Posterolateral corner injuries of knee joint Samir Dwidmuthe
Missed posterolateral corner injuries of knee joint is a common cause for failure of ACL and PCL reconstruction only next to malpositioned tunnels.
Isolated PLC injuries are uncommon, making up <2% of all acute knee ligamentous injuries. Covey JBJS 2001
Incidence of PLC injuries associated with concomitant ACL and PCL disruptions are much more common (43% to 80%). Ranawat JAAOS 2008
A recent (MRI) analysis of surgical tibialplateau fractures demonstrated an incidence of PLC injuries in 68% of cases. Gardner JOT 2005
Take home message
PLC injuries to be ruled out in every case of ACL& PCL rupture.
Neurovascular integrity to be checked in every case.
Grade I & II can be managed conservatively.
Grade III Acute- Repair.
Grade III Chronic- Anatomic PLC recon.
Beware of varus knee alignment.
Posterolateral corner injuries of knee joint Samir Dwidmuthe
Missed posterolateral corner injuries of knee joint is a common cause for failure of ACL and PCL reconstruction only next to malpositioned tunnels.
Isolated PLC injuries are uncommon, making up <2% of all acute knee ligamentous injuries. Covey JBJS 2001
Incidence of PLC injuries associated with concomitant ACL and PCL disruptions are much more common (43% to 80%). Ranawat JAAOS 2008
A recent (MRI) analysis of surgical tibialplateau fractures demonstrated an incidence of PLC injuries in 68% of cases. Gardner JOT 2005
Take home message
PLC injuries to be ruled out in every case of ACL& PCL rupture.
Neurovascular integrity to be checked in every case.
Grade I & II can be managed conservatively.
Grade III Acute- Repair.
Grade III Chronic- Anatomic PLC recon.
Beware of varus knee alignment.
Can read freely here
https://sethiortho.blogspot.com/
Challenges and Solutions in
Management of Distal Humerus Fractures
Epidemiology
Anatomy
Classification
Controversies and Recent studies
Approach
Implants selection
Plate configuration
Ulnar nerve transposition
Role of total elbow arthroplasty in DHF
Role of hemiarthroplasty in DHF
Metaphyseal comminution –
Anatomic complexity of the distal humerus
Positioning of the plates
TBW –
Skin closure
Osteoporotic nature of the bone –
Less BMD/Thin metaphysis
Screw Pullout strength is low
DHF account for 2% of all adult fractures
The common pattern of fracture
Intraarticular and involves both columns
Bimodal distribution
Peak incidence in young male and in older female patients
Young male – High-velocity injury
Older female - Osteoporosis
The distal humerus is flattened and expanded bony structure
It is composed of lateral and medial columns with the trochlea situated between these columns.
The location of the trochlea is central rather than medial
Formed by Medial SCR + M/Epicondyle
The distal end has 450 angulation with humeral shaft
M/ Epicondyle gives attachment for MCL & Common Flexor Origin
The MCL originates from the undersurface of the medial epicondyle where it is vulnerable to excessive dissection
Ulnar nerve
Formed by Lateral SCR and L/Epicondyle and Capitulum
Distal end has 200 with humeral shaft
L/ epicondyle gives attachment for LCL & common extensor origin
Its posterior surface is non articular and can be used as a site for a plate fixation
The lateral column curves anteriorly
Placement of a straight plate on the posterolateral surface of the humerus risks straightening of distal humerus.
The medial column including the medial epicondyle is in line with the humeral shaft.
It forms the center of the triangle
It has 30 - 80 – external rotation & 250 anterior divergent with the shaft
It forms a 40 - 80 degree valgus direction
X-ray -
Anterior-posterior view
lateral View
Traction View – This can help to define articular fragments and aid in pre-operative classification of the fracture.
NCCT – Elbow
Articular surfaces
Position of the fracture fragments
useful for identifying impacted fracture fragments that make reduction challenging
Olecranon Osteotomy Approach – 52-57%
Triceps sparing VS Olecranon osteotomy approach
The lateral column was often the first to fail as a result of excessive varus forces acting on the elbow during normal activities of daily living. Small anterior-posterior diameter
Smaller diameter of the humerus, permitting only one or two short screws for fixation.
