Subido por juan camilo mateus jaime

Fracturas-de-Astragalo-Abiel-Garza-Borjon.compressed

Anuncio
Hospital Universitario
Dr. José Eleuterio González
Fracturas de Astrágalo
Asesor – Dr. Ángel Arnaud
Dr. Abiel Eugenio Garza Borjón
RIV TyO
Introducción
• “Articulación universal
del pie”
• 1% de todas las
fracturas (Alta energía)
– Accidente vehicular
– Caídas de altura
• Segundo hueso en
fracturarse por
incidencia (+
Calcáneo)
Introducción
• Astrágalo proviene
de la palabra
– Francesa “Talo” –
Tobillo
– Latín “Taxillus” –
Dado
– Griego “Astragalus” –
Dado
Introducción
• Descritas desde 1608
– Fabricius de Hilden - Talectomía
• 1818 (James Syme)
– Tratamiento de fracturas Amputación distal a rodilla
(Mortalidad de 25%)
• 1952 (Coltart)
– Descripción de 228 casos
acumulados por la 2da Guerra
Mundial
• 1970 (Hawkins)
– Describe clasificación pronóstica para
necrosis avascular
Anatomía Esquelética
• Articulaciones (Movilidad
de retro-pie y medio-pie):
– Sub-astragalina
– Tarsal transversa
– Tobillo
• 2/3 cubierto por cartílago
articular
(5 carillas articulares)
– Fracturas desplazadas =
Sub/luxación
13.1.1 Talus (Figures 13.6–13.7, 13.17
Anatomía Esquelética
The talus is called the astragalus in other anim
situated between the tibia and fibula superiorly
to this bone. It rests atop the calcaneus and arti
lower member of the talocrural joint. Talar va
a. The head is the rounded, convex, distal art
of the navicular.
• No inserciones
tendinosas
medial malleolar
articular surface
body
b. The body is the squarish bulk of the bone
neck
c. The trochlea isneck
the saddle-shaped articula
and medial malleolar surfaces (or facets
respectively.
d. The neck connects the head of the talus to
lar facets on the neck, formed by contact w
head
strong dorsiflexion of the foot
at the ankle
squatting facets.
lateral malleolar
articular surface
body
• Transfiere el peso del
pie a la tibia y peroné.
medial subtalar
facet
posterior subtalar
facet
lateral process
Figure 13.7 Right talus. Left: medial view; right: lateral view. Dorsal is up. Natural size.
• Se divide en 3 partes y
2 procesos:
e.
surface of the talar body. It is so named because it transmits the tendon of this muscle, a
calf muscle that plantarflexes the foot and hallux.
f. The subtalar (or calcaneal) facets on the inferior aspect of the talus are usually three in
number and variable in shape.
trochlea
1. The anterior subtalar (or calcaneal) facet is the most anterior facet on the plantar
(inferior) surface of the talus, often somewhat continuous with the articular surface of
posterior process
the talar head.
2. The medial subtalar (or calcaneal) facet is highly variable, sometimes separated
from — but often merging to a greater or lesser extent with — the anteriorgroove
subtalar
for
flexor hallucis longus
facet (see Figure 3.1 for examples).
3. The posterior subtalar (or calcaneal) facet is the largest facet on the plantar surface
anterior
fa
neck
medial
malleolar
vertical groove on the posterior
The groove for flexor hallucis longus is the short, nearly
surface
– Cuerpo, Cuello y
Cabeza
– Lateral y posterior
face
head
superior
articular surface
lateral malleolar
surface
lateral process
posterior subtalar
facet
ne
Anatomía Esquelética
Cabeza del Astrágalo
• “Acetabulum Pedis”
– Porción distal del
astrágalo que hace
“nido” a la articulación
• Formado por
– Superficie intermedia y
anterior del calcáneo
– Superficie articular del
escafoides
– Unidas por los
ligamentos inferior y
superomedial
calcaneo-escafoideos
SK: Anatomy of the foot and ankle, Philadelphia, 19
Anatomía Esquelética
Cabeza del Astrágalo
• Se mantiene en
posición en “plano
axial”:
– Lateral – Ligamento
bifurcado
calcáneoescafoideo
– Medial – Tibial
posterior y
ligamento “Spring
o CalcáneoEscafoideo”
A
C
B
Figure 39-4 The talocalcaneal angle demonstrates
deviation of the talus on the calcaneus, not only fro
declination angle of the talar neck but also from the
articulation.
a keystone. This unique shape provides maximal
congruence in the articular joint when the talu
dorsiflexed position.
The inferior surface of the talar body consis
facies articularis calcanea posterior tali.134 This
surface is quadrilateral and is concave in the long
flat transversely. It articulates with the posterior
the calcaneus (Fig. 39-4).
2104
Anatomía Esquelética
Cabeza del Astrágalo
• Porción anteroinferior medial es
cuadrilateral u oval
– Se articula con faceta
anterior del
calcáneo.
Anatomía Esquelética
Cuello del Astrágalo
• Cuenta con 4
superficies:
– Superior, lateral,
medial e inferior.
• No cubierto por
superficie articular
• Cuello angulado
– 24º medial (10-44º)
– 5-50º plantar
– Parte más
vulnerable a
fracturarse
Anatomía Esquelética
Cuello del Astrágalo
• Superior
– Limitado por:
• Domo del astrágalo
(Posterior)
• Cabeza del astrágalo
(Anterior)
– Cápsula Tibioastragalina se inserta
en superficie superior
• Aledaño a inserción
capsular de articulación
astrágalo-escafoidea.
13.1.1 Talus (Figures 13.6–13.7, 13.17)
Anatomía Esquelética
Cuello del Astrágalo
The talus is called the astragalus in other animals. It is the second largest of the tarsals and is
situated between the tibia and fibula superiorly and the calcaneus inferiorly. No muscles attach
to this bone. It rests atop the calcaneus and articulates distally with the navicular. It forms the
lower member of the talocrural joint. Talar variation is illustrated in Figure 3.1 of Chapter 3.
a. The head is the rounded, convex, distal articular surface of the talus. It fits into the hollow
of the navicular.
b. The body is the squarish bulk of the bone posterior to the talar neck.
c. The trochlea is the saddle-shaped articular surface of the body. Its sides are the lateral
and medial malleolar surfaces (or facets), which articulate with the fibula and tibia,
respectively.
d. The neck connects the head of the talus to the body. Occasionally there are small articular facets on the neck, formed by contact with the anterior surface of the distal tibia during
strong dorsiflexion of the foot at the ankle (or talocrural) joint. These facets are called
squatting facets.
• Inferior
– Forma el techo del
seno del tarso,
canal del tarso.
