Periarticular Connective Tissue 2024 Student PDF

Summary

This document is student notes on periarticular connective tissue. It covers the components of connective tissue, types of periarticular connective tissue like dense connective tissue, articular cartilage and fibrocartilage, their structure, function, and response to aging, injury, loading and unloading. The document includes discussion on tendon, ligament and joint capsule biomechanics, function, injury and healing.

Full Transcript

Periarticular Connective
Tissue
Andrew Sprague, PT, PhD, DPT
Periarticular Connective Tissue
 Periarticular Connective Tissue
Components of Connective Tissue
Fibrous Proteins
Ground Substance
Cells
Types of Periarticular Connective Tissue
Dense Connective Tissue
Structure; Function;
Joint Capsule, Ligaments, Tendons
Response to Aging, Injury,
Articular Cartilage Loading and Unloading
Fibrocartilage
Bone
Periarticular Connective Tissue
Capsule, ligament, tendon, articular cartilage, and
fibrocartilage
Basic Components:
1. Fibrous proteins: Collagen and elastin
2. Ground substance: Glycosaminoglycans, water, and solutes
3. Cells: Fibroblasts, tenocytes, and chondrocytes
The relative amount and types of these components
dictate structure and function
 Fibrous Proteins
Collagen: Most common protein in the
human body
Collagen molecules  tropocollagen (threads) 
fibrils  fibers
Type I: Thick, strong fibers that resist tension well
Ligaments, tendons, fascia, and joint capsule
Type II: Thinner fibers that provide scaffold for
other types of tissue, better resistance to
compressive loads
Hyaline cartilage
Type III: Present in the same tissues as Type I
but thinner and weaker.
Associated with scar tissue and injury.
Fibrous Proteins
Elastin: Elastic (stretchy) proteins
Resists tension but less well than collagen
Helps maintain the structure of tissues - return
to original shape after being loaded
 Ground Substance
Water-saturated matrix or gel that surrounds
the fibrous and cellular components of
connective tissue
Glycosaminoglycans: Hydrophilic (water-loving)
chains of polysaccharides (sugars)
Provides hydration by bringing in water
Helps provide resistance to compression
Solutes: Ions and other materials that enter
through diffusion to support the cells within the
ground substance

What are the consequences of reduced
glycosaminoglycans?
Cells
Responsible for synthesizing the ground substance and
fibrous proteins of the respective tissues
Fibroblasts: Primary cells in ligaments, tendons and most other
connective tissues
Chondrocytes: Primary cells of articular cartilage and fibrocartilage
Other cells break down and remove aging/injured
components of the tissues
Relatively few cells in periarticular connective tissue
compared to other types of connective tissue
Types of Periarticular Connective
Tissue
1. Dense Connective Tissue
Joint capsule, ligaments, and tendons
2. Articular Cartilage
3. Fibrocartilage
 Dense Connective Tissue
Few cells, low to moderate amounts of
proteoglycans and elastin, high amounts
of Type I collagen, and limited blood
supply
Irregular: Haphazard orientation of collagen
fibers
Adapted to resist multi-directional forces
Regular: Orderly orientation of collagen
fibers
Adapted to resist forces in a single or relatively few
directions
What type of dense connective tissue is joint capsule?
Ligament?
Tendon?
Primary Types of Dense Connective
Tissue
1. Tendon
2. Joint Capsule
3. Ligament

We will use tendon as a model for discussing the
behavior of dense connective tissue
 Tendon Composition
Muscle  Bone
Highly organized, parallel collagen
fiber bundles
70-80% Type I Collagen
Embedded in extracellular matrix
Surrounded by epitenon/paratenon
Reduces friction
Tenocytes (tendon cells) sit between
collagen fibers
Aslan et al. 2008.

Wang et al. 2012.
Function of Tendon
Transmit forces from muscle to
bone
Energy conservation (spring)
Protect muscle from injury

Adapted from Primal Pictures. 3D Atlas. Available at: Anatomy.tv

Roberts & Konow 2013; Monte et al. 2020
 Tendon Biomechanics
Tension Compression
Very well adapted to resist tension
Not well suited for compression
Viscoelastic structure
Response to loading (function) is dependent on
rate and duration of loading

Adapted from: Netter. Atlas of Human Anatomy. 5 th ed.