Interruption of blood supply to the lateral column
blood supply to the lateral column is also derived from posterior segmental vessels. Sagittal plane plating has less risk of injuring these structures, which may improve the chances of union
Can read freely here
https://sethiortho.blogspot.com/
Challenges and Solutions in
Management of Distal Humerus Fractures
Epidemiology
Anatomy
Classification
Controversies and Recent studies
Approach
Implants selection
Plate configuration
Ulnar nerve transposition
Role of total elbow arthroplasty in DHF
Role of hemiarthroplasty in DHF
Metaphyseal comminution –
Anatomic complexity of the distal humerus
Positioning of the plates
TBW –
Skin closure
Osteoporotic nature of the bone –
Less BMD/Thin metaphysis
Screw Pullout strength is low
DHF account for 2% of all adult fractures
The common pattern of fracture
Intraarticular and involves both columns
Bimodal distribution
Peak incidence in young male and in older female patients
Young male – High-velocity injury
Older female - Osteoporosis
The distal humerus is flattened and expanded bony structure
It is composed of lateral and medial columns with the trochlea situated between these columns.
The location of the trochlea is central rather than medial
Formed by Medial SCR + M/Epicondyle
The distal end has 450 angulation with humeral shaft
M/ Epicondyle gives attachment for MCL & Common Flexor Origin
The MCL originates from the undersurface of the medial epicondyle where it is vulnerable to excessive dissection
Ulnar nerve
Formed by Lateral SCR and L/Epicondyle and Capitulum
Distal end has 200 with humeral shaft
L/ epicondyle gives attachment for LCL & common extensor origin
Its posterior surface is non articular and can be used as a site for a plate fixation
The lateral column curves anteriorly
Placement of a straight plate on the posterolateral surface of the humerus risks straightening of distal humerus.
The medial column including the medial epicondyle is in line with the humeral shaft.
It forms the center of the triangle
It has 30 - 80 – external rotation & 250 anterior divergent with the shaft
It forms a 40 - 80 degree valgus direction
X-ray -
Anterior-posterior view
lateral View
Traction View – This can help to define articular fragments and aid in pre-operative classification of the fracture.
NCCT – Elbow
Articular surfaces
Position of the fracture fragments
useful for identifying impacted fracture fragments that make reduction challenging
Olecranon Osteotomy Approach – 52-57%
Triceps sparing VS Olecranon osteotomy approach
The lateral column was often the first to fail as a result of excessive varus forces acting on the elbow during normal activities of daily living. Small anterior-posterior diameter
Smaller diameter of the humerus, permitting only one or two short screws for fixation.
Interruption of blood supply to the lateral column
blood supply to the lateral column is also derived from posterior segmental vessels. Sagittal plane plating has less risk of injuring these structures, which may improve the chances of union
an easy introduction of nervous system. Detail theoretical information purposefully avoided. At the beginning of medical course, also biology student need to know about nervous system. Within short time this presentation give a simple overview of NS.
We all have good and bad thoughts from time to time and situation to situation. We are bombarded daily with spiraling thoughts(both negative and positive) creating all-consuming feel , making us difficult to manage with associated suffering. Good thoughts are like our Mob Signal (Positive thought) amidst noise(negative thought) in the atmosphere. Negative thoughts like noise outweigh positive thoughts. These thoughts often create unwanted confusion, trouble, stress and frustration in our mind as well as chaos in our physical world. Negative thoughts are also known as “distorted thinking”.
Students, digital devices and success - Andreas Schleicher - 27 May 2024..pptxEduSkills OECD
Andreas Schleicher presents at the OECD webinar ‘Digital devices in schools: detrimental distraction or secret to success?’ on 27 May 2024. The presentation was based on findings from PISA 2022 results and the webinar helped launch the PISA in Focus ‘Managing screen time: How to protect and equip students against distraction’ https://www.oecd-ilibrary.org/education/managing-screen-time_7c225af4-en and the OECD Education Policy Perspective ‘Students, digital devices and success’ can be found here - https://oe.cd/il/5yV
Model Attribute Check Company Auto PropertyCeline George
In Odoo, the multi-company feature allows you to manage multiple companies within a single Odoo database instance. Each company can have its own configurations while still sharing common resources such as products, customers, and suppliers.