– Punto de inserción
del ligamento:
facet for the navicular
head
• Astrágalo-calcáneo
medial
(Estabilizador
de
malleolar
surface
articulación subastragalina)
head
anterior subtalar
facet
neck
superior
articular surface
neck
medial
subtalar
facet
lateral malleolar
surface
lateral process
sulcus tali
trochlea
posterior subtalar
facet
posterior process
groove for
flexor hallucis longus
groove for
flexor hallucis longus
Figure 13.6 Right talus. Left: dorsal (or superior) view; right: plantar (or inferior) view. Distal is up. Natural size.
Anatomía Esquelética
Cuello del Astrágalo
• Lateral
– Forma cóncava
– Inserción del aspecto
medial del retínaculo
extensor inferior
• Medial
– Forma convexa
– Inserción de ligamentos
astrágalo-escafoideos
L
M
Dorsal metatarsal ligaments
Lateral talocalcaneal ligament
Dorsal c u n e o c u b o i d ligament
Long plantar ligament
Cuboid bone
Fibularis (peroneus) longus
Dorsal calcaneocuboid ligament
Fibularis (peroneus) brevis
Right foot: medial view
Posterior tibiotalar part
Medial (deltoid)
ligament of ankle )
Medial talocalcaneal ligament
Tibiocalcaneal part
Tibionavicular part
Anterior tibiotalar part
Posterior process of talus
Dorsal talonavicular ligament
Posterior talocalcaneal
igament
Navicular bone
Dorsal cuneonavicular ligaments
Medial cuneiform bone
Calcaneal
(Achilles)
tendon
(cut)
Dorsal intercuneiform ligament
Dorsal tarsometatarsal ligaments
u
...
1st metatarsal bone
Tuberosity
ii i
^
J
j ,
•;
^y^i
Tibialis anterior tendon
Tibialis posterior tendon
„
Short plantar
ligament
Plantar calcaneonavicular (spring) ligament
Sustentaculum
tali
^ L o n g plantar ligament
Anatomía Esquelética
Cuerpo del Astrágalo
• Vista coronal – Polea
• Vista axial – “Piedra Angular”
– Anterior “+ ancha”
• Dividido en 5 superficies
–
–
–
–
–
Lateral
Medial
Superior
Inferior
Posterior.
Anatomía Esquelética
Cuerpo del Astrágalo
• Superficie Lateral consiste
de:
– Superficie articular larga
– Fascia Maleolaris Lateralis
• Articula con peroné distal
– Proceso lateral
• Componente no articular
donde se inserta:
– Lig. Astrágalo-calcaneo lateral
– Ligamento anterior y posterior
Astrágalo-peroneo
Right foot: lateral view
Fibula
Anterior and
Posterior
tibiofibular
ligaments
Superior fibular (peroneal)
etinaculum
i
Posterior talofibular ligament
) Component s of lateral
Calcaneofibular ligament
> (collateral) ligament
Anterior talofibular ligament \ of ankle
Interosseous talocalcaneal ligament
Dorsal talonavicular ligament
Calcaneonavicular ligament
(
caneocuboid ligament
J
__
Blfurcate
h
^ament
Dorsal cuboideonavicular ligament
Dorsal cuneonavicular ligaments
Dorsal intercuneiform ligaments
Dorsal tarsometatarsal ligament
alcaneal (Achilles)
endon (cut)
nferior
ibular
peroneal)
retinaculum
Dorsal metatarsal ligaments
Lateral talocalcaneal ligament
Long plantar ligament
Fibularis (peroneus) longus
Dorsal c u n e o c u b o i d ligament
Cuboid bone
Dorsal calcaneocuboid ligament
Anatomía Esquelética
Cuerpo del Astrágalo
• Superficie medial cuenta
con 2 áreas:
– Superior
• Ocupada por faceta
articular
– Fascia malleolaris medialis
• “Cola”
– Inserción de lig. deltoideo.
– Inferior
• No articular
• Mitad anterior con
forámenes vasculares.
respectively.
d. The neck connects the head of the talus to the body. Occasionally there are small articular facets on the neck, formed by contact with the anterior surface of the distal tibia during
strong dorsiflexion of the foot at the ankle (or talocrural) joint. These facets are called
squatting facets.
Anatomía Esquelética
Cuerpo del Astrágalo
• Superficie Inferior
facet for the navicular
head
anterior subtalar
– Facies articularis
neck
facet
calcanea posterior superior
neck
articular surface
medial
tali.
malleolar
lateral malleolar
surface
head
medial
subtalar
facet
surface
lateral process
• Superficie cuadrilateral
trochlea
y cóncava en el eje posterior subtalar
facet
largo
posterior process
groove for
sulcus tali
groove for
flexor halluciscon
longus faceta
flexor hallucis longus
• Se articula
posterior
calcáneo.
Figure 13.6 Right
talus. Left: dorsaldel
(or superior)
view; right: plantar (or inferior) view. Distal is up. Natural size.
respectively.
Anatomía Esquelética
Cuerpo del Astrágalo
• Superficie posterior
consiste de Tubérculos
d. The neck connects the head of
lar facets on the neck, formed b
strong dorsiflexion of the foot
squatting facets.
head
neck
• Postero-lateral (+ Prominente)
• Postero-medial
– Flanquean el tendón flexor
largo del 1er ortejo.
superior
articular surface
medial
malleolar
surface
lateral malleo
surface
lateral proce
trochlea
posterior su
facet
• PL también llamado
Proceso de Stieda o Os
Trígono
(3-8% de los
pacientes)
posterior process
groove for
flexor hallucis longus
Figure 13.6 Right talus. Left: dorsal (or superior) view; right: plantar (or infer
276
CHAPTER 13 Foot: Tarsals, Metatarsals, and Phalanges
Anatomía Vascular
• Estudiada a detalle por la
incidencia de NAV después
de las fracturas y
luxaciones
• Irrigación extra-ósea e
intra-ósea extensa
• Al no haber inserciones
musculares hay pocas
áreas de ingreso vascular
Anatomía Vascular
Irrigación Arterial Extra-ósea
• Ramas de:
– Tibial posterior(+
Aporte)
– Pedia dorsal / tibial
anterior
– Arterias peroneas
• Crean anastomosis
que rodean al
astrágalo en su región
no cartilaginosa.
Anatomía Vascular
Irrigación Arterial Extra-ósea
• Tibial Posterior (2 ramas)
– Rama Deltoidea
– Plexo vascular
Anatomía Vascular
Irrigación Arterial Extra-ósea
• Tibial Posterior (2
ramas)
– Rama Deltoidea
• Pasa entre las porciones:
– Astrágalo-tibial
– Astrágalo-calcáneo del
ligamento deltoideo.
• Irriga la región medial
del cuerpo del astrágalo
Anatomía Vascular
Irrigación Arterial Extra-ósea
• Tibial Posterior (2
ramas)
– Plexo vascular
• Se forma por
anastomosis de:
– Arteria calcanea (T.