Wang et al. 2012; Docking et al. 2013; Khan & Scott, 2009
Tendon Mechanobiology
Cells sense load  Trigger a biological response
Tendons are metabolically active
Respond to changes in their loading environment
Tenocytes experience shear and compression forces during loading 
remodeling

Khan & Scott, 2009
 Tendon Response to Load
Underloading: Excessive Overload:

Load
Rest/Immobilization Overload + Inadequate
Short term (1-2 weeks) Recovery
unloading reduces tendon Leads to injury
stiffness and collagen
production

Khan & Scott, 2009; Magnusson & Kjaer 2019
 Joint Capsule
Envelope or sac that surrounds and
encloses a joint
Fibrous (outer) layer – Irregular connective
tissue
Synovial (inner) layer
Mechanosensitive – Adapts to
loading demands
Primarily Type I collagen but
composition varies by joint
 Function of Joint Capsule
Enclose the joint to help maintain the
articular environment
Provides joint stability
May be thickened in specific areas to
form capsular ligaments
Proprioceptive feedback
Produces synovial fluid to lubricate
and provide nutrition to joint Iliofemoral ligament (Y-ligament) is a
capsular ligament
Ligament
Bone  Bone
Similar hierarchical structure to tendon
Densely arranged collagen fibers but not always in parallel
Less collagen but more elastin and proteoglycans than tendon
More metabolically active than tendon

Tendon Ligament
 Types of Ligaments
Capsular Ligaments
Thickenings of the joint capsule
Oriented to resist multi-directional forces
Intra- or Extra-capsular Ligaments
More rope-like
Capsular ligaments of hip
Typically oriented to resist 1-2 forces

Lateral collateral
ligament (LCL) ACL and PCL
outside joint inside of joint
capsule (capsule
resected)
Function of Ligaments
Resists excessive joint motion
Guide joint motion
Provide proprioceptive feedback
 Dense Connective Tissue Injury
Overuse: Repetitive microtrauma
with inadequate recovery leads to
damage accumulation
(degeneration)
Acute: Application of stress that
exceeds the failure point of the
structure
May be preceded by degeneration that
lowers failure point’
Can be complete or partial rupture
Overuse Dense Connective Tissue Injury
Load Tolerance

Load Tolerance
Injury

Time/Recovery Time/Recovery
= Net collagen degradation (breaking down)
= Net collagen synthesis (building up)

Magnusson & Kjaer 2019; Miller et al. 2005
Rate of Force Application
Forces can be applied to ligaments and tendons at
various speeds
Not 100% predictive of injury
High rate of loading ≈ Rupture
Lower rate of loading ≈ Avulsion
 Soft Tissue Healing

Seconds to Hours
Hours to Days
Days to Weeks
Weeks to >1 Year
1) Hemostasis (Bleeding) Phase
Vessels constrict to slow bleeding
Platelets stick together to form an
immature clot
Fibrin binds to clot to reinforce it and
hold it in place
2) Inflammatory Phase
Pro-inflammatory chemicals at wound
site trigger inflammatory response
Neutrophils and macrophages begin to
remove:
Bacteria and foreign materials
Damaged cells
3) Proliferative (Repair) Phase
Fibroblasts proliferate and lay down
extracellular matrix and disorganized
collagen fibers (Type III)
Granulation tissue
Angiogenesis: New blood vessels form
4) Remodeling Phase
Weak, disorganized Type III collagen
(scar tissue) replaced by stronger Type
I collagen
Collagen fibers begin to align to
stresses placed on tissue
If not mobilized, scar tissue can
contract and limit joint motion
 Importance of Mechanical Stress During
Healing
Moderate stress induces organization
of collagen in a more parallel
arrangement in the direction of
applied forces
Minimizes contraction of scar
During early phases of healing,
movement of joint appears to be Disorganized scar tissue  Organized Type I
sufficient stress

Smaller diameter Type III  Larger diameter Type I
Effects of Temperature
Viscoelastic properties change with heat to allow
greater stress relaxation and creep
Stress relaxation increases when tissues are heated
>98.6°
Less time is needed to reach a given strain in response
to stretching when heated
 Response to Prolonged
Immobilization
Arthrofibrosis: Excessive collagen production (scar
tissue) and adhesion formation resulting in restricted joint
Reduced tensile strength motion and pain.
50% loss after 8 weeks
12 to >18 months to restore
Adaptive shortening of
structures
Especially joint capsule
Changes occur even in
uninjured structures