Synthetic Fiber Construction in lab .pptxPavel ( NSTU)
Synthetic fiber production is a fascinating and complex field that blends chemistry, engineering, and environmental science. By understanding these aspects, students can gain a comprehensive view of synthetic fiber production, its impact on society and the environment, and the potential for future innovations. Synthetic fibers play a crucial role in modern society, impacting various aspects of daily life, industry, and the environment. ynthetic fibers are integral to modern life, offering a range of benefits from cost-effectiveness and versatility to innovative applications and performance characteristics. While they pose environmental challenges, ongoing research and development aim to create more sustainable and eco-friendly alternatives. Understanding the importance of synthetic fibers helps in appreciating their role in the economy, industry, and daily life, while also emphasizing the need for sustainable practices and innovation.
How to Make a Field invisible in Odoo 17Celine George
It is possible to hide or invisible some fields in odoo. Commonly using “invisible” attribute in the field definition to invisible the fields. This slide will show how to make a field invisible in odoo 17.
2024.06.01 Introducing a competency framework for languag learning materials ...Sandy Millin
http://sandymillin.wordpress.com/iateflwebinar2024
Published classroom materials form the basis of syllabuses, drive teacher professional development, and have a potentially huge influence on learners, teachers and education systems. All teachers also create their own materials, whether a few sentences on a blackboard, a highly-structured fully-realised online course, or anything in between. Despite this, the knowledge and skills needed to create effective language learning materials are rarely part of teacher training, and are mostly learnt by trial and error.
Knowledge and skills frameworks, generally called competency frameworks, for ELT teachers, trainers and managers have existed for a few years now. However, until I created one for my MA dissertation, there wasn’t one drawing together what we need to know and do to be able to effectively produce language learning materials.
This webinar will introduce you to my framework, highlighting the key competencies I identified from my research. It will also show how anybody involved in language teaching (any language, not just English!), teacher training, managing schools or developing language learning materials can benefit from using the framework.
Operation “Blue Star” is the only event in the history of Independent India where the state went into war with its own people. Even after about 40 years it is not clear if it was culmination of states anger over people of the region, a political game of power or start of dictatorial chapter in the democratic setup.
The people of Punjab felt alienated from main stream due to denial of their just demands during a long democratic struggle since independence. As it happen all over the word, it led to militant struggle with great loss of lives of military, police and civilian personnel. Killing of Indira Gandhi and massacre of innocent Sikhs in Delhi and other India cities was also associated with this movement.
The French Revolution, which began in 1789, was a period of radical social and political upheaval in France. It marked the decline of absolute monarchies, the rise of secular and democratic republics, and the eventual rise of Napoleon Bonaparte. This revolutionary period is crucial in understanding the transition from feudalism to modernity in Europe.
For more information, visit-www.vavaclasses.com
2. Introduction
The complexity of anatomy , physiological role of talus
in functioning of lower extremity and variability of
fracture pattern often complicates the outcomes of
talus fracture
To gain full confidence in the treatment , orthopaedic
surgeon should have thorough knowledge of osseous
anatomy and vascular supply and modern method of
fixation .
Surgeon should be prepared to deal with complications
which often occur.
3. HISTORY
• Roman Times- The heel bone of horse was
used as dice and was called Taxillus. This
Word evolved into Talus
• Year 1919-Anderson – reported the first series
of talar neck fractures in World War I pilots and
coined the term Aviators Astragalus.
• YEAR 1943- BLAIR described talectomy of the
Talus body with tibial slide fusion to the head and
neck of talus.
4. • Year 1970- Hawkins – presented
classification of neck of talus fracture
based on pattern of injury and disruption of
blood supply .
