Bone, Cartilage, Joint Anatomy Slides PDF

Summary

These slides cover bone and cartilage anatomy, including classifications, structures, cells, and functions. They also explain different types of joints and their stability, along with examples. This material is suitable for a college or university-level study of human anatomy and physiology.

Full Transcript

PT7001 / PT4050

Bone, Cartilage, Joint Anatomy
Mia Preece
[email protected]
Lecture Aims
 Explain what bone and cartilage are and describe how they are classified

 Describe the structure of spongy (trabecular) and compact bone

 List the cells of cartilage and bone, their matrix components and give their
functions
 Define the parts and functions of the skeleton

 List the anatomical terms used to describe bones

 Provide a classification of the different types of joints, and be able to
describe these and name examples of each
 Describe the structure and role of capsular ligaments and intra-articular
discs
 Describe the different structures that determine joint stability
 Skeleton

 ~ 206 bones in adult

 (300 in babies -> fuse)

 more then half in hand & feet

 cartilage also part of skeletal system
Axial or Appendicular
Axial Skeleton
≈ 80 bones

SKULL
22 bones of
Face (14) and skull (8)

RIB CAGE
Sternum and Ribs
12 pairs of ribs
True ribs 1-7
False ribs 8-12
(Floating ribs 11 & 12)

VERTEBRAL COLUMN
Divided into 5 sections:
Cervical - 7
Thoracic - 12
Lumbar - 5
Sacral - 5 (fused)
Coccyx - 3-5 (fused)
Appendicular
Skeleton

 Consists of 126 bones

 Phalanges x 56

 Tarsals and Carpals x 30

 Metatarsals and metacarpals x 20

 Radius, ulnar, tibia and fibula

 Humerus and femur

 Pelvis (ilium, ischium, pubis)

 Patella

 Clavicle, scapula
Axial vs Appendicular
Quiz

 This part is mostly responsible
for movements such as walking,
running, eating, waving..............

 This part is responsible for
protection of vital organs............

 Consists of around 80 bones.....

 Consists of around 126 bones...

 The part is mostly responsible
for posture..................................
Bones
Bone Composition
5 Roles of Bone - What are they?
Structure of Bones

 Diaphysis - long shaft

 Epiphysis - rounded ends

 Periosteum - outer layer

 Epiphyseal line (growth plate)

 Medullary cavity - bone marrow

 Articular cartilage
Structure of Bones
 Compact Bone

Compact (Cortical) Bone
 The basic unit of structure is the
osteon - Haversian Systems

 Each osteon is composed of
calcified matrix called lamellae

 Down the centre runs the central
canal (Haversian Canal) through
which blood, nerves and lymph
vessels pass

 The osteocytes are located inside
spaces called lacunae
 Spongy Bone

Spongy Bone
(Cancellous/Trabecular)
 Found in the epiphysis
 Mainly in long bones
 Porous
 Lightweight
 Irregular arrangement to increase
strength
 Consists of a system of struts and
plates (Trabeculae)
 Red bone marrow fills the spaces
 Inside a Bone
contd.
 Bone marrow – soft gelatin-like tissue found in central
medullary cavities of long bones & some short bones.
Contains stem cells. Produces most of new RBC in body
 2 types of bone marrow:
 Red (medulla ossium rubra) in flat & spongy bone
 Yellow (medulla ossium flava) in medullary cavity
 Red bone marrow  RBC, platelets and WBC
stored and produced
 Yellow bone marrow  fat cells
 Both highly vascular
 At birth all bone marrow is red. By
By adulthood 50:50
Bone Cells Stem cells:
unspecialized cells,
Osteoid: non-mineral, able to differentiate
organic part of bone into any cell
matrix made of
collagen & other
 Osteocytes proteins. Osteoblasts
 mature bone cells secrete these.
 lie in lacunae

 Osteoblasts
 deposition of osteoid

 Osteoprogenitor (osteogenic) cells
 mesenchymal, stem cell

 Osteoclasts
 haemopoietic, stem cells
 involved in resorption of bone
Bone Development
During bone development bone replaces cartilage and
other connective tissues = ossification Intramembranous
bones forming