Posterior)
– Arteria peronea
• Se encuentra sobre el
tubérculo medial del
astrágalo
Anatomía Vascular
Irrigación Arterial Extra-ósea
Interosseous Muscles and Deep Arteries of Foot
• Tibial Anterior (Pedia Dorsal)
Dorsal view
Fibularis (peroneus)
longus tendon (cut)
• Provee irrigación a través de 2
grupos de vasos.
Fibularis (peroneus)
brevis tendon (cut)
Cuboid bone
Lateral tarsal artery
Tuberosity of 5th metatarsal bone
– Ramas tarsales media /
Ramas de la Arteria Maleolar
anteromedial
Fibularis (peroneus)
tertius tendon (cut)
Posterior perforating branches
(from deep plantar arterial arch)
Dorsal metatarsal arteries
Extensor digitorum
longus tendons (cu
Navicular bone
Dorsalis pedis artery
Medial tarsal artery
Lateral
)
Intermediate / Cuneiform bones
Medial
)
Dorsal tarsometatarsal ligaments
Dorsal metatarsal ligaments
artery
Deep plantar artery passes to
contribute to deep plantar arch
interosseous muscles
Metatarsal bones
Extensor expansions
• Superficie superior del cuello
del astrágalo
Anterior perforating branches
(from plantar metatarsal arteries)
Extensor hallucis longus tendon (cut)
Extensor digitorum brevis and
extensor hallucis brevis tendons (cut)
Dorsal digital arteries
– Rama Maleolar anterolateral
Plantar view
• Anastomosa con arterias
perforantes de la peronea =
Arteria del seno tarsal.
Proper plantar digital arteries
C o m m o n plantar digital arteries
Lumbrical muscles (cut)
Deep transverse metatarsal ligament
and plantar ligaments (plates)
Interosseous muscles
Plantar
Dorsal
A b d u c t o r digiti minimi muscles
Plantar metatarsal arteries
Flexor digiti minimi brevis muscle
Deep plantar arch
Lateral plantar artery (cut)
Tuberosity of 5th metatarsal bone
Flexor hallucis longus tendon (cut)
Anterior perforating branches
(to dorsal metatarsal arteries)
Sesamoid bones
Insertion of adductor hallucis
and lateral head of flexor hallucis
brevis muscles (cut)
Insertion of abductor hallucis
and medial head of flexor hallucis
brevis muscles (cut)
Medial origin of flexor hallucis
brevis muscle (cut)
Deep plantar artery (from dorsalis
pedis artery)
Posterior perforating branches
(to dorsal metatarsal arteries)
Plantar metatarsal ligaments (between
bases of metatarsal bones)
Medial cuneiform bone
Anatomía Vascular
Irrigación Arterial Extra-ósea
• Arteria Peronea
• Irrigación a través de 2
fuentes.
–
Plexo vascular por ramas
anastomosadas:
• A. Peronea + A.
Calcanea (T. Posterior)
• Ubicadas en tubérculo
posterior de astrágalo
– Arteria del seno tarsal
• Ramas perforantes de la
peronea se anastomosan
con otras.
Anatomía Vascular
Irrigación Arterial Extra-ósea
• Arteria del Seno Tarsal
– Formada por anastomosis de
varias arterias de la región
lateral:
• A. Antero lateral maleolar (T.
Anterior)
• A. Proximal/distal lateral
tarsal
• Arteria peronea
– Principal aportador a
estructuras intra-senosas y
del astrágalo.
Anatomía Vascular
Irrigación Arterial Extra-Ósea
• Arteria del canal
Tarsal
– Nace de la tibial
posterior
– 1 cm proximal al
origen de las arterias
plantares medial y
lateral
– Pasa en la mitad
posterior más cerca del
astrágalo que el
Anatomía Vascular
Irrigación Arterial Extra-Ósea
• Arteria del canal
Tarsal
– Se anastomosa
• Seno tarsal para
formar la arteria del
“tarsal sling”
• Da ramas que
pasan por la parte
inferior del cuello
Anatomía Vascular
Irrigación Arterial Intra-Ósea
• Cabeza del Astrágalo
– Dos fuentes
• Ramas de Tibial
anterior (Pedia dorsal)
– Mitad supero-medial
• Tarsal Sling –
– Mitad latero-inferior
Anatomía Vascular
Irrigación Arterial Intra-Ósea
• Cuerpo del Astrágalo
– Aporte mediante vasos
perforantes de las 5
superficies
– 2/3 laterales del cuerpo
- Arteria del canal tarsal
• Aporte a 4 de las 5 ramas
principales del cuerpo
Anatomía Vascular
Irrigación Arterial Intra-Ósea
• Cuerpo del Astrágalo
– Tercio medial
• Arteria Deltoidea
– Tubérculo Posterior
• Ramas pequeñas de la
anastomosis posterior
de:
– Arteria peronea
– Ramas de tibial
posterior.
Fracturas de Cabeza
de Astrágalo
Incidencia
• < 10% de las
fracturas del
astrágalo
involucran la
cabeza.
• Se presentan con
lesiones
asociadas en:
– Cuello
– Cuerpo
– Luxación-fractura
de complejo de
Mecanismo de lesión
• Resultado de caídas o
accidentes vehiculares
• Tipos de fractura
– Compresión
• Impacto en eje
longitudinal del pie en
flexión plantar
– Cizallamiento
• Causado por inversión
• Escafoides separa
porción de la cabeza del
astrágalo
Evaluación Clínica
• Historia de flexión
plantar al momento
del traumatismo
• Dolor en la región
dorsal de la
articulación
astrágalo-escafoidea
• Dolor a la
movilización de
articulación medio
tarsal
Evaluación Radiográfica
• AP, Lateral,
Oblicuas del pie
• Delinear margen
de cabeza y cuello
(AP y Lateral)
• Duda - TAC
Tratamiento
• No desplazadas
– Yeso sin apoyo por
4 semanas
– Apoyo progresivo
hasta que haya
consolidación y
alivio del dolor
Tratamiento
• Desplazada
– Reducción abierta y
fijación interna
– Meta de restaurar
• Superficie articular
– Art. Astrágalo escafoidea
– Art. Astrágalo calcaneo
• Longitud de columna
medial y lateral
Tratamiento
• Desplazada
– Fragmentos
• Pequeños – retirarlos por
posibilidad de bloquear
articulación astrágaloescafoidea
• Grandes que causen
acortamiento de columna
medial
– Fij. Externo + Tornillos
Headless/Clavos (4-6
semanas)
– Conminución importante
• Artrodesis astrágaloescafoidea vs Triple
Artrodesis
Fracturas de Cuello
del Astrágalo
Fracturas de Cuello del
Astrágalo
• 50% de las fracturas
en astrágalo
• 20-30% son fracturas
expuestas
• Alto porcentaje de
fracturas se
relacionan a lesiones
en:
– Pie, Tobillo y Columna
Fracturas de Cuello del
Astrágalo
• Complicaciones
principales son:
–
–
–
–
–
–
Necrosis avascular
No-unión
Mal-unión
Infección
Artritis
Pérdida de hueso
Anatomía
Cuello
• Porción mas débil del
astrágalo
– Porosidad por
vasculatura
• Única porción extraarticular
• Orientación:
– Sagital (Caudal)
– Axial (Medial – 24º)
Mecanismo de Lesión
• Hiper-dorsiflexión del pie
– Cuello impacta a la tibia
• Aplastamiento
– Calcáneo y tibia (Sin
movilidad de astrágalo)
– Alta energía
• Lesión de ligamentos interóseos (Desplazamiento
anterior/medial/lateral del
calcáneo)
• Supinación forzada del pie
– Asociada a fx maleolar
Clasificación
• Coltart (1952 – 2da Guerra
Mundial)
– Fracturas
• Avulsiones, Compresión
– Fracturas/Luxaciones
• Fracturas del cuello/Luxación
sub-astragalina
• Fracturas del cuello/Luxación
posterior cuerpo
• Fracturas del cuerpo/Luxación
Sub-astragalina
– Luxaciones
Clasificación Hawkins
• Simple, Útil, Valor pronóstico
– Fracturas de cuello (Imagen
RX al momento de lesión)
• Inicialmente idea:
– Fracturas cuello --Osteonecrosis
– Fracturas del cuerpo --Artritis Postraumatica
• Estudios recientes:
– Tasas similares de Necrosis
avascular y artritis postraumática en ambas
fracturas
graphs.131 In type I injuries, onl
sources of blood supply to
Clasificación Hawkins
• Tipo 1
– No desplazadas
– Relación preservada con
articulación subastragalina.