Usher et al., Bone Res. 2019
 Effects of Age and Aging
Adolescent:
Dense connective tissue stronger than bone
More likely to experience avulsion fracture than
rupture
Old Age:
Potentially degenerative changes
Alterations to fibroblast metabolism/remodeling
ability
Reduction in stiffness, strength, and collagen
content
Appears to be more related to decreased activity and
inactivity than aging itself
Types of Periarticular Connective
Tissue
1. Dense Connective Tissue
Joint capsule, ligaments, and tendons
2. Articular Cartilage
3. Fibrocartilage
 Cartilage
Strong but elastic connective tissue
Composed of chondrocytes, collagen, and
matrix
70-85% water by weight
Avascular and aneural
Usually surrounded by perichondrium
Contains blood vessels and nerves
Provides nutrition and maintains tissue
 Chondrocytes
Mature cartilage cells
May be in groups called Lacunae
Produce and maintain the
cartilaginous matrix
Sparsely distributed
Types of Cartilage

1. Articular (hyaline) cartilage
Bluish white appearance
Reduces friction and absorbs shock at joints
Weakest of the three types of cartilage
2. Fibrocartilage
Intervertebral discs, pubic symphysis, menisci
Strongest of the 3 types of cartilage
3. Elastic cartilage
External ear, arteries, lung tissue
 Articular Cartilage
Specialized type of hyaline cartilage
on the load-bearing surfaces of
joints
Lacks a perichondrium
Implications?
Chondrocytes surrounded by Type
II collagen
Articular Cartilage
Roles:
Distribute and disperse
compressive forces
Reduce friction between joint
surfaces
5-20x more slippery than ice on ice
 Articular Cartilage
Superficial tangential zone (STZ):
Collagen fibers parallel to articular surface
Highest collagen and lowest proteoglycan content
Flat chondrocytes
Middle Zone:
Oblique collagen fibers
Thickest layer
Round chondrocytes
 Articular Cartilage
Deep Zone:
Perpendicular collagen fibers
Highest concentration of
proteoglycans
Calcified zone:
Anchors cartilage to bone
Tidemark
Separates calcified zone from
subchondral bone
Diffusion barrier between
cartilage and bone
 Articular Cartilage Nutrition
Nutrition provided by diffusion
Deformation of articular surface during
intermittent joint loading
“Washes” synovial fluid in and out of
cartilage
Also provides lubrication
Response to Reduced Loading

Reduced nutrition: may lead to degenerative changes
Reduced lubrication: Increases friction between joint
surfaces  degenerative changes
Response to Immobilization/Unloading

Consequences of reduced loading +
Decreased cartilage thickness
Reduced chondrocyte density
Reduced collagen content
Softer and weaker
 Response to Excessive Loading
(Injury)
Damage to collagen fiber network
Fibrillation: Cartilage becomes less smooth
Proteoglycan loss  decreased fluid
content
Decreased stiffness
Loses ability to respond to
compressive and shear forces
Response to Impact Loading
Occurs when loads are applied at a fast rate
Cartilage becomes stiffer
Unable to deform and redistribute loads fast enough
Effect of Aging on Cartilage
Imbalance between breakdown
and repair
↓ Thickness
Calcification of the cartilage
tissue
Increased cross-linking
↑ Stiffness
↑ Susceptibility to fatigue failure
Reduced chondrocyte density
Types of Periarticular
Connective Tissue
1. Dense Connective Tissue
Joint capsule, ligaments, and tendons
2. Articular Cartilage
3. Fibrocartilage
 Fibrocartilage
Mixture of dense connective tissue and
articular cartilage
Strength and shock absorption of articular cartilage +
tensile strength of ligament and tendon
Dense and multidirectional collagen
network
Type I collagen and moderate amounts of
proteoglycans
Resists multidirectional tensile, shear, and
compressive forces

