Traumatology introduction.ppt
ankitkumarsharma32
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Mar 30, 2023
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About This Presentation
eu
Slide Content
PROFESSOR
Fishchenko Vladimir
Alexandrovich
Fishchenko Vladimir
Alexandrovich
BASHINSKIY GENNADIY
PETROVICH
PETROVICH
Traumatology:
•acute injuries,
•polytrauma.
Orthopedics :
•post-traumatic conditions,
•axial deformities,
•congenital and inherited systemic
bone diseases,
•limb developmental defciencies,
•infammatory diseases of bones and
joints,
•musculoskeletal tumors.
•acute injuries,
•polytrauma.
Orthopedics :
•post-traumatic conditions,
•axial deformities,
•congenital and inherited systemic
bone diseases,
•limb developmental defciencies,
•infammatory diseases of bones and
joints,
•musculoskeletal tumors.
QUESTIONING
GENERAL APPEARANCE
LOCAL EXAMINATION
OF THE AFFECTED
AREA
GENERAL APPEARANCE
LOCAL EXAMINATION
OF THE AFFECTED
AREA
Patient’s complaints (pain,
limitation of function, deformity)
History (type of injury, cause,
time, first aid)
Life history (occupation, habits,
family history, social history,
genetic history, previous injury
or orthopedic disease)
limitation of function, deformity)
History (type of injury, cause,
time, first aid)
Life history (occupation, habits,
family history, social history,
genetic history, previous injury
or orthopedic disease)
Weight
Constitution
Position
Body build
Posture (attitude)
Gait
Constitution
Position
Body build
Posture (attitude)
Gait
For the degree of
abnormality aсessment,
simultaneous examination
of the opposite limb
required
abnormality aсessment,
simultaneous examination
of the opposite limb
required
Skin state (ecchymosis, inflamation signs,
tumors bruising, swelling, hematoma,
lacerations, or puncture wounds. Note scars
that indicate previous trauma or surgeries to
the limb)
Deformities (valgus, varus, antecurvation,
recurvation)
Extremity length
Limb circumference measurement
Muscle strength measurement
The motion range measurement
tumors bruising, swelling, hematoma,
lacerations, or puncture wounds. Note scars
that indicate previous trauma or surgeries to
the limb)
Deformities (valgus, varus, antecurvation,
recurvation)
Extremity length
Limb circumference measurement
Muscle strength measurement
The motion range measurement
Axis of extremity
Axis of upper extremity –
conditionally passes through
the middle of shoulder, radial
and ulnar heads.
Axis of upper extremity –
conditionally passes through
the middle of shoulder, radial
and ulnar heads.
Axis of lower
extremity
Axis of lower extremity–
from the front upper iliac
horn through the middle of
patella to the gap between
1st and 2nd fingers on feet.
extremity
Axis of lower extremity–
from the front upper iliac
horn through the middle of
patella to the gap between
1st and 2nd fingers on feet.
DEFORMATION OF
EXTREMITY
–Impairments of the axis are:
outside –valgus
EXTREMITY
–Impairments of the axis are:
outside –valgus
–Impairments of the
axis are:inside –varus
axis are:inside –varus
Impairments of the axis are:
when the angle is open
forward –recurvatum
when the angle is open
forward –recurvatum
Impairments of the axis
are: when the angle is
open backwards –
antecurvatum.
are: when the angle is
open backwards –
antecurvatum.
Measuring of length of
limbs
Common lent of upper extremity
measure from akromial process
of scapula to styloid process of
ulna
limbs
Common lent of upper extremity
measure from akromial process
of scapula to styloid process of
ulna
Thecommon length of lower
extremity is measured from
the front upper iliac horn to
the top of the inner ankle
extremity is measured from
the front upper iliac horn to
the top of the inner ankle
The shoulder length is
measured from the
akromion to olecranon;
measured from the
akromion to olecranon;
The length of forearm is
measured from olecranon to
styloid process of ulna
measured from olecranon to
styloid process of ulna
The length of the hip is
measured from greater
trohanter to the head of
fibula
measured from greater
trohanter to the head of
fibula
the length of the crus is
measured from the head of
fibula to the top of the lateral
ankle
measured from the head of
fibula to the top of the lateral
ankle
There are following types of
shortening
1) Anatomic shortening.
2) Relative shortening
3)projecting shortening
4) Functional shortening
shortening
1) Anatomic shortening.