A
B
C
D
– Fractura acaba en el
aspecto inferior del cuello
– Solo 1 de las 3 fuentes de
irrigación afectada
• Vasos dorsolaterales del
cuello y que van hacia
proximal
Clasificación Hawkins
• Tipo 2
– Fracturas desplazadas del
cuello
+
Subluxación o luxación de
articulación subastragalina
– Luxación puede ser:
• Medial (Inversión) “+”
• Lateral (Eversión)
– Relación entre cuerpo y
tobillo preservada
Clasificación Hawkins
• Tipo 2
– Relación entre cabeza
y escafoides y faceta
anterior preservada
– Al menos 2 de 3
fuentes de irrigación
afectadas
Clasificación Hawkins
• Tipo 3
– Fractura vertical desplazada
del cuello
– Luxación del Cuerpo de
tobillo y articulación
subastragalina
– Cuerpo astragalino extruido
hacia posterior y medial.
– Localizado entre superficie
posterior de la tibia y el
tendón de Aquiles.
Clasificación Hawkins
• Tipo 3
– Cabeza mantiene relación
con escafoides
– Paquete neurovascular tibial
en riesgo con tensión de
piel sobre hueso luxado
– >50% son expuestas
(Postero-medial)
– 3 fuentes de irrigación
afectadas
Clasificación Hawkins
• Tipo 4
Fractura del cuello
+
Luxación del cuerpo
(Tobillo y Subastragalina)
+
Luxación de Cabeza
(Astrágalo-escafoideo)
– Lesión vascular al
cuerpo, cabeza y cuello
Evaluación Clínica
Fractures and Fracture-Dislocations of the Talus ■ Chapter 39
Inferior
surface
• Adultos jóvenes
Tarsal
Superior
surface
Head
sinus
112 + 28
140
Lateral
• Hombres
3:1
process
Skin necrosis
Tarsal
sinus
61
Tarsal
canal
22 + 33
Lateral
process
55
Astragalus
dislocated
• Lesiones asociadas
Neck fractures
– SME
Body fractures
39-9 Talar
neck and talar body fractures can be
• Figure
Maléolo
medial
accurately distinguished by evaluating the position from
the fracture lumbar
line exits the talus at the level of the
• which
Columna
subtalar joint. Numbers indicate number of cases with each
pattern. (From Inokuchi S, Ogawa K, Usami N: Classification
of fractures of the talus: clear differentiation between neck
and body fractures. Foot Ankle Int 17:748-750, 1996.)
attempts to differentiate vertical fractures of the talar neck
Figure 39-10 Displacement of the talus against the skin
causes pressure necrosis, which can lead to development of
an open fracture. These bony protrusions must be evaluated
and treated immediately. (From McKeever FM: Treatment of
complications of fractures and dislocations of the talus. Clin
Orthop Relat Res 30:45-52, 1963.)
that neck and body fractures could be distinguished more
clearly by evaluating the fracture line on the inferior
surface of the talus. The inferior fracture line consistently
propagated either in front of or behind the lateral process
of the talus. Fractures in front of the lateral process entered
the sinus tarsi and thus were extraarticular talar neck frac-
the ankle is distorted, with the rapid onset of swelling
preventing palpation of the displaced talar body.11,101
In these injuries, the pressure and tension from the
displaced bones beneath the unyielding anterior skin are
accompanied by extensive hemorrhagic infiltration of the
tissues and venous thrombosis of the skin.101 This can
result in an area of skin necrosis over the protruding bone
• Dolor, edema importante en pie
• Cuerpo
se palpa
baseddel
on the astrágalo
fracture line at the superior
surface of the
talus caused considerable confusion in making the correct
superficialmente
diagnosis. In evaluating 215 fractures, they recognized
Evaluación Clínica
• Infiltración hemorrágica
– Se promueve a la trombosis
venosa de la piel con
necrosis de piel sobre hueso
(Urgencia - reducción)
• Luxación del cuerpo
posterior
– Tensa capsula posterior,
tendones y paquete neurovascular
– Exploración – Dedos
flexionados, movilidad
produce dolor
Evaluación Radiológica
• AP, Lateral, Mortaja y Oblicuas de
Tobillo y Pie
• Valorar lesiones asociadas:
–
–
–
–
Maléolo medial
Calcáneo
Escafoides
Cuboides
Evaluación Radiológica
• Desplazamiento puede ocurrir en 2
planos:
– Desplazamiento Dorsal-plantar (Rx
lateral)
– Desplazamiento en varo (Menos
apreciada)
– Vista de Canale para evaluar el cuello
Part X ■ Trauma
75°
15°
A
B
Figure 39-11 A, The Canale view, as described by Canale and Kelly, is obtained by everting and plantar flexing the foot in
relation to the x-ray beam. B, The resultant image should move the calcaneus out from underneath the talus to allow an
unobstructed view of the talar neck. (From Banerjee R, Nickisch F, Easley M, DiGiovanni C: Foot injuries. In Browner B, Jupiter J,
Levine A, Trafton, editors: Skeletal trauma, ed 4, Philadelphia, 2009, Saunders.)
the talus within the ankle mortise. The lateral radiograph
stability, and minimization of complications, such as
Evaluación Radiológica
• TAC
– Indicado para delinear la
fractura y desplazamiento.