• He determined the risk of osteonecrosis to
talar dome
5. YEAR 1978- Canale and Kelly Expanded the
HAWKINS classification system and
introduced type 4 .
Canale – pioneered specific radiographic
techniques for talus
6. ANATOMY
• Second largest tarsal bone.
• Ossification – from one centre which appear
in 6th month of intrauterine life
• 60 % is covered with articular cartilage
7. • PARTS OF TALUS
1. HEAD
2. NECK
3. BODY
4. LATERAL PROCESS
5. POSTERIOR PROCESS
8. BODY OF TALUS
• 5 surfaces:-
• 1. superior surface
• 2. Inferior surface
• 3.medial surface
• 4. lateral surface
• 5.posterior surface
9. • NECK OF TALUS
• Constricted potion of bone between the body
and the oval head .
• Directed forward , medial word , downward
• Angle of medial deviation is 15 to 20 degree in
adults
• Plantar deviation is 24 degree approx
• Neck body angle is 150 degree in adults
• Relatively thin diameter makes it weaker area and
hence more vulnerable to fractures
10. HEAD OF TALUS
• Anterior articular surface is large , oval and convex
articulating with navicular bone
• Inferior surface have two facets medial and lateral for
articulation with calcaneum
11. • TARSAL CANAL
• Formed of sulcus of
inferior surface of talus
and superior sulcus of
calcaneum
• Contents- artery of
tarsal canal and
talocalcaneal
interosseous ligament
12. • Posterior process has a
medial and lateral
tubercle separated by a
groove for the flexor
hallucis longus tendon
18. • EXTRAOSSEOUS ARTERIES INCLUDE ANTERIR TIBIAL OR
DORSALIS PEDIS ARTERY WHICH IS SMALLER TERMINAL
BRANCH OF POPLITEAL ARTERY
• POSTERIOR TIBIAL ARTERY WHICH IS LARGER TERMINAL
BRANCH OF POPLITEAL ARTERY
• PEROFORATING PERONEAL ARTERY BRANCH OF
POSTERIOR TIBIAL ARTEY
• THESE ARTEIES ANASTOMOSE TO FORM SLING AROUND
THE TALUS WHIS IS SOURCE OF INTERAOSSEOUS BLOOD
SUPPLY OF TALLUS
19.
20. • POSTERIOR TUBERCLE is
directly supplied
POSTERIOR TUBERCLE
ARTERY
• ARTERY OF THE TARSAL
CANAL which branches
around 1cm proximal to
MEDIAL AND LATERAL
PLANTAR ARTERIES IS THE
MAJOR SUPPLIER OF
HEAD BODY OF TALUS
• DELTOID ARTERY which is
the BRANCH OF ARTERY
OF TARSAL CANAL it
directly supply THE
BLOOD TO MEDIAL HALF
OF TALAR BODY
POSTETIOR
TIBIAL
ARTERY(47
%)
MEDIAL AND LATERLA
PLANTAR ARTERIES
DELTOID
BRANCHES
POSTERIOR TUBERCLE
ARTERY
ARTERY TO TARSAL CANAL
21. • SINUS TARSI ARTERY -- THIS ARTERY IS
FORMED BY ANASTOMOSIS BETWEEN
BRANCHES OF POsTERIOR TIBIAL ARTERY
TIBIAL ARTERY AND PERFORATING PERONEAL
ARTERIES IN THE TARSAL CANAL….THIS
ARTERY SUPPLIES LATERAL ONE 8TH OF TARSAL
BODY
22. Blood supply of talus- INTERAOSSEOUS
• HEAD IS SUPPLIED FROM
TWO SOURCES ….MEDIAL
SUPERIOR HALF IS SUPPLIED
BY DORSALIS PEDIS ARTERY
BRANCHES…….INFERIOR
HALF IS SUPPLIED DIRECTLY
FROM ARTERY OF TARSAL
SINUS
• BODY OF TALUS IS SUPPLIED
BY ANASTOMOTIC ARTERY
OF TARSAL CANAL….
