increase during maturation and then decreases
No gender-related differences in strength
Tendon Biomechanics
Parallel arrangement of collagen fibers to the direction of tensile force give tendons one of the highest tensile strengths of any soft tissue in the body. Two ways to characterize the tensile properties of tendon
Mechanical properties of the tendon
Stress-strain relationship
Structural properties of the bone-tendon-muscle unit
Load-elongation relationship
Tendon: Biomechanics
Challenges in conversion of load-extension curve to stress strain curve:
How to measure deformation
Specimen length for strain
Tendons are slippery
Definition of original length: ideal initial length is in the body Pre-strains are removed following dissection inducing slackness
Specimen area for stress
area is seldom uniform along the length caliper measurements prone to error due to compressibility of tissue indirect measurement of area: volume/length laser based techniques
Tendon: Deformation Mechanisms
Toe region
Changes are at light microscopic level Waviness of fiber bundles straightened out Continued elongation results in increased stiffness End of toe region ranges from 1.5-4% strain
Methods to quantify toe-region
Wertheim (1947) 2=c12+c2 (c’s constant) Morgan (1960) =c30.812 Elden (1968) =c42 Fung (1967) quasi-linear viscoelastic model L=L ec5(-)
Tendon: Deformation Mechanisms
Linear region
Ranges from 2-5% Tendon will recover to its original length if not strained beyond the linear region Common parameter is elastic or linear stiffness
Tendon: Deformation Mechanisms
Failure region
Collagen fibers slide past each other Possible rupture of crosslinks Reduction in stiffness Waviness reappears at an increasing rate indicating gradual rupturing of bundles Ruptured fibers/bundles recoil
Tendon: Viscoelasticity Rate dependency (rat tail tendon):
Force
high-rate
low-rate
Extension
Tendon: Viscoelasticity Preconditioning:
Tendon: Biomechanics of the tendon-muscle unit
Tendons function as a unit of a muscletendon-bone system Healthy tendon is seldom the weakest link of the system
Tendon: In vivo considerations
Patellar tendon forces:
5.2 kN during kicking 8.0 kN during jump 9.0 kN during fast-running 14.5 kN during competitive weight-lifting
3,300lbs
Tendon: Aging •Increase in collagen content •Decline in water content •Decrease in crimp
Elastic Modulus
•Increase in collagen cross-links
Age
Digression: Tendon vs. Ligament
What is elastin? Take a guess Both get mechanical properties, for the most part, from collagen
Digression: Tendon vs. Ligament
Ligament, Aging Important because age is probably more important than strain rate for failure
BIOLOGICAL TISSUES RESPOND TO THEIR LOADING ENVIRONMENT!!!!!!!!!!
Ligament Biomechanics
Like tendons, ligaments demonstrate time- and history-dependent behavior Clinically-relevant examples
ACL reconstruction: initial force applied to tension the graft decreases w/ time b/o stress relaxation
Intraoperative spinal distraction
Preconditioning can decrease amt of stress-relaxation by ~50% Can decrease peak forces on instruments and their insertions on vertebra b/o soft-tissue creep
Shoulder dislocations
Creep in capsular ligaments & soft tissues
Example 4.1
Modulus values in literature must be cautiously applied based on strain values
Clinical correlate ACL reconstruction
50% chance of osteoarthritis at seven year follow up
10-mm wide BPTB graft has stiffness and ultimate load values of 210 ± 65 N/mm and 1784 ± 580 N QSTG autograft, evolved from a single-strand semitendinosus tendon graft, has very high stiffness and ultimate load values of 776 ± 204 N/mm, 4090 ± 295 N, respectively). Which is better?
Question During
a one handed grip, which can you squeeze with more force, a pencil, a beer can, or a coffee can? Why?