(1-2mm)
• RM
– No recomendado en agudo
– Sub-agudo
• Útil para evaluar lesiones
ligamentarias,
osteocondrales
– Útil para lesiones tipo 1 (no
desplazadas) confundidas
con esguinces
Tratamiento
• Metas
– Reducción anatómica
– Preservación de la
movilidad
– Estabilidad articular
– Minimizar complicaciones
• Infección, no-unión, malunión, artrosis postraumática, Necrosis
avascular
Tratamiento
• Fracturas Tipo 1
– Conservador
– Osteonecrosis de 0%
(0 – 13%??)
– Presencia de trazo de
fractura incita a buscar el
desplazamiento para la
clasificación, tratamiento
y pronostico. (TAC)
Tratamiento
• Fracturas Tipo 1
– Inmovilizar sin apoyo
por 6-8 semanas con
yeso (Bota chica)
• “Walker” sin apoyo pero
con movilidad le sigue
por 4 semanas
• Apoyo temprano
promueve el
desplazamiento de la
fractura
Tratamiento
• Fracturas Tipo II
– Conservador
• Reducción
anatómica
confirmada por
TAC (Cerrada)
– 49% Requieren de
reducción abierta
Tratamiento
• Fracturas Tipo II
– Conservador
• Bota con flexión
plantar +
Inversión/Eversión
(6 semanas)
• Mal posición causa
deformidad,
limitación en
rangos de
movilidad en subastragalina.
Tratamiento
• Tipo II
– Quirúrgico
• Dificultad en reducción
cerrada
• No relación:
– Tiempo en iniciar cirugía
con el desarrollo de necrosis
avascular
• Necrosis Avascular /Tasa de
Unión afectada por:
–
–
–
–
Desplazamiento
Conminución
Lesión de tejidos blandos
Calidad de reducción
Fractures and Fracture-Disl
Lateral approach
Posterior
tibial
tendon
Medial
approach
Anterior tibial
tendon
Figure 39-17 Surgical approaches to the talus. (From
Sangeorzan BJ: Foot and ankle joint. In Hansen ST Jr,
Swiontkowski MF, editors: Orthopaedic trauma protocols,
New York, 1993, Raven, p 352.)
After open red
placed as describe
the talar neck m
fragment plates
provide no biome
they may offer su
control anatomic
Corticocancellous
imal tibia or the i
tutes may also be
comminution.
No studies hav
tage of using stain
ture fixation. Som
and Thordarson e
allow subsequent
implications of th
POSTOPERATIVE
Most authors agre
fixation, the patie
early motion of
minimum of 10 to
menced until clin
Fractures and Fracture-Dislocations of the Talus ■ Chapter 39
Tratamiento
fractures will be best treated with surgical reduction and
mechanical advantage than anteriorly placed screws,
fixation. Historically, despite a lack of sufficient evidence,
which passed eccentrically through the dorsal part of the
urgent treatment of displaced talar neck fractures was
talar head and neck, oblique to the plane of fracture
advocated as a method for reducing the risk of AVN.
(Fig. 39-14).
However, more recent studies suggest no relationship
The advantages of placing screws from an anterior
between the timing of surgery and the subsequent develdirection include the option to perform direct visualiza7,90,160
Instead, the displacement of the
opment of AVN.
tion of the fracture and avoidance of minor blood vessels
fracture, fracture comminution, soft tissue injury (open
entering posteriorly. After reduction, internal fixation is
fractures), and quality of surgical reduction impact the
accomplished with two titanium 3.5-mm small-fragment
development of AVN, union rates, and overall result.
cortical screws inserted from the talar neck into the
Fractures that are relatively nondisplaced and with
body.136 The cortical screws, whenever possible, should be
inserted as lag screws by overdrilling the near fragment to
absent or minimal comminution may be treated with
provide maximum stability. It is usually possible to insert
fluoroscopically guided closed reduction and minimally
the two screws near the osteocartilaginous junction of the
invasive or percutaneous screw fixation. Closed reduction
head, either both on the medial side or one on the medial
is performed as described above and stabilized with perand one on the lateral side (Fig. 39-15A). These screws are
cutaneously placed K-wires. Careful fluoroscopic imaging
best placed in parallel so that the fragments can compress.
is used to ensure anatomic reduction. Internal fixation is
If the neck is comminuted, screws might have to be placed
then typically performed with screws placed across the
in a nonparallel alignment to function as position screws
fracture site.
to maintain alignment. Lagging the fracture together
Screws may be placed from an anterior to posterior
under such circumstances would lead to shortening of the
direction through small incisions, or alternatively, through
neck, which would result in subtalar subluxation and all
a posterior approach. Although Kirschner wires were used
Figure 39-14 The difference between
posterior and
the problems associated with a malreduction.136
in many earlier studies, Kirschner wires alone should not
anterior
It is oftenAtdifficult
placetoan
times, it isto
necessary
insert one or more screws
be used for fixation
becausescrew
they do insertion.
not provide sufficient
153
mechanically
tested variousto the
through
the cartilaginous
covering of the head at the
stability. Swanson
et al screw
anterior
perpendicular
fracture
line. (From
fixation devices in vitro and found that fixation with
talonavicular joint. If the screw is inserted through the
Swanson
TV, Bray
TJ, provided
HolmesbyGB cartilage,
Jr: Fractures
of head
the should
talar be recessed below
screws provided
superior strength
to that
the screw
Kirschner wires.
The
calculated
theoretic
maximum
shear
the level
the cartilage
39-15B
neck. A mechanical study of fixation.
J of
Bone
Joint (Fig.
Surg
Am and C).54,136 Grob
et al54 showed how the screws should be countersunk and
force across the talar neck during active motion was 1129
74:544-551,
1992.)
positioned relative to the fracture line. Failure to bury the
N. This exceeded the strength provided by Kirschner wires
head sufficiently will result in altered talonavicular
and anteriorly inserted screws but not the strength promotion and subsequent arthritis. Rarely, the fracture
vided by screws placed posteriorly. In addition, because
pattern is so oblique that the only location for the screw
the posteriorly inserted screws were placed across the
is in the medial talar head, requiring partial removal of
central portion of the talar neck and perpendicular to
the medial navicular.25 The surgeon should take great care
the plane of fracture, they theoretically had 101
a better
Part X ■ Trauma
• Tipo II
– Quirúrgico
• Desplazamientos menos
marcados
– 2 tornillos percutáneos
(media rosca) de anterior a
posterior
• Fuerza de cizallamiento
del cuello es de 1129 N,
– No tolerados por clavos
0.62 o tornillos vía
posterior
Ad
close
neal
to til
is ob
there
Penn
over
redu
Be
cate o
for e
inclu
the s
posit
joint
In
compromise of the skin about the ankle, and prompt
radio
reduction is needed. Any skin slough that leads to
wound infection places the underlying structures at risk
casts
for deep infection.24,66,101
accep
has b
NONOPERATIVE TREATMENT
well
Sa
An immediate closed reduction should be performed in
misa
the emergency department by manipulating the foot into
sensi
full plantar flexion, thereby bringing the head in line with
ditio
the body.5,35,116 The goal of reduction at this point is to
diminish the risk of soft tissue compromise. Reduction of
with
the subtalar joint is then obtained by manipulating the
acter
A heel into either inversion
B
C
or eversion, depending
on
stage
Figure 39-15 Internal fixation of the talus with screws placed anterior to posterior. Screws may be parallel or, especially with
whether
the
subtalar
component
of
the
dislocation
is
of th
comminution of the talar neck (A), may be crossed. When screws must be inserted through the talar head, countersinking is
116 MF, editors: Orthopaedic trauma
critical (B and C). (A, From Sangeorzan BJ: Foot and ankle joint. In Hansen ST Jr, Swiontkowski
and
Dunn
medial
or
lateral
(see
Fig
39-13D).