MIDDLE ONE THIRD OF TALUS CORONAL
SECTION
23. • THE DELTOID
BRANCHES WHICH
SUPPLIES THE BODY ON
ITS MEDIAL SURFACE
,,,IT SUPPLIES MEDIAL
ONE THIRD OF BODY OF
TALUS
MIDDLE ONE THIRD OF TALUS SAGITAL
SECTION
26. ANATOMICAL CLASSIFICATION OF TALUS FRACTURE :-
• 1. Talar neck fracture
• 2. Talar body fracture
• 3. Talar head fracture
• 4. Lateral process fracture
• 5. Posterior process fracture
27.
28. CLINICAL PRESENTATION
• Talus fractures frequently occur in a young, active,
and mobile population
• History of high velocity injury present
• Clinically :-
Intense pain , unable to move ankle,
Gross edema and echymosis usually present
When there is subluxation or dislocation the normal
contours of ankle and hind foot are distorted
Open injury may occur if there is significant
distortment
30. • CANALE AND KELLY VIEW
view of the talar neck
achieved by internal rotation
of the foot by placing the foot
plantigrade on an x-ray film
and angling the beam at 75
degrees to the perpendicular
Gives best view of talus neck
Useful intraoperatively to
check alignment of neck and
to confirm that varus
misalignment has been
avoided
31. • CT SCAN
give excellent visualization
of the congruity of the
subtalar joint and provide
superior details of fracture.
small but significant
fractures of the inferior
aspect of the talus, are
better appreciated on CT
scans compared to plain
xray films alone.
32. • MRI SCAN
• demonstrates
osteonecrosis most
effectively.
• Use of titanium screws
have been preffered if
AVN of bone is
suspected
33. FRACTURE NECK OF TALUS
Constitue 30 % of talus fractures.
MECHANISM OF INJURY
Forced hyperdorsiflexion of the ankle and
impingement of the talar neck on the distal
anterior tibia .
Axial load to plantar foot causes talar neck
fracture
34. HAWKIN CLASSIFICATION OF
TALAR NECK FRACTURE
• Hawkins 1970 - talar neck fractures into three
type
• Canale and Kelly added type IV
• Based on displacement of body of talus.
• Useful to perdict long term outcome and
development of avn of talar body
35. HAWKINS TYPE 1
• Undisplaced fracture of
talar neck.
• Here medial blood
supply is still assured
36. HAWKINS TYPE 2
• Displaced fracture of
the talar neck with
subtalar dislocation or
subluxation.
• The medial blood
supply may be
preserved.
37. HAWKINS TYPE 3
• Displaced fracture of
the talar neck with
dislocation or
subluxation of the talar
body from both the
tibiotalar and subtalar
joints.
• All medial blood supply
to the body is disrupted
38. HAWKINS TYPE 4
• Displaced fracture of
the talar neck with
dislocation or
subluxation of the
talonavicular , tibiotalar
, and subtalar joints.
• Worst prognosis
because of avn of the
body and often of the
head fragment
40. TREATMENT
• Goals of treatment:
1. Early anatomic reduction of the neck fracture
2. Reduction of dislocated joints
3. Stable fixation
4. Avoidance of complications
41. Treatment
Hawkins type 1 fracture
• Nonoperative Management
Considered for fractures in which there is no
displacement of the fracture line and no
incongruity of the subtalar joint.
SHOULD BE CONFIRMED WITH CT SCAN IF
DOUBTFULL
42. Non operative management
Treated with below knee non
weight bearing cast with ankle in
slight equinus for 1 month
Cast should be removed and
short leg walking cast is applied
for 2 more months until Clinical
and x-ray signs of healing
appears.
Once secure union is achieved
active range of motion and
progressive weight bearing as
tolerated is started
44. • HAWKINS TYPE 2
• NON OPERATIVE
Achieving closed reduction is very difficult.
Should be only attempted if surgery is
delayed.
45. HAWKINS TYPE 2 CLOSED REDUCTION
• firstly, adequate analgesia and sedation
• technique involves bringing the foot, including the
talar head, to the residual talar body fragment
• requires the talar body to be reduced within the
ankle mortise
• the knee is flexed and the foot is flexed plantar ward.
