FRACTURE CLASSIFICATION AND MANAGEMENT..
GanesanRamGanesan
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Aug 31, 2025
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About This Presentation
Fracture
Slide Content
FRACTURE
Bone
Bone is a living tissue
that supports soft tissues,
provides a frame for the
connection of ligaments
and tendons, and enables
locomotion.
Bone is a living tissue
that supports soft tissues,
provides a frame for the
connection of ligaments
and tendons, and enables
locomotion.
Definition
A fracture is disruption of the continuity
or integrity of bone
A fracture is disruption of the continuity
or integrity of bone
Although bones are strong, they are susceptible to breaks
(fractures) all throughout life.
The most common times in life for fractures to occur are
during youth (due to excessive activity, sports, and bad
judgement) and in the elderly (due to bone thinning and
weakening, often due to osteoporosis).
(fractures) all throughout life.
The most common times in life for fractures to occur are
during youth (due to excessive activity, sports, and bad
judgement) and in the elderly (due to bone thinning and
weakening, often due to osteoporosis).
Classification
On the basis of relationship with external environment
Closed :A fracture not communicating with the
external environment.
Open :A fracture with break in the overlying skin and
soft tissue, leading to the fracture communicating
with the external environment.
On the basis of relationship with external environment
Closed :A fracture not communicating with the
external environment.
Open :A fracture with break in the overlying skin and
soft tissue, leading to the fracture communicating
with the external environment.
On the basis of aetiology
Traumatic
Pathological
On the basis of displacement
Undisplaced
Displaced
Traumatic
Pathological
On the basis of displacement
Undisplaced
Displaced
On the basis of pattern;
Transverse: The fracture line is perpendicular to
the long axis of the bone. Caused by bending
force.
Oblique: The fracture line is oblique. Caused by
a bending force which in addition has a
component along long axis.
Spiral: The fracture line runs spirally in more than
one plane . Caused by primarily twisting force.
Transverse: The fracture line is perpendicular to
the long axis of the bone. Caused by bending
force.
Oblique: The fracture line is oblique. Caused by
a bending force which in addition has a
component along long axis.
Spiral: The fracture line runs spirally in more than
one plane . Caused by primarily twisting force.
Comminuted: Fracture with multiple
fragments. It is caused by a crushing or
compression force along the long axis of
the bone.
Segmental: There are two fractures in one
bone at different levels.
fragments. It is caused by a crushing or
compression force along the long axis of
the bone.
Segmental: There are two fractures in one
bone at different levels.
TYPES OF FRACTURE
Types of Bone
Lamellar Bone
Collagen fibers arranged in parallel layers
Normal adult bone
Woven Bone (non-lamellar)
Randomly oriented collagen fibers
In adults, seen at sites of fracture healing,
tendon or ligament attachment and in
pathological conditions
Lamellar Bone
Collagen fibers arranged in parallel layers
Normal adult bone
Woven Bone (non-lamellar)
Randomly oriented collagen fibers
In adults, seen at sites of fracture healing,
tendon or ligament attachment and in
pathological conditions
Six most common types of
fractures:
1)Comminuted
2)Compression
3)Depressed
4)Impacted
5)Spiral
6)Greenstick
fractures:
1)Comminuted
2)Compression
3)Depressed
4)Impacted
5)Spiral
6)Greenstick
Comminuted fractures: bone breaks in many
fragments.
fragments.
Compression fractures: bone is crushed.
Depressed fractures: bone is pressed inward.
Impacted fractures: broken bone ends are forced into each other.
Spiral fractures: ragged break occurs during twisting.
Greenstick fractures: bone breaks incompletely (like a young twig).
Stages of Fracture Healing
Stage of haematoma
Stage of granulation tissue
Stage of callus
Stage of remodelling
Stage of modelling.
Stage of haematoma
Stage of granulation tissue
Stage of callus
Stage of remodelling
Stage of modelling.
How fractures heal – in nature
1) Reactive phase
Fracture and
inflammatory phase
Granulation tissue
formation
2) Reparative phase
Callus formation
Lamellar bone
deposition
3) Remodelling phase
Remodelling to
original bone contour
1) Reactive phase
Fracture and
inflammatory phase
Granulation tissue
formation
2) Reparative phase
Callus formation
Lamellar bone
deposition
3) Remodelling phase
Remodelling to
original bone contour
1.) Inflammatory Phase
Bleeding from bone, bone periosteum, & tissues surrounding the
bone
formation of fracture hematoma & initiation of
inflammatory response
Induction (stimulus for bone regeneration) - caused
by:
decreased oxygen and bone necrosis (fractured bone
becomes hypoxic immediately)
disruption of & creation of new bioelectrical potentials
Bleeding from bone, bone periosteum, & tissues surrounding the
bone
formation of fracture hematoma & initiation of
inflammatory response
Induction (stimulus for bone regeneration) - caused
by:
decreased oxygen and bone necrosis (fractured bone
becomes hypoxic immediately)
disruption of & creation of new bioelectrical potentials
Inflammatory response - lasts between 2- 9 days
following injury:
phagocytes & lysosomes clear necrosed bone and other
debris
a fibrin mesh forms and “walls off” the fracture site
serves as “scaffold” for fibroblasts and capillary buds
capillaries grow into the hematoma
in a fracture, the new blood supply arises from
periosteum
normally 3/4 of blood flow in adult bone arises
from endosteum
in children, normal blood flow already comes
from periosteum.
following injury:
phagocytes & lysosomes clear necrosed bone and other
debris
a fibrin mesh forms and “walls off” the fracture site
serves as “scaffold” for fibroblasts and capillary buds
capillaries grow into the hematoma
in a fracture, the new blood supply arises from
periosteum
normally 3/4 of blood flow in adult bone arises
from endosteum
in children, normal blood flow already comes
from periosteum.
2.) Fibrocartilagenous callus Formation
Lasts an average of 3 weeks
Fibroblasts and osteoblasts arrive from periosteum &
endosteum
Within 2-3 days, fibroblasts produce collagen fibers that
span the break
Lasts an average of 3 weeks
Fibroblasts and osteoblasts arrive from periosteum &
endosteum
Within 2-3 days, fibroblasts produce collagen fibers that
span the break
This tissue is called Fibro - Cartilagenous Callus and
serves to “splint” the bone
FCC is formed both in and around the fracture site
Osteoblasts in outer layer of FCC begin to lay down new
hard bone
in a non-immobilized fracture, the FCC has poor
vascularization
serves to “splint” the bone
FCC is formed both in and around the fracture site
Osteoblasts in outer layer of FCC begin to lay down new
hard bone
in a non-immobilized fracture, the FCC has poor
vascularization
3.) Hard Bony Callus Formation & Ossification
Weeks to months
Fracture fragments are joined by collagen, cartilage, & then
immature bone
Osteoblasts form trabelcular bone along fracture periphery
(external callus)
Trabecular bone is then laid down in the fracture interior
(internal callus)
Weeks to months
Fracture fragments are joined by collagen, cartilage, & then
immature bone
Osteoblasts form trabelcular bone along fracture periphery
(external callus)
Trabecular bone is then laid down in the fracture interior
(internal callus)
Ossification (mineralization) starts by 2-3 weeks &
continues for 3-4 months
Alkaline phosphatase is secreted by osteoblasts
blood serum levels serve as an indicator of the rate
of bone formation
In non-Immobilized fractures, more “cartilage” than
bone is laid down
this must later be replaced by normal cancellous
bone
results in a longer healing time and fractured area
remains weak for a longer period
Fractures should be reduced (immobilized) within 3-5
days
continues for 3-4 months
Alkaline phosphatase is secreted by osteoblasts
blood serum levels serve as an indicator of the rate
of bone formation
In non-Immobilized fractures, more “cartilage” than