Muscle Mechanics Jim Jastifer MD
Introduction
Muscle types:
Cardiac muscle: composes the heart Smooth muscle: lines hollow internal organs Skeletal muscle:
Skeletal muscle accounts for 40-45% of body weight
- 700 muscles
- 80 pairs produce vigorous movement
Dynamic & static work
Dynamic: locomotion & positioning of segments Static: maintains body posture
Introduction
Cells as opposed to extracellular matrix Several Properties
Responsiveness (excitability)-touch a hot stove
Conductivity
shortens when stimulated
Extensibility
local electrical change triggers a wave of excitation that travels along the muscle fiber
Contractility
capable of response to chemical signals, stretch or other signals & responding with electrical changes across the plasma membrane
capable of being stretched
Elasticity
returns to its original resting length after being stretched
Skeletal Muscle Voluntary striated muscle attached to one or more bones Muscle fibers (myofibers) as long as 30 cm Exhibits alternating light and dark transverse bands or striations
reflects
overlapping arrangement of internal contractile proteins
Under conscious control
Motor unit
One nerve cell activates several muscle cells
Sarcoplasmic reticulum
Network of tubules & sacs; Parallel to myofibrils Enlarged & fused at junction between A & I bands: transverse sacs (terminal cisternae) Triad {terminal cisternae, transverse tubule} T system: duct for fluids & propogation of electrical stimulus for contraction (action potential) Sarcoplasmic reticulum store calcium
Regulatory & Contractile Proteins
Myosin & actin are contractile proteins
they do work of shortening the muscle
Tropomyosin & troponin are regulatory proteins
act like a switch that starts & stops shortening
Overlap of Thick & Thin Filaments
Beer is always the answer Length-Tension Curve
Types of contraction
Muscle Twitch
Threshold is minimum voltage necessary to produce contraction
a single brief stimulus at that voltage produces a quick cycle of contraction & relaxation called a twitch
Phases of a twitch contraction
latent period (2 ms) is delay between stimulus & onset of twitch contraction phase is period during which tension develops and shortens relaxation phase shows a loss of tension & return to resting length refractory period is period when muscle will not respond to new stimulus
Production of Variable Contraction Strengths
Stimulating the nerve with higher voltage get stronger contractions because recruit more motor units Stimulate the muscle at higher frequencies (stimuli/sec) up to 10Hz, produces twitch contractions with full recovery between twitches 10 - 20, each twitch develops more tension than the one before due to failure to remove all Ca+2 20 - 40, each stimulus arrives before the previous twitch is over temporal or wave summation produces incomplete tetanus 40 - 50, no time to relax between stimuli so twitches fuse into smooth prolonged contraction called complete tetanus (normal smooth movements)
Recruitment & Stimulus Intensity
Maximal recruitment
Histology of muscle
Type IIA Type IIB Type I
Eye muscle (Rectus lateralis); Myofibrillar ATPase stain, PH 4.3
Muscle Differentiation (types of fibers) I (slow-twitch oxidative)
IIA (fast-twitch oxidative glycolytic)
IIB fast-twitch glycolytic
Contraction speed
Slow
fast
fast
Myosin-ATPase activity
Low
High
High
Primary source of ATP Oxidative production phosphorylation
Oxidative phosphorylation
Anaerobic glycolysis
Glycolytic enzyme activity
Low
Intermediate
High
No. of mitochondria
Many
Many
Few
Capillaries
Many
Many
Few
Myoglobin contents
High
High
Low
Muscle Color
Red
Red
White
Glycogen content
Low
Intermediate
High
Fiber diameter
small
Intermediate
Large
Rate of fatigue
slow
Intermediate
Fast
Functional arrangement of muscle
pinnated angle of muscle
The Musculotendinous Unit
PEC: parallel elastic component CC: contractile component SEC: series elastic component
Tendon- spring-like elastic component in series with contractile component (proteins)
Parallel elastic component (epimysium, perimysium, endomysium, sarcolemma)
Muscle mechanics Static contractions Twitch, summation, tetanus: 60hz
Brooks et al.
Motor unit recruitment All-or-nothing event 2 ways to increase tension: - Stimulation rate - Recruitment of more motor unit
Size principle Smallest m.u. recruited first Largest m.u. last
Influence of parallel elastic component
Fc
Ft
Ft
Fp
Fp l0
Fc
l0
Force and Velocity •Force diminishes with increase in velocity •Maximum force can actually be generated with eccentric contractions (1.8 times isometric max) •Power= Force * Velocity
Force-Velocity Characteristics
Concentric contraction
Muscle contracts and shortening, positive work was done on external load by muscle Tension in a muscle decreases as it shortens
Eccentric contraction
Muscle contracts and lengthening, external load does work on muscle or negative work done by muscle. Tension in a muscle increases as it lengthens by external load
Length and velocity versus Force
Note: maximum contraction condition; normal contractions are fraction of the maximum force
Muscle fatigue
Drop in tension followed prolonged stimulation. Fatigue occurs when the stimulation frequency outstrips rate of replacement of ATP, the twitch force decreases with time
Muscle mechanics To review, determinants of force/power production by a muscle 1. # of motor units recruited (i.e., the cross-sectional area of the active muscle) 2. frequency of stimulation 3. length of the fibers relative to Lo 4. velocity (shortening and lengthening) a. myosin ATPase activity b. SR concentration 5. muscle architecture a. orientation of fibers to the long axis b. the # of sarcomeres in series
Obesity
There is a dose-response relationship between obesity and Osteoarthritis.
Increase in body weight proportionatly increases forces across weight bearing joints.
Changes in obesity