TWO PROCESSES
 1. Intramembranous Ossification
 bones of the head Extracellular matrix
of embryonic
 in mesenchyme unspecialized
Endochondral
connective tissue
 no cartilage present bones forming

 from mesenchymal stem cells

 2. Endochondral Ossification
 from pre-existing cartilage model
Endochondral Ossification

 Bones start as cartilage and
change to bone - Ossification

 Mostly when we are a foetus

 Some develop as we go
through early childhood

 Mature in adolescence

 Bones grow in length at the
epiphyseal plate
Endochondral Ossification 1

1. First site of ossification occurs in the
primary ossification centre, in middle
of diaphysis
2. Formation of periosteum - contains
osteoprogenitor cells  become
osteoblasts later
3. Formation of bone collar - osteoblasts
secrete osteoid on the cartilage model
= Appositional growth - support for
new bone
4. Calcification of matrix - chondrocytes
in primary ossification centre grow -
begin to deposit minerals. Osteoclasts
break down spongy bone to form
medullary cavity. diameter growth of bones
occurs by deposition of bone
beneath periosteum
Endochondral Ossification 2

1. Around the time of birth, a secondary ossification
centre appears in each end (epiphysis) of long
bones.
2. The cartilage between the primary and
secondary ossification centres = epiphyseal plate
 continues to form new cartilage  replaced by
bone = increase in bone length.
3. Process continues until about 20 years until all
cartilage is replaced by bone.
4. Point of union between 1ry & 2ry ossification
centres = epiphyseal line
Diameter growth of bones occurs by deposition of
bone beneath periosteum (appositional growth).
Osteoclasts resorb  ultimate thickness achieved.
Growth (Epiphyseal) Plates
Bone Growth and
Remodelling
Bone Cells

Osteoblasts
deposition of
new bone

Formation and
resorption of bone
occur continuously
= remodelling

Osteoclasts
resorption of
old / damaged
bone
Bone Remodelling

 Osteoblasts
 deposition of new bone HEALTHY OSTEOPOROSIS

 Osteoclasts
 resorption of old/damaged bone

 Needs a balance

The formation and resorption of bone occur
continuously = remodelling
Bone remodelling is a lifelong process where
mature bone tissue is removed from the skeleton and
new bone tissue is formed. These processes control
the reshaping or replacement of bone following
injuries like fractures but also micro-damage, which occurs
during normal activity.
Bone resorption outpaces bone formation as the body ages.
Types of Bones
Types of Bones

 FLAT

 LONG

 SHORT

 IRREGULAR

 SESAMOID
 Lumps and Bumps

Tubercle - small
rounded point

Tuberosity / trochanter
- larger rounded bit

Linea - line

Hamulus – hook
shape

Process - projection

Ramus – curved part
of a bone (structural)

Spine - ridge
 Grooves and
Holes

Fossa – broad
shallow dip

Foramen – hole
(typically for nerves,
veins, arteries)

Sulcus – groove/dip

Notch - groove
 Articular Surfaces

Condyle – rounded
bone end -
articulates

Epicondyle – a
protuberance on the
condyle – muscle
attachments

Capitulum – can be
part of a condyle

Trochlea – groove
like a pulley

Facet – flat or
curved, synovial
gliding joint
Cartilage and Joints
Cartilage - What is it?