Pennal
comp
protocols, New York, 1993, Raven, p 351. B and C, From Brunner CF, Weber BG: Special techniques in internal fixation, Berlin,
1982, Springer-Verlag.)
et al35 cautioned against repeated forceful attempts at
Meas
closed reduction. If closed reduction is unsuccessful,
conta
2115
open reduction is required.
rior
If an anatomic closed reduction is obtained and conbut m
firmed with a CT scan, definitive closed treatment may be
conc
attempted. However, an exact reduction of both the talar
the n
neck fracture and the subtalar dislocation is required. The
joint
Tratamiento
• Fracturas Tipo II
– Manejo
postoperatorio con
movilidad de tobillo y
sub-astragalina sin
apoyo. (10 - 12
semanas)
– Apoyo hasta que
haya datos
radiográficos y
clínicos de
Complicaciones
• Fracturas tipo II
– Más común Necrosis
avascular (0-50%) y
Artrosis Subastragalina/Tobillo
(90%)
– Conminución = Peor
Pronostico
a motor vehicle accident, including this open type III talar
(B). The talar body assumed a typical posteromedial location
ach, and the patient underwent open reduction and
G
Tratamiento
Fractures
• Tipo III
– Cuerpo ubicado
– 50% son
expuestas, resto
con piel a tensión
(necrosis)
A
Fractures and Fracture-Dislocations of the Talu
A
B
C
• Posterior y medial
entre fibras del
ligamento
deltoideo
D
E
F
Figure 39-19 A 20-year-old female sustained multiple fractures
neck fracture as seen in the lateral radiograph (A) and photograp
(C and D). The body was reduced through an extensile medial ap
B through two incisions (E-G).
internal fixation
on the overlying skin, which can result in necrosis unless
prompt reduction is instituted.
Tratamiento
• Tipo III –
Conservador
– Poco alentador por:
• Difícil reducción (falta
de soporte
ligamentario)
– No evidencia que
apoye tratarlo de
manera conservador
Tratamiento
Part X ■ Trauma
• Tipo III – Quirúrgico
– Abordaje medial
• Reducción (Maléolo
fx)
Figure 39-20 Osteotomy of the medial
• Maléolo
íntegro
malleolus for treatment
of fractures and
Chevron
Line of osteotomy
Deltoid ligament
dislocations of the talar body.
– Osteotomía
(Chevron)
– Posterior a
reducción se fija de
If the body of
the talus is trapped behind the medial
la misma
manera
malleolus and no space seems to exist for the body, disquetraction
lasis required.
tipoA femoral
II distractor can be placed on
the medial side with one Schanz screw in the tibia and
one in the os calcis. This opens up the space between the
tibia and the os calcis much more efficiently than manual
traction and greatly eases the manipulative reduction of
136
AUTHORS’ PREFERRED METHOD OF TREATMENT
The authors recommend urgent attempted reduction of
these fractures in the emergency department. If the fracture can be reduced by closed means, urgent operative
treatment is not required. If closed reduction cannot be
achieved, the authors recommend urgent operative treatment to relieve pressure on the skin and neurovascular
Tratamiento
• Postoperatorio
– Unión ósea en 5-8
meses
• NAV 75-100%
• No unión 30%
• Mal unión 30%
– Artrosis Pos traumática
• 70% Tobillo
• 30% Sub-astragalina
– Intervenciones
subsecuentes
Tratamiento
• Tipo IV
– Expuestas
– Riesgo de:
• Necrosis de cabeza y cuerpo
• Infección
– 71% de falla en
procedimiento quirúrgicos
• Artrosis
– Grob, Kleiger, Boyd,
Knight, Pnnal, Canale,
Kelly, Szyszkowitz
• Fusión sub-talar primaria
Luxación Total del
Astrágalo
of injury is forced supination or pronation, usually
they manifest wit
coupled
with
plantar
flexion,
causing
a
medial
or
lateral
lateral
coupled with plantar flexion, causing a medial or lateral
lateralside
sideseconda
second
often referred
to asdislocation,
a pantalar dislocation.
The with
mechanism
When
these injuries
areagainst
closed, with
no
subtalar
combined
a
force
strong
enough
talus
thethe
sofs
subtalar dislocation, combined with
a
force
strong
enough
talus
against
14,74,88,125
of injurytoisdislocate
forced supination
or
pronation,
usually
they
manifest
with
tense
anterior
skin,
u
ated
with
fractures
thethe
ankle
(Fig.
39-24).
ated
with
fractureo
to dislocate
ankle
(Fig.
39-24).14,74,88,125
coupled with plantar flexion, causing a medial or lateral
subtalar dislocation, combined with a force strong enough
to dislocate the ankle (Fig. 39-24).14,74,88,125
lateral side secondary to the pressure of t
talus against the soft tissue envelope.24 Ma
ated with fractures of at least some portio
Luxación Total de Astrágalo
• También conocida
como:
– Luxación pantalar
A
• Afección completa
de articulaciones:
– Tobillo
– Sub-astragalina
– Astrágaloescafoidea
B1
B1B1
AA
Luxación Total de Astrágalo
• Rara
– Cerradas
• Tensión en piel
– Abiertas
• Variante de
expulsión completa
del cuerpo sin
fracturas asociadas
• Mecanismo
– Supinación/
Pronación forzada +
Flexión plantar
Luxación Total de Astrágalo
• Acompañadas de Fx
maleolares
• Dilema
– ¿Reimplantación,
Fusión, Talectomía?
Reimplantación
• Diferentes autores:
– Sneed, Coltart,
Mindell, Pennal,
Ritsema, Hiraizumi,
Marsh, Burston,
Brewster, Maffulli,
Palomo-Traver.
– Resultados variables
– Reimplantar si hay
tejido blando
adherido al
astrágalo.
Resección y Fusión
• Stimpson, Detenbeck,
Kelly, Jaffe, Hiraizumi
• Resección en casos de:
– Contaminación
– Separación completa de
tejidos blandos +
• Realizar Fusión tibiacalcanea.