Also in hip and shoulder
labrum, TFCC (wrist)
Fibrocartilage Function

1. Help supports and stabilize joints
2. Guides movement (arthrokinematics)
3. Dissipates forces
Fibrocartilage
Like articular cartilage, lacks a perichondrium
Nutrition provided by diffusion of synovial fluid
Intermittent loading
Similar response to loading, unloading, and aging as
articular cartilage
 Composition of Bone
Fibrous proteins:
Primarily Type I Collagen
Cells
Osteoblasts – bone-building cells
Osteocytes – mature bone cells
Osteoclasts – resorb bones
Ground substance
Mostly calcium phosphate – provides rigidity
Mineral salts crystallize in the framework created by the collagen –
calcification
Water, proteoglycans, and other materials
Function of Bone
Support
Protection
Assist in movement
Mineral and fat storage and
release
Blood cell production
Structure of Bone
Comprised of two layers:
1) Compact (Cortical) Bone: Dense
outer layer
2) Cancellous (Trabecular) Bone:
Spongy, inner core
 Compact (Cortical) Bone
Exterior of bones
Thick around the middle of the bone
Thinner at ends of long bones

Provides protection and support
Resists stresses from weight and movement
Osteon: Structural unit of compact bone
Collagen and mineralized ground substance organized in
concentric rings (lamellae)
Arranged in the direction of the stresses they encounter
Ex: parallel to the long axis of the bone in the shaft

Surrounded by periosteum
Supplies blood vessels
 Cancellous (Trabecular) Bone
More metabolically active than
compact bone
More flexible than compact bone
Transmits and distributes forces
along the long axis of the bone
Wolff’s Law
Bone constantly alters shape, strength, and density in response
to external forces
“Bone is laid down in areas of high stress and reabsorbed in
areas of low stress”

Immobilization or Weightbearing
Inactivity Activity
Pediatric Adult
Mechanical Properties of Bone
Subjected to several types of loading
Greatest strength (failure stress) in compressive loading
Different bones (or portions of a bone) are better suited for
handling different types of stresses
E.g. Weight-bearing long bones vs. flat bones
 Fractures

Named according to location, severity, and/or shape
Open Fracture: Bones penetrate the skin
Closed Fracture: Skin remains intact
Displaced Fracture: Bones out of position relative to original orientation
Stress Injury: Repetitive overload with inadequate recovery and/or nutrition
May progress to a stress fracture
Fracture Healing
1. Formation of Hematoma (Days 1-5)

Fracture tears blood vessels, hematoma forms and clots
Hematoma provides a temporary framework for the repair
Neutrophils, macrophages, and osteoclasts migrate to
hematoma
Swelling and inflammation occur
Cells remove the dead/damaged cells and tissue
 Fracture Healing
2. Fibrocartilaginous Callus Formation (Days 5-11)

Angiogenesis (new blood vessel)
formation
Fibrin-rich granulation tissue forms
(strengthens clot)
Mesenchymal stem cells differentiate
into:
Fibroblasts
Chondroblasts
Osteoblasts
Fibrocartilaginous tissue bridges
fracture gap
Bone begins to form under the
periosteal surface
 Fracture Healing
3. Bony Callus Formation (Days 11-28)

Ossification of callus
Continued laying down of
bone under periosteal
surface
Further angiogenesis
Brings cells deeper into the
fracture site
 Fracture Healing
4. Bone Remodeling (Day 18+)

Repeated remodeling
Absorption by osteoclasts
New bone formation by
osteoblasts
Lasts months to years
Restoration of normal
architecture
Influenced by loading
environment
Response to Loading
Responds favorably to compression loads
Will grow stronger and in the direction of compression loads
Increased deposition of mineral salts and production of collagen fibers
Application of weight-bearing in the remodeling stage of fracture
healing is critical
Reduced compression may occur from lack of weight
bearing or muscle force on bone
Less deposition of bone, with same resorption rate results in reduced
bone mass
Bone will become mechanically weaker
 Response to Unloading
Occurs after fractures, comas and other
diseases/conditions
Reduced compression and tensile strain
from lack of weight bearing and muscle
force
Less deposition of bone, with the same resorption
rate results in reduced bone mass
Bone will become mechanically weaker
Greater impact on weight-bearing bones Bloomfield S.A., Med Sci Spots
Exerc. 1997.
Effects of Aging
Resorption > Deposition
Reduced Bone Mass
Bone becomes stiffer (brittle)
Mechanically weaker
Changes with age may be delayed with activities that encourage
muscle force and weight bearing loads
 Osteopenia and Osteoporosis

Resorption >>> Deposition
Depletion of calcium
Decreased estrogen and testosterone
Osteopenia: Reduced bone mineral
density
Osteoporosis: Bone mineral density
scores >2.5 standard deviations below
normal
Questions???