This relaxes the gastrocsoleus complex and brings
the talar head fragment into proper relation to the
body
46. • At that point, any varus or valgus
malalignment can be corrected as well
• reduction is achieved, excessive dorsiflexion
will cause a redisplacement of the head
fragment, and therefore radiographs to
confirm reduction should be performed with
the foot in a comfortable position of equinus
49. • Anterolateral approach is usuallyy applied for
treatment of talus fracture
• Anteromedial approach is used along with
anterolateral approach in order to expose talar
neck
• Anteromedial approach combined with medial
malleolar osteotomy helps the better exposure of
talar body.
50. • HAWKINS TYPE 3 AND 4
• Most authors agree that group III and IV cannot be
reduced and held by closed attempts
• Almost all require surgical stabilization.
• Most patients require additional surgery for relief of
complications resulting from the initial injury
51. • TYPE 3 & TYPE 4
• SCREW FIXATION
ANTERIOR TO POSTEROR
POSTERIOR TO ANTERIOR
• DIRECT PLATE FIXATION
52. Advantages Disadvantage
s
Anterior-to-posterior
screw fixation1
1. Direct visualization of
fracture reduction
1.Difficult to insert
perpendicular to fracture
line
2. Avoidance of articular
cartilage damage
2.Less strong compared
to posterior-to-anterior
screws and plate fixation
3. Use of compression
screws where indicated
3.Inappropriate use of
compression may cause
malalignment , especially
varus
Screw fixation
53. Advantages Disadvantages
Posterior-to-anterior
screw fixation
Stronger fixation
compared with anterior
screw fixation
Indirect visualization of
reduction; may require
change in positioning
Easily inserted
perpendicular to fracture
line
Some cartilage damage to
posterior talus.
May cause less soft tissue
disruption
Risk of iatrogenic nerve
damage
55. • External Fixation
Limited roles:
• Multiply injured
patient with talar neck
fracture in whom
definitive surgery will
be delayed.
• Temporary measure to
stabilize reduced joints
57. AVN OF TALUS
• Most common complication of talar neck
fracture.
• Extent of involvement of talar body by
osteonecrosis is directly related to degree of
vascular disruption
58. AVN: Incidence after Talus Fracture
• Hawkins (1970)
I 0%
II 42%
III 91%
• Canale(197
2):
– I: 15 %
– II: 50 %
– III: 85 %
– IV: 100 %
Behrens (1988):
Overall 25 %
59. HAWKIN’S SIGN
Osteonecrosis is identified
based on AP radiograph
between 6 and 8 weeks
Subchondral lucency is
indicative of relative
osteopenia secondary to
bony resorption and an
intact blood supply
Progresses from medial to
lateral due to vascular re-
establishing from medial
side of dome through
deltoid ligament
Indicative of diffuse
osteopenia with vascular
congestion suggests
continuity of blood supply
60. AVN: Diagnosis
• Technetium bone scan
and MRI are used to
evaluate osteonecrosis
and also condition of
articular cartilage in
MRI
Osteonecrosis of talar body
after 6 months of fracture
65. TALAR BODY FRACTURE
• DEFINITION-fractures of the talar body are intra-
articular injuries in which the articular surfaces of
the tibiotalar and the subtalar joints are involved.
• RADIOGRAPHIC –LATERAL XRAY VIEWS
fractures extending into or posterior to the lateral
process of the talus are defined as talar body
fractures
whereas fractures anterior to the lateral process
are defined as talar neck fractures.
66. • MECHANISM OF INJURY
• AXIAL COMPRESSION OF THE TALUS BETWEEN
TIBIAL PLAFOND AND THE CALCANEUS
• USUALLY SEEN IN MOTOR VEHICLE ACCIDENTS
AND FALLS FROM HEIGHT
67. • CLASSIFICATION
• SNEPPEN ET AL CLASSIFIED
BASED ON ANATOMICAL
LOCATION
• I- transchondral dome fractures;
• II- shear fractures;
• III- posterior tubercle fractures;
• IV- lateral process fractures; and
• V- crush fractures
69. • MULLER AO/OTA
CLASSIFICATION
• fracture are grouped
according to increasing
severity with increasing
treatment difficulty and
worst prognosis
• C1- osteochondral injuries
with ankle joint
involvement
73. • SURGICAL ORIF- As surface for fixation is
always articular, fixation is done by headless
compression screw or bioabsorbable pins
74. COMMINUTED FRACTURES OF BODY
Difficult to treat
Accurate replacement of fragments is near
impossible
Long term results- bad
IN SUCH CASES TALECTOMY ALONG WITH
CALCANEOTIBIAL FUSION IS PREFFERRED.
GIVES PATIENT PAINLESS AND STABLE WALKING
FOOT
76. • PROBLEMS FACED WITH TALOCALCANEAL
FUSION
DECREASE IN HEIGHT AND THE RIGIDITY OF
ANKLE JOINT
BLAIR SUGGESTED ALTERNATIVE PROCEDURE-
TIBIOTALAR ARTHRODESIS
78. • ADVANTAGES OF TIBIO TALAR ARTHRODESIS OVER
CALACANEOTIBIAL FUSION
Position of foot is unchanged
Weight bearing thrust is placed on more or less normal
undisturbed joint tissue.
No shortening
After surgery- still slight flexion and extention of the foot
on leg , the two subtalar facets and talonavicular joint is
possible.
80. Talus head fracture
• Incidence- 5 to 10 % of talar injuries
• Mechanism of injury-
axially directed loading and compression of talar
head
Dorsal compression fracture of anterior tibial
plafond
• injuries to calcaneocuboid and subtalar joint are
common with these injuries
82. TREATMENT
• PRINCIPLES
Maintainance of alignment of dorsomedial arch
of foot.
Prevention of talonavicular joint incongruity and
instability
Reduction of displaced talar head fragment
83. • Fracture without displacement
Well molded short leg cast for 6 weeks
Weight bearing is started at 6 weeks
84. • Displaced fractures and those associated with
joint subluxation or dislocation
ORIF
Small comminuted segments can be excised
Larger fragments are reduced with screws
ranging from 2.0 to 3.5 mm
85. COMPLICATIONS AND PROGNOSIS
• TALONAVICULAR ARTHRITIS IN DISPLACED
FRACTURE
Conservatively managed with longitudianal arch
support shoe
If conservative fails then talonavicular
arthrodesis releives symptoms
• NONUNION- UNCOMMON
MALUINION - TALONAVICULAR JOINT
SUBLUXATION
86. FRACTURE OF LATERAL PROCESS OF
TALUS
• RADIOGRAPHIC XRAYS
• VON KNOCH ET AL
described v sign
• V SiGN- it is the contour of
lateral process over lateral
view xrays
• V sign positive- any
disruption in contour of V
indicating fracture lateral
processs -VE V SIGN
88. treatment
• Type I fractures can be treated in a non weight-bearing
cast for 6 weeks, unless they are displaced or involve a
significant portion of the talar side of the posterior facet, in
which case they should be treated by ORIF.
• Type II fractures benefit from débridement of frature
fragments
• Type III fractures- treated conservatively with cast
application
• If non union occurs the debridement of fragments is
advised
89. POSTERIOR PROCESS FRACTURES
• These include the medial and
lateral tubercle fractures
• Fracture occurs in a severe
ankle inversion injury where
posterior talofibular ligament
avulses the lateral tubercle
• Undisplaced fracture treated
with a short leg cast for 4
weeks
• Displaced fracture treated
with primary excision of small
fragments or ORIF when entire
posterior process is fractured
AS THERE IS ENOUGH COMENSATORY MOVEMENT WHICH DEVELOPS IN PATIENTS MIDTARSAL JOINT ….ENABLING HIM TO WALK WITH SLIGHT LIMP
Four years after tibiocalcaneal fusion by compression arthrodesis and autogenous iliac bone grafting. B, Sixteen
years after fusion, degenerative changes at midtarsal joints are present but patient is active with mild symptoms