• 89% osteomielitis
Luxación Sub-total del
Astrágalo (Subastragalina
o Peri-Astragalina)
Fr
ac
tu
re
s
A
Fi
ta gur
lo e
na 3
vic 9-2
ul 6
ar
an A, L
d
a
su ter
bt al
al
ar rad
jo iog
in
ts. rap
C, h o
an
Luxación Sub-total del
Astrágalo (Subastragalina o
Peri-Astragalina)
Fractures and Fracture-Disloc
• Alta y baja energía
(Basquetbol)
Fr
ac
tu
r
A
Fi
ta gur Fractures and Fracture-Dislocations of the Talus ■ Chapter 39
lo e
na 3
vic 9-2
ul 6
ar
A
B
C
a n A, L
d
at
su erFigure 39-26 A, Lateral radiograph of a closed peritalar dislocation. B, Postreduction l
bt al
and subtalar joints. C, Postreduction computed tomography scan that show
al talonavicular
ar rad
i
jo og
in
ts. rap
C, h o
Po f a
str cl
ed os
B
uc ed
Fi
t
p
io
fra gur A
n erit
co al
ct e 3
m ar
ur
pu d
es 9-2
te islo
of 7
d
t
B
fra
to cBati
he o
A
C
d
m on
c
y
t
in tu
o
al
. Btype I: coronal (A) and sagittal (B). C, S
Figure 39-27 Body fractures of the talus.gShear
ar fra
B
C talar body. D, Crush fractureraof
, Ptalar body. (Copyright Jesse C. DeLee
arA juri res,
fractures of the
bo ctu
phthe
t
e
os
icu s, fra
dy re
y
poFigure
C
tr
s
s
u
39-26
A,
Lateral
radiograph
of
a
closed
peritalar
dislocation.
B,
Postreduction
lateral
demonstrating
reduction
of
c
.
l
c
ste ar su tu
D, of
antheedu
m talonavicular
and
subtalar
joints.
C,
Postreduction
computed
tomography
scan
that
shows
a
small
fracture
of
the
talar
neck.
t
r
all es
Cr th
th cti
b en rio io
• Dirección del pie y
calcáneo ---Medial
• Cabeza astragalina
--- Dorsolateral
Luxación Sub-total del
Astrágalo (Subastragalina o
Peri-Astragalina)
• Reducción cerrada +
Bota sin apoyo (4-6
Semanas)
Fractures and Fractu
A
Fi
ta gur
lo e
na 3
vic 9-2
ul 6
ar
an A, L
d
a
su ter
bt al
al
ar rad
jo iog
in
ts. rap
C, h o
Po f a
str cl
ed os
B
uc e d
tio pe
n
r
A
co ital
m a
• Alta energía (47%)
– Reducción abierta x
obstrucción de tejidos
blandos)
Fi
fra gur A
ct e 3
u
B
Fracturas del
Cuerpo del
Astrágalo
Introducción
• Son 13-20% de las
fracturas astragalinas
• Se acompañan de
– Fracturas del cuello o
maléolos
– Luxación
– Expuestas
• Lesión intra-articulares
verdaderas
– Incongruencia art.
Astragalo-tibial (Bloqueo en
dorsi-flexión)
Mecanismo de Lesión
• Compresión axial con alta
energía
(Caídas de altura o Accidentes
vehiculares)
• Lesión articular
Tibio-Astragalina + Sub-Astragalina
– Peor pronóstico
– 38 - 50% Necrosis
Avascular
– 65 - 100% Artritis Posttraumática
Clasificación
• Se dividen en:
– Fracturas por cizallamiento
• I – Trazo coronal o sagital
– IA - ID
• II – Trazo horizontal
– IIA – No desplazadas
– IIB – Desplazadas (>3mm)
– Fracturas “Crush”
Tratamiento
• Objetivo
– Restaurar congruencia
articular
– Prevenir infección
– Necrosis avascular
• Conservador
– Fracturas no
desplazadas
– Bota corta sin apoyo por
6-8 semanas
Type IA
Tratamiento
Quirúrgico
Type IB
A
• Restaurar articulaciones
(T-A y S-A) para
movilización temprana
Type IC
Type ID
Figure 39-28 Shearing injuries to the talar body. This
classification is for coronal and sagittal fractures only.
(Copyright Jesse C. DeLee, MD.)
• Fijación temprana no
influye en resultado
Nonoperative Treatment
Nonoperative treatment is reserved for nondisplaced fractures of the talar body.13,116 These patients are treated with
a below-knee non–weight-bearing cast for 6 to 8 weeks
or until there are clinical and radiographic signs of fracture healing.
For fractures with dislocation of the talar body (Fig.
39-29), an attempt at closed reduction is made in the
emergency department, but failure to achieve closed
reduction requires urgent open reduction to relieve soft
tissue and neurovascular compromise.
B
• Trazo simple (1 abordaje)
• Trazo complejo (2
abordajes)
Surgical Treatment
The majority of talar body fractures are displaced and will
require operative treatment to restore anatomic congruity
at the tibiotalar and subtalar joints and to allow early
mobilization of the joints (Figs. 39-29 to 39-33).* Open
talar body fractures are treated with appropriate antibiotics and surgical debridement before fixation.
The surgical approach is carefully planned based on
C
Figure 39-29 A, Lateral radiograph depicting a
portion of the talar dome rotated and facing anteriorly.
B, Anteroposterior view showing the sagittal fracture line
through the talar dome. C, Postoperative lateral view with
lateral-to-medial screw and bioabsorbable fixation reducing
the sagittal body fracture.
The anteromedial and anterolateral approaches can be
planned to incorporate fractures or osteotomies of the
Tratamiento
Quirúrgico
• Alta conminución sin
posibilidad de
reconstrucción
– Astragalectomía / Fusión
Tibio-Calcanea
• Post-Operatorio
– Férula por 2 semanas
– No apoyo por 8-12
semanas
– Insistir en rangos de
movilidad
Part X ■ Trauma
A
B
D
G
C
E
H
F
I
Figure 39-31 Open talar body fracture dislocation with associated pilon and medial malleolar fractures in a 33-year-old female
nurse. A, Transverse medial open wound. Lateral (B) and anteroposterior (AP) (C) views of the fracture. D, Provisionally reduced
talus with a malreduced pilon fracture. E, Accurate pilon reduction after working through the talus fracture. AP (F) and lateral
(G) postoperative views depicting fracture reduction of the talus, pilon, and medial malleolus. AP (H) and lateral (I) views 9
months after surgery, showing increased talar dome density. Patient remains fully ambulatory without aids but still experiences
pain with daily use.
arthritis is an expected result in displaced talar body fractures despite accurate reduction with stable fixation.
Authors’ Preferred Method of Treatment
will often require a concomitant medial or lateral malleolar osteotomy as described above. A distractor is almost
always used to improve visualization.
After exposure of the fracture, fragments are manipulated
with K-wires as joysticks. Anatomic reduction is provision-
concomitant fracture of the anterior colliculus of the medial malleolus was reduced through a separate anteromedial incision
and stabilized with a single 2.7-mm lag screw (D).
A
D
B
E
C
F
G
Figure 39-33 A 37-year-old male jumped off a roof, sustaining bilateral talar body fractures. Injury radiographs (A) and
computed tomography scan (B) demonstrate a talar body fracture with displacement and depression of the articular surface.
The fracture was exposed through a fibular osteotomy. After exposure of the distal fibula, the anterior tibiofibular ligament
(C, indicated by the elevator) was divided. An oblique osteotomy of the tibula was performed above the level of the plafond
(D), to allow external rotation of the distal fibula and exposure of the fracture. A distractor was applied from the tibia to the
talar neck to further improve exposure (E). The talar body was anatomically reduced and stabilized with 2.0-mm screws, and the
fibular osteotomy was reduced and fixed (F and G). The syndesmotic ligaments were repaired and the syndesmosis was
stabilized with a tricortical 3.5-mm screw.
Postoperatively, the patient is immobilized in a short
leg splint for 2 weeks to allow wound healing. Patients
posttraumatic arthritis of the subtalar joint, the ankle
joint, or both.
Complicaciones Asociadas
•
Necrosis de piel
•
Osteomielitis
•
Necrosis avascular del astrágalo (8
semanas inicia) – Signo Hawkins)
•
Retraso en la unión (No evidencia de
unión x 6 meses)
•
No-Unión (2.5%)
•
Mala-Unión (Mala reducción- Deformidad
en Varo)
•
Artritis Post-traumática de tobillo y Subastragalina
Fracturas del Proceso
Posterior
lar facets on the neck, formed by cont
strong dorsiflexion of the foot at the a
squatting facets.
Anatomía
head
Proceso Posterior
• Compuesto de tubérculos:
an
neck
– Postero-lateral
(+ Prominente, No-articular)
superior
articular surface
medial
malleolar
surface
lateral malleolar
surface
lateral process
– Postero-medial
trochlea
posterior subtalar
facet
posterior process
• Separados por surco del
tendón flexor largo del 1er
ortejo
groove for
flexor hallucis longus
Figure 13.6 Right talus. Left: dorsal (or superior) view; right: plantar (or inferior) view
276
CHAPTER 13 Foot: Tarsals, Metatarsals, and Phalanges
Anatomía
• Estructuras con inserción
en tubérculo Posterolateral:
– Ligamento Astrágaloperoneo Posterior
– Componente astragalino
del ligamento PeroneoAstrágalo-Calcáneo
Radiologic
E, Clinical photograph
shows Evaluation
fracture of the posterior process
(arrow) with injury of the posterior facet of the talus.
Anatomía
Os Trigonum
D
C
E
• Hueso accesorio asociado
al tubérculo Posterolateral
Figure 39-37 Posterior process fracture (arrows).
Anteroposterior (A) and lateral (B) radiographs, and coronal
(C) and transverse (D) computed tomography scans,
demonstrate true extent of injury into the subtalar joint.
E, Clinical photograph shows fracture of the posterior process
(arrow) with injury of the posterior facet of the talus.
• Presente en 50% de los
pies
os trigo
num th
A lateral radiographic view of the ankle best demonstrat
fracture
the lateral tubercle of the posterior process of th
netium
talus and the os trigonum. To differentiate from
of the
normal smooth-surfaced os trigonum, the surgeon shou
the fibr
remember that in an acute fracture of the posterior tal
process, the fracture surfaces should be rough and irreg
lar (Fig. 39-41).
Because the os trigonum is reported to be unilateral
more than two thirds of cases, however, compariso
radiographs may not be of value.100 Paulos et al115 sugge
the use of a special 30-degree subtalar oblique view
help distinguish between an acute fracture and an
trigonum. They found that a posterior process fracture
generally larger and extends farther into the body of th
talus.
Bone scans can be used to distinguish among a norm
os trigonum, a traumatic separation of a normal os trig
num through its fibrous attachment to the talus, and
fractured posterior process of the talus.115 A positive tec
netium bone scan is present in all patients with fractu
of the posterior process and in those with disruption
the fibrous attachment of the os trigonum to the talu
A
B
Figure 39-38 Os trigonum varies greatly in size. A, Small oval structure w
more of the subtalar joint. (Copyright Jesse C. DeLee, MD.)
• Varía en tamaño y puede
estar fusionado al
astrágalo/calcáneo
– Proceso trigonal
A
B
• Cuenta con 3 superficies:
Figure 39-38 Os trigonum varies greatly in size. A, Small oval structure with smooth surfaces. B, Large structure involving
more of the subtalar joint. (Copyright Jesse C. DeLee, MD.)
– Anterior, Inferior y
213
Fracturas del Tubérculo
Postero-Lateral
Mecanismo de Lesión
• Flexión plantar forzada
del pie (+ Común)
– Vista en bailarinas de
Ballet y Soccer
• Dorsi-flexión excesiva
del tobillo
– Tensión del ligamento
astrágalo-peroneo Avulsión
Fracturas del Tubérculo
Postero-Lateral
Evaluación Clínica
• Dolor y edema en región
posterior del tobillo
– Incrementadas al correr,
brincar, bajar escaleras,
hacer sentadilla.
• Dolor al movilizar tendón
flexor del 1er Ortejo
(Surco Adyacente)
Fracturas del Tubérculo
Postero-Lateral
• Palpación
– Dolor anterior al
tendón de Aquiles y
Posterior al Astrágalo
– Crepitación al
realizar flexión
plantar
• Conjunto de estos
hallazgos =
Síndrome del Os
Trigonum
Fracturas del Tubérculo
Postero-Lateral
• Diagnostico
diferencial
– Fractura del proceso
lateral
– Fractura del Os
trigonum fusionado
– Ruptura de la
Sincondrosis del Os
trigonum con el cuerpo
Fracturas del Tubérculo
Postero-Lateral
Evaluación Radiológica
• Radiografía lateral
– Demuestra tubérculo lateral de
proceso posterior del astrágalo
y Os Trigonum
• Radiografía con 30º de
oblicuidad Sub-astragalina
– Fractura aguda vs Os Trigonum
• TAC
– Información adicional
A
A
B
D
B
B
Clinically, tenderne
tendon and posterior t
heard or felt with plant
be seen with motion o
of the flexor hallucis lo
to the injured lateral tu
D
This syndrome of c
15,66,
trigonum syndrome.
Fractures and Fracture-Dislocations
of the T
diagnosis, however, n
lateral process, fracture
of the
synchoa
Clinically,ruption
tenderness
is present
body.
tendon and talar
posterior
to the talus, an
C
E plantar flexion of t
heard or felt with
seen process
with fracture
motion(arrows).
of the great t
Figure 39-37 be
Posterior
Radiologic
Evaluat
Anteroposteriorof(A)
andflexor
lateralhallucis