 Soft, slightly elastic tissue consisting of a
matrix of chondrin (a protein)

 Does not contain blood vessels

 Chondro = cartilage

THREE TYPES

Elastic Hyaline
cartilage Fibrocartilage
cartilage
Elastic Cartilage

 Consists of YELLOW elastic fibres running
through a solid matrix

 Chondrocytes large and numerous

 Has a perichondrium (thick conn tissue layer)

 Provides strength, and elasticity, and
maintains the shape of certain structure

 Example: Epiglottis, ears
Fibrocartilage

 Consists of dense mass of WHITE
collagen fibres in solid matrix
 Lacks a perichondrium
 Chondrocytes in rows
 Gives it a great tensile strength
 Tough, slightly flexible
 Example:
 intervertebral disc
 symphysis pubis
 articular discs e.g. menisci in knee
 labrum
Hyaline Articular cartilage coefficient of friction - as low as 0.002< 0.02

Cartilage
- ice on ice = 0.02

 Appears as smooth BLUISH-WHITE matrix

 Matrix is solid, smooth and firm (glassy)

 Smooth, almost frictionless

 Chondrocytes housed in lacunae

 Has a perichondrium (except articular cartilage)

 Example:
 on surfaces of bones that form synovial joints
 ribs
 nose, larynx, tracheae
Cartilage locations
Growth of
Cartilage
Appositional growth:
 Chondroblasts in perichondrium differentiate
into chondrocytes  start producing matrix,
and add to existing cartilage (widen)

Interstitial growth:
 Proliferation and hypertrophy of existing
chondrocytes (lengthen)
Joints

 Arthro = joint
 Where two or more bones come together - this
gives each joint its name
 Allow and control movement between bones -
dictated by the shape of the articulating surfaces
 Stability of a joint depends on:
 shape of articular surfaces
 ligaments
 muscles
Classification of joints

FIBROUS

CARTILAGINOUS

SYNOVIAL
Fibrous joints

 Bones are united by dense,
fibrous connective tissue
 No joint cavity
 Little or no movement
 Syndesmoses - broad fibrous
connective tissue
 Gomphoses - dento-alveolar joint
 Suture - skull…
…sutures

 Serrated (denticulated) sutures
…sutures

 Squamous sutures
…sutures

 Plane sutures
Cartilaginous joints
PRIMARY

 Articulating bones separated by
cartilage - binds the bone
 No joint cavity
 Synchondroses (primary) -
hyaline cartilage between the
bones e.g. ribs-sternum
 Symphyses (secondary) -
fibrocartilage between the
bones e.g. intervertebral discs SECONDARY
 Synovial joints
 All peripheral joints
 Surrounded by a synovial capsule
and synovial fluid
 Ends are covered in hyaline/articular
cartilage
 Ligaments connect, inside and
outside capsule
 Usually located at the ends of long
bones
 Allow for a lot of movement
 Ligaments support articulating bones
Specialised features of synovial joints
Synovial joints - 6 types

 PIVOT

 PLANE/GLIDING

 HINGE

 SADDLE

 CONYLOID

 BALL AND SOCKET
Synovial joints

 PIVOT e.g. radioulnar
 Cylindrical shape
 Mono / Uniaxial
 Ring formed by bone and ligament
 Allows rotation
Pivot joint between head of radius and radial notch
of ulna
 PLANE/GLIDING e.g. carpals
 Flat/slightly curved
 Mono / Uni / Nonaxial
 Glides and slides
Synovial joints

 HINGE e.g. tibiofemoral
 Convex and concave
 Mono/Uniaxial
 Can be ‘modified’
 Allows flexion and extension

 SADDLE e.g. trapeziometacarpal
 Convex and concave
 Biaxial (2 axes)
 Allows slight movements including
flexion, extension, abduction and
adduction
Synovial joints

 CONDYLOID e.g.
metacarpophalangeal
 Oval convex and concave
 Biaxial
 Allows flexion, extension, abduction,
adduction and circumduction
 BALL and SOCKET e.g. GHJ
 Obvious convex ball and concave
 Multiaxial
 Allows flexion, extension, abduction,
adduction, medial and lateral rotation,
circumduction
Capsular Ligaments

Thickening of the fibrous capsule that form bands/ triangles which
enhance the strength of the joint capsule

e.g. KNEE

 Intracapsular e.g:
 ACL, PCL, transverse ligament

 Extracapsular e.g:
 MCL, LCL, popliteal
Capsular Ligaments

e.g. HIP

 Intracapsular e.g:
 Head of the femur lig.
 Transverse

 Extracapsular e.g:
 Iliofemoral ligament
 Pubofemoral ligament
 Ischiofemoral ligament
Capsular Ligaments

SELF-DIRECTED LEARNING

 What are the intra/extracapsular ligaments of the shoulder?
Intra-articular discs
 Fibrocartilage, strong, thick fibres
 Attached to the joint capsule/bone
Discs located:
 Temporomandibular joint
 Sternoclavicular joint
 Ulnocarpal joint
 Incomplete discs = Menisci
 On the tibial plateau medial & lateral
 Susceptible to injury
 FUNCTIONS:
 Shock absorption
 Increase depth of joint (congruency)
 Weight bearing distribution
 Nutrition & Lubrication
Stability versus Mobility

 Joints which have a large range of movement
compromise their stability

 Stability is dependent on:
 Articular shape
 Strength of capsule
 Ligaments
 Muscle
 Tendon

 Mobility is limited by the same factors
Tendons and Ligaments
Tendons & Ligaments

 Tendons
 e.g. Achilles Tendon

 Ligaments
 e.g. Medial Collateral Ligament (MCL)
of the knee
Muscles
Muscles

Human Body
consists of
OVER
600 muscles
 Terms you need to
know!
 AGONIST (Prime Mover)
 one muscle plays major role in accomplishing
desired movement

 ANTAGONIST
 muscle working in opposite direction to
another muscle - controls/slows a movement

 SYNERGIST / STABILISER
 muscle which holds body position to enable
agonist to operate - assists agonist

 FIXATORS
 may stabilise joint(s) crossed by the agonist
(hold joint in position) - assists stabiliser
Terms you need to
know!

 BI-ARTICULAR
 produces action over TWO joints
e.g. rectus femoris

 MONO-ARTICULAR (UNI-ARTICULAR)
 produces action over ONE joint
e.g. soleus
Muscle shapes

 The shape of the muscle determines the degree a
muscle can contract and the force it can generate

 The arrangement of the individual fibres within a muscle
can be either parallel or oblique to the line of pull of the
whole muscle

 Muscles only move by shortening

 FIVE groups:

Parallel Fusiform Pennate Circular Convergent
Parallel Muscles

 The length of
the fascicles
run parallel to
the long axis
of the muscle
Fusiform Muscles

 The fibres are arranged parallel
to the line of pull

 The muscle belly is wider than
the origin and insertion
Pennate Muscles

 The fibres are oblique to the
line of pull

 Come in three forms:
 Unipennate
 Bipennate
 Multipennate
Circular Muscles

 The arrangement of the fibres are
in rings
 Surround external body openings,
which they close by contracting
 General term used is “sphincter”

e.g. mouth, gastrointestinal tract
Convergent Muscles

 Muscle fibres are spread
over a broad area, but the
fascicles all converge at one
common attachment site
 Base is wider than insertion
= fan shaped
 Allows muscle to contract
with greater force than
parallel muscle
 Relatively strong
e.g. pectoralis major
Origins and Insertions

 ORIGIN of a muscle is at the FIXED bone

 INSERTION of a muscle is at the MOVING bone

 Example: Biceps Brachii

 ORIGIN: Coracoid process / Supraglenoid

tuberosity

 INSERTION: Tuberosity of radius
Types of Muscle
contraction

 CONCENTRIC

 ECCENTRIC

 ISOMETRIC
Types of Muscle
contraction

 CONCENTRIC

Muscles develop sufficient
tension to overcome a
resistance, and shortening
takes place…

Muscle is shortening as it
contracts
Types of Muscle
contraction

 ECCENTRIC

Muscle cannot develop
sufficient tension to
overcome the force, and net
lengthening takes place…

Muscle is lengthening as it
contracts
Types of Muscle
contraction

 ISOMETRIC

Net effect is no joint angle
changes

Muscle develops force
equal to that created by
the load it is expected to
overcome

No movement
Types of
Muscle Contraction