2) Relative shortening
3)projecting shortening
4) Functional shortening
The patient or limb position (attitude)–
active, passive, involuntary (forced).
-Active position indicates on absence of
severe functional disorders in case of
trauma, compensatory adjustments
(adaptation) in orthopedic patients.
-Passive position indicates on the severity
of trauma, shock. It may be caused by
fractured bones or paralysis.
-Forced extremity or trunk attitude may be
result of dislocation, inflammation, etc. After
reposition of dislocation, reduction of the
inflammatory process the forced position
active, passive, involuntary (forced).
-Active position indicates on absence of
severe functional disorders in case of
trauma, compensatory adjustments
(adaptation) in orthopedic patients.
-Passive position indicates on the severity
of trauma, shock. It may be caused by
fractured bones or paralysis.
-Forced extremity or trunk attitude may be
result of dislocation, inflammation, etc. After
reposition of dislocation, reduction of the
inflammatory process the forced position
Contractureis a restriction of passive
movements in the joint.
1. Antalgic (фprotective, analgetic)
2. Miogenic (due to one or group of muscles
shortening)
3. Arthrogenic (due to posttraumatic,
inflammatory or degenerative-dystrophic
changes in the joints).
4. Desmogenic (scarring of fasciae, ligaments
after trauma and operations)
5. Dermatogenic (after extensive burns)
6. Neurogenic (in cases of flaccid, spastic
paralyses)
7. Tenogenic (reducing of a tendon or its
fusion with its vagina)
movements in the joint.
1. Antalgic (фprotective, analgetic)
2. Miogenic (due to one or group of muscles
shortening)
3. Arthrogenic (due to posttraumatic,
inflammatory or degenerative-dystrophic
changes in the joints).
4. Desmogenic (scarring of fasciae, ligaments
after trauma and operations)
5. Dermatogenic (after extensive burns)
6. Neurogenic (in cases of flaccid, spastic
paralyses)
7. Tenogenic (reducing of a tendon or its
fusion with its vagina)
Joint stiffnessis a state insignificant
(that does not exceed 3-5°) oscillatory
motions are saved in a joint.
Ankylosisis a complete absence of
movements. Ankyloses may be fibrous
and bony (true), intra-articular and
extra-articular, concordant (in
functionally advantageous position) and
and discordant (in functionally
disadvantageous position).
(that does not exceed 3-5°) oscillatory
motions are saved in a joint.
Ankylosisis a complete absence of
movements. Ankyloses may be fibrous
and bony (true), intra-articular and
extra-articular, concordant (in
functionally advantageous position) and
and discordant (in functionally
disadvantageous position).
Absolute signs of fracture:
-Visible deformation (axis
violation)
-Crepitation
-Pathological mobility
-True shortening
-Pain during axis loading
-Visible deformation (axis
violation)
-Crepitation
-Pathological mobility
-True shortening
-Pain during axis loading
Absolute signs of dislocation (luxatio):
-Forced limb position
-Violation of the joint lines
-Palpation of the head outside the joint
cavity
-Relative (dislocational) shortening or
lengthening
-Active movement is impossible, but
passive -elastic
-Forced limb position
-Violation of the joint lines
-Palpation of the head outside the joint
cavity
-Relative (dislocational) shortening or
lengthening
-Active movement is impossible, but
passive -elastic
Rozer-Nelaton’s
Rozer-Nelaton’sline
connects tuber of iscium and
the front upper iliac horn. It is
used to determine
pathological states in the hip
joint. Normally, hip is bent at
an angle of 130°, the greater
trochanter is palpated on this
line.
Rozer-Nelaton’sline
connects tuber of iscium and
the front upper iliac horn. It is
used to determine
pathological states in the hip
joint. Normally, hip is bent at
an angle of 130°, the greater
trochanter is palpated on this
line.
Shemaker’s line
Shemaker’s lineconnects
the tip of the greater
trochanter and the front
upper iliac horn. Conditional
continue of the line usually
passes above the navel.
Shemaker’s lineconnects
the tip of the greater
trochanter and the front
upper iliac horn. Conditional
continue of the line usually
passes above the navel.
Brian’s triangle
Brian’s triangleis formed by
a line drawn along the axis of
the aligned hip up to the
crossing with the
perpendicular, which starts
from the front upper iliac
horn. It connects it with a
greater trochanter.