bone is laid down
this must later be replaced by normal cancellous
bone
results in a longer healing time and fractured area
remains weak for a longer period
Fractures should be reduced (immobilized) within 3-5
days
Callus
4.) Bone Remodeling
Months to years (mechanically stable at 40 days)
Excess material inside bone shaft is replaced by
more compact bone
Final remodeled structure is influenced by optimal
bone stress
Months to years (mechanically stable at 40 days)
Excess material inside bone shaft is replaced by
more compact bone
Final remodeled structure is influenced by optimal
bone stress
Woven bone is gradually converted to lamellar bone
Medullary cavity is reconstituted
Bone is restructured in response to stress and strain
(Wolff’s Law)
Medullary cavity is reconstituted
Bone is restructured in response to stress and strain
(Wolff’s Law)
Healing in Bone:
1D - Hematoma
3D - Inflammation
1W - Soft callus
3-6W - Callus
8+W - Re-modeling
1D - Hematoma
3D - Inflammation
1W - Soft callus
3-6W - Callus
8+W - Re-modeling
Stages of wound healing
Time after injury
Hemostasis
Inflammation
Proliferation
Resolution/ Remodeling
PMNs, Macrophages, Lymphocytes
Reepithelialization, Angiogenesis, Fibrogenesis,
Vessel regression, Collagen remodeling
Fibrin clot, platelet
deposition
1D 3D 1wk 6wk 8wk
Time after injury
Hemostasis
Inflammation
Proliferation
Resolution/ Remodeling
PMNs, Macrophages, Lymphocytes
Reepithelialization, Angiogenesis, Fibrogenesis,
Vessel regression, Collagen remodeling
Fibrin clot, platelet
deposition
1D 3D 1wk 6wk 8wk
FACTORS INFLUENCING # HEALING
AGE
TYPE OF BONE
TYPE OF FRACTURE
GENERAL STATUS OF THE PATIENT-VITAMIN
DEF,DM,SYPHILIS,IMMUNOCOMPRAMISED.
IMPROPER REDUCTION
INADEQUATE BLOOD SUPPLY
INADEQUATE IMMOLISATION
INFECTION
SOFT TISSUE INTERPOSITION
AGE
TYPE OF BONE
TYPE OF FRACTURE
GENERAL STATUS OF THE PATIENT-VITAMIN
DEF,DM,SYPHILIS,IMMUNOCOMPRAMISED.
IMPROPER REDUCTION
INADEQUATE BLOOD SUPPLY
INADEQUATE IMMOLISATION
INFECTION
SOFT TISSUE INTERPOSITION
Factors Enhancing Bone Healing
Youth
Early Immobilization of fracture fragments
Maximum bone fragment contact
Adequate blood supply
Proper Nutrition
Vitamines A&D
Youth
Early Immobilization of fracture fragments
Maximum bone fragment contact
Adequate blood supply
Proper Nutrition
Vitamines A&D
Weight bearing exercise for long bones in the
late stages of healing
Adequate hormones:
growth hormone
thyroxine
calcitonin
late stages of healing
Adequate hormones:
growth hormone
thyroxine
calcitonin
Age
Fractured Femur Healing Time
infant: 4 weeks
teenager: 12 to 16 weeks
60 year old adult: 18 to 20 weeks
Extensive local soft tissue trauma
Factors Inhibiting Bone Healing
Fractured Femur Healing Time
infant: 4 weeks
teenager: 12 to 16 weeks
60 year old adult: 18 to 20 weeks
Extensive local soft tissue trauma
Factors Inhibiting Bone Healing
Bone loss due to the severity of the
fracture
Infection
Inadequate immobilization (motion at the
fracture site)
Avascular Necrosis
fracture
Infection
Inadequate immobilization (motion at the
fracture site)
Avascular Necrosis
Complication
Acute Compartment Syndrome
Serious condition in which increased
pressure within one or more compartments
causes massive compromise of circulation to
the area
Prevention of pressure buildup of blood or
fluid accumulation
Pathophysiologic changes sometimes
referred to as ischemia-edema cycle
Serious condition in which increased
pressure within one or more compartments
causes massive compromise of circulation to
the area
Prevention of pressure buildup of blood or
fluid accumulation
Pathophysiologic changes sometimes
referred to as ischemia-edema cycle
Emergency Care - Acute
Compartment Syndrome
Within 4 to 6 hr after the onset of acute compartment
syndrome, neuromuscular damage is irreversible; the
limb can become useless within 24 to 48 hr.
Monitor compartment pressures.
Fasciotomy may be performed to relieve pressure.
Pack and dress the wound after fasciotomy.
Compartment Syndrome
Within 4 to 6 hr after the onset of acute compartment
syndrome, neuromuscular damage is irreversible; the
limb can become useless within 24 to 48 hr.
Monitor compartment pressures.
Fasciotomy may be performed to relieve pressure.
Pack and dress the wound after fasciotomy.
Possible Results of Acute
Compartment Syndrome
Infection
Motor weakness
Volkmann’s contractures
Myoglobinuric renal failure, known as
rhabdomyolysis
Compartment Syndrome
Infection
Motor weakness
Volkmann’s contractures
Myoglobinuric renal failure, known as
rhabdomyolysis
Other Complications of Fractures
Shock
Fat embolism syndrome: serious complication resulting
from a fracture; fat globules are released from yellow
bone marrow into bloodstream
Venous thromboembolism
Infection
Ischemic necrosis
Fracture blisters, delayed union, nonunion, and
malunion
Shock
Fat embolism syndrome: serious complication resulting
from a fracture; fat globules are released from yellow
bone marrow into bloodstream
Venous thromboembolism
Infection
Ischemic necrosis
Fracture blisters, delayed union, nonunion, and
malunion
Muscle Atrophy, loss of muscle strength range of
motion, pressure ulcers, and other problems
associated with immobility
Embolism/Pneumonia/ARDS
TREATMENT – hydration, albumin, corticosteroids
Constipation/Anorexia
UTI
DVT
motion, pressure ulcers, and other problems
associated with immobility
Embolism/Pneumonia/ARDS
TREATMENT – hydration, albumin, corticosteroids
Constipation/Anorexia
UTI
DVT
Musculoskeletal Assessment -
Fracture
Change in bone alignment
Alteration in length of extremity
Change in shape of bone
Pain upon movement
Decreased ROM
Crepitation
Ecchymotic skin
Fracture
Change in bone alignment
Alteration in length of extremity
Change in shape of bone
Pain upon movement
Decreased ROM
Crepitation
Ecchymotic skin
Musculoskeletal Assessment –
Fracture (Continued)
Subcutaneous emphysema with bubbles
under the skin
Swelling at the fracture site
Fracture (Continued)
Subcutaneous emphysema with bubbles
under the skin
Swelling at the fracture site
Special Assessment
Considerations
For fractures of the shoulder and upper arm,
assess client in sitting or standing position.
Support the affected arm to promote comfort.
For distal areas of the arm, assess client in a
supine position.
For fracture of lower extremities and pelvis,
client is in supine position.
Considerations
For fractures of the shoulder and upper arm,
assess client in sitting or standing position.
Support the affected arm to promote comfort.
For distal areas of the arm, assess client in a
supine position.
For fracture of lower extremities and pelvis,
client is in supine position.
Risk for Peripheral
Neurovascular Dysfunction
Interventions include:
Emergency care: assess for respiratory
distress, bleeding and head injury
Nonsurgical management: closed reduction
and immobilization with a bandage, splint,
cast, or traction
Neurovascular Dysfunction
Interventions include:
Emergency care: assess for respiratory
distress, bleeding and head injury
Nonsurgical management: closed reduction
and immobilization with a bandage, splint,
cast, or traction
Casts
Rigid device that immobilizes the affected
body part while allowing other body parts
to move
Cast materials: plaster, fiberglass,
polyester-cotton
Types of casts for various parts of the
body: arm, leg, brace, body
(Continued)
Rigid device that immobilizes the affected
body part while allowing other body parts
to move
Cast materials: plaster, fiberglass,
polyester-cotton
Types of casts for various parts of the
body: arm, leg, brace, body
(Continued)
Casts (Continued)
Cast care and client education
Cast complications: infection, circulation
impairment, peripheral nerve damage,
complications of immobility
Cast care and client education
Cast complications: infection, circulation
impairment, peripheral nerve damage,
complications of immobility
Managing Care of the Patient in a Cast
Casting Materials
Relieving Pain
Improving Mobility
Promoting Healing
Neurovascular Function
Potential Complications
Casting Materials
Relieving Pain
Improving Mobility
Promoting Healing
Neurovascular Function
Potential Complications
Cast, Splint, Braces, and Traction
Management Considerations
Arm Casts
Leg Casts
Body or Spica Casts
Splints and Braces
External Fixator
Traction
Management Considerations
Arm Casts
Leg Casts
Body or Spica Casts
Splints and Braces
External Fixator
Traction
Musculoskeletal
Nursing Care - Casts
Cast (Leg, arm, body)
Different materials-
fiberglass, plastic,
plaster, stockinette
Neurovascular
Check color/capillary
refill
Temperature
Pulse
Movement
Sensation
Traction
Buck’s
Russell’s
Skeletal
Traction Nursing Care
Weighs hang free
Pin Site care
Skin and neurovascular
check
Nursing Care - Casts
Cast (Leg, arm, body)
Different materials-
fiberglass, plastic,
plaster, stockinette
Neurovascular
Check color/capillary
refill
Temperature
Pulse
Movement
Sensation
Traction
Buck’s
Russell’s
Skeletal
Traction Nursing Care
Weighs hang free
Pin Site care
Skin and neurovascular
check
Cast Care (continued)
Elevate Extremity
Exercises – to unaffected side; isometric exercises to affected
extremity
Keep heel off mattress
Handle with palms of hands if cast wet
Turn every two hours till dry
Notify MD at once of wound drainage
Do not place items under cast.
Elevate Extremity
Exercises – to unaffected side; isometric exercises to affected
extremity
Keep heel off mattress
Handle with palms of hands if cast wet
Turn every two hours till dry
Notify MD at once of wound drainage
Do not place items under cast.
Traction
Application of a pulling force to the body
to provide reduction, alignment, and rest
at that site
Types of traction: skin, skeletal, plaster,
brace, circumferential
(Continued)
Application of a pulling force to the body
to provide reduction, alignment, and rest
at that site
Types of traction: skin, skeletal, plaster,
brace, circumferential
(Continued)
Traction (Continued)
Traction care:
Maintain correct balance between traction pull
and countertraction force
Care of weights
Skin inspection
Pin care
Assessment of neurovascular status
Traction care:
Maintain correct balance between traction pull
and countertraction force
Care of weights
Skin inspection
Pin care
Assessment of neurovascular status
Musculoskeletal – Fractures
Treatment
Primary Goal – reduce fracture-
Realign and immobilize
Medications
Analgesics, antibiotics, tetanus toxoid
Closed Reduction – Manual and Cast; External
Fixation Device
Traction; Splints; Braces
Surgery
Open reduction with internal fixation
Reconstructive surgery
Endoprosthetic replacement
Treatment
Primary Goal – reduce fracture-
Realign and immobilize
Medications
Analgesics, antibiotics, tetanus toxoid
Closed Reduction – Manual and Cast; External
Fixation Device
Traction; Splints; Braces
Surgery
Open reduction with internal fixation
Reconstructive surgery
Endoprosthetic replacement
Nursing Management
Positioning
Strengthening Exercises
Potential Complications
Positioning
Strengthening Exercises
Potential Complications
Musculoskeletal
Nursing Care
Other External Immobilizations
Halo Vest
External Fixation with lag screws at tibia, pelvic,
ankle/foot
Nursing Care
Other External Immobilizations
Halo Vest
External Fixation with lag screws at tibia, pelvic,
ankle/foot
Musculoskeletal
Nursing Care -2
Promote comfort
Assess infection
Promote mobility
Teach safety
Vital Signs
Flotation, sheep skin
Nutrition
Vital Signs
Monitor elimination
Elevate extremity to
decrease swelling/ ice
pack
Teach skin care, cast
care, diet,
complications
Nursing Care -2
Promote comfort
Assess infection
Promote mobility
Teach safety
Vital Signs
Flotation, sheep skin
Nutrition
Vital Signs
Monitor elimination
Elevate extremity to
decrease swelling/ ice
pack
Teach skin care, cast
care, diet,
complications
Operative Procedures
Open reduction with internal fixation
External fixation
Postoperative care: similar to that for any
surgery; certain complications specific to
fractures and musculoskeletal surgery
include fat embolism and venous
thromboembolism
Open reduction with internal fixation
External fixation
Postoperative care: similar to that for any
surgery; certain complications specific to
fractures and musculoskeletal surgery
include fat embolism and venous
thromboembolism
Acute Pain - Orthopedic Surgery
Interventions include:
Reduction and immobilization of fracture
Assessment of pain
Drug therapy: opioid and nonopioid drugs
(Continued)
Interventions include:
Reduction and immobilization of fracture
Assessment of pain
Drug therapy: opioid and nonopioid drugs
(Continued)
Acute Pain (Continued)
Orthopedic Surgery
Complementary and alternative therapies: ice,
heat, elevation of body part, massage, baths,
back rub, therapeutic touch, distraction,
imagery, music therapy, relaxation techniques
Orthopedic Surgery
Complementary and alternative therapies: ice,
heat, elevation of body part, massage, baths,
back rub, therapeutic touch, distraction,
imagery, music therapy, relaxation techniques
Risk for Infection
Interventions include:
Apply strict aseptic technique for dressing
changes and wound irrigations.
Assess for local inflammation
Report purulent drainage immediately to
health care provider.
(Continued)
Interventions include:
Apply strict aseptic technique for dressing
changes and wound irrigations.
Assess for local inflammation
Report purulent drainage immediately to
health care provider.
(Continued)
Risk for Infection (Continued)
Assess for pneumonia and urinary tract
infection.
Administer broad-spectrum antibiotics
prophylactically.
Assess for pneumonia and urinary tract
infection.
Administer broad-spectrum antibiotics
prophylactically.
Impaired Physical Mobility
Interventions include:
Use of crutches to promote mobility
Use of walkers and canes to promote mobility
Interventions include:
Use of crutches to promote mobility
Use of walkers and canes to promote mobility
Imbalanced Nutrition: Less Than
Body Requirements
Interventions include:
Diet high in protein, calories, and calcium,
supplemental vitamins B and C
Frequent small feedings and supplements of
high-protein liquids
Intake of foods high in iron
Body Requirements
Interventions include:
Diet high in protein, calories, and calcium,
supplemental vitamins B and C
Frequent small feedings and supplements of
high-protein liquids
Intake of foods high in iron
Upper Extremity Fractures
Fractures include those of the:
Clavicle
Scapula
Humerus
Olecranon
Radius and ulna
Wrist and hand
Fractures include those of the:
Clavicle
Scapula
Humerus
Olecranon
Radius and ulna
Wrist and hand
Lower Extremity Fractures
Fractures include those of the:
Femur
Patella
Tibia and fibula
Ankle and foot
Fractures include those of the:
Femur
Patella
Tibia and fibula
Ankle and foot
Fractures of the Hip
Intracapsular or extracapsular
Treatment of choice: surgical repair, when
possible, to allow the older client to get
out of bed
Open reduction with internal fixation
Intramedullary rod, pins, a prosthesis, or a
fixed sliding plate
Prosthetic device
Intracapsular or extracapsular
Treatment of choice: surgical repair, when
possible, to allow the older client to get
out of bed
Open reduction with internal fixation
Intramedullary rod, pins, a prosthesis, or a
fixed sliding plate
Prosthetic device
Fractures of the Pelvis
Associated internal damage the chief
concern in fracture management of pelvic
fractures
Non–weight-bearing fracture of the pelvis
Weight-bearing fracture of the pelvis
Associated internal damage the chief
concern in fracture management of pelvic
fractures
Non–weight-bearing fracture of the pelvis
Weight-bearing fracture of the pelvis
Compression Fractures of the
Spine
Most are associated with osteoporosis
rather than acute spinal injury.
Multiple hairline fractures result when
bone mass diminishes.
(Continued)
Spine
Most are associated with osteoporosis
rather than acute spinal injury.
Multiple hairline fractures result when
bone mass diminishes.
(Continued)
Compression Fractures of the
Spine (Continued)
Nonsurgical management includes
bedrest, analgesics, and physical therapy.
Minimally invasive surgeries are
vertebroplasty and kyphoplasty, in which
bone cement is injected.
(Continued)
Spine (Continued)
Nonsurgical management includes
bedrest, analgesics, and physical therapy.
Minimally invasive surgeries are
vertebroplasty and kyphoplasty, in which
bone cement is injected.
(Continued)
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