Brian’s triangleis formed by
a line drawn along the axis of
the aligned hip up to the
crossing with the
perpendicular, which starts
from the front upper iliac
horn. It connects it with a
greater trochanter.
Marx’s line
Marx’s lineconnects both
epicondyles of the shoulder
bone and normally is
perpendicular to the
longitudinal axis of the bone.
Marx’s lineconnects both
epicondyles of the shoulder
bone and normally is
perpendicular to the
longitudinal axis of the bone.
Huter’s triangle
Huter’s triangleis formed
during forearm flexion at 90°
by three bone shelves: both
of epicondyles and the tip of
olecranon.
Huter’s triangleis formed
during forearm flexion at 90°
by three bone shelves: both
of epicondyles and the tip of
olecranon.
Huter’s line
Huter’s linein the unbent
position connects two
epicondyles and the tip of
olecranon.
Huter’s linein the unbent
position connects two
epicondyles and the tip of
olecranon.
Look
Swelling
Bruising
Deformity
Overlying skin
Adjacent joint
Limb shortening
Local examination
Swelling
Bruising
Deformity
Overlying skin
Adjacent joint
Limb shortening
Local examination
Feel
Temperature
Tenderness
Swelling
Peripheral sensation
Peripheral pulses
Local examination
Temperature
Tenderness
Swelling
Peripheral sensation
Peripheral pulses
Local examination
Move
No attempt should be made
to elicit abnormal mobility or
crepitus in a fractured bone.
Joint movements should only
be tested if patients can
perform them actively without
much discomfort.
Local examination
No attempt should be made
to elicit abnormal mobility or
crepitus in a fractured bone.
Joint movements should only
be tested if patients can
perform them actively without
much discomfort.
Local examination
POSTURE
Pt’s neck appears short and broad. Pt’s hairline is low and an associated
Sprengel deformity is present, the left scapula being hypoplastic and high
riding. As a result, the patient is unable to fully raise his left arm.
Sprengel deformity is present, the left scapula being hypoplastic and high
riding. As a result, the patient is unable to fully raise his left arm.
CT
Stages of fracture healing
(Frost 1989)
1. Stage of haematoma
Approximate time: Less than 7 days
Essential features: Fracture-end necrosis
occurs. Sensitisation of precursor cells.
2. Stage of granulation tissue
Approximate time: Up to 2 –3 weeks;
Essential features: Prolifiration and
differentiation of daughter cells into
vessels, fibroblasts, osteoblasts etc.
(Frost 1989)
1. Stage of haematoma
Approximate time: Less than 7 days
Essential features: Fracture-end necrosis
occurs. Sensitisation of precursor cells.
2. Stage of granulation tissue
Approximate time: Up to 2 –3 weeks;
Essential features: Prolifiration and
differentiation of daughter cells into
vessels, fibroblasts, osteoblasts etc.
3.Stage of callus
Approximate time: 4 –12 weeks;
Essential festures: Mineralisation of
granulation tissue. Callus radiologically
visible. Fracture clinically united, no
more mobile.
4. Stage of remodelling
Approximate time: 1 –2 years;
Essential features: Lamellar
boneformation by multicellular unit
based remodelling of callus. Outline of
callus becomes dense and sharply
Approximate time: 4 –12 weeks;
Essential festures: Mineralisation of
granulation tissue. Callus radiologically
visible. Fracture clinically united, no
more mobile.
4. Stage of remodelling
Approximate time: 1 –2 years;
Essential features: Lamellar
boneformation by multicellular unit
based remodelling of callus. Outline of
callus becomes dense and sharply
5. Stage of modelling
Approximate time: Many years;
Essential features: Modelling of endosteal
and periosteal surface so that the
fracture-site becomes indistinguishable
from the parent bone.
Approximate time: Many years;
Essential features: Modelling of endosteal
and periosteal surface so that the
fracture-site becomes indistinguishable
from the parent bone.
Consilidation of bone tissue may
be due to next bone callus:
Endosteal
Periosteal
Paraosseous
Intermediary
be due to next bone callus:
Endosteal
Periosteal
Paraosseous
Intermediary
Consolidation of bone tissue devides to
primary consolidation and secondary
consolidation
Primary consolidation as rool due to
intermedial callus. It’s much more
complete;
And secondary as rool due to periostal
callus.
primary consolidation and secondary
consolidation
Primary consolidation as rool due to
intermedial callus. It’s much more
complete;
And secondary as rool due to periostal
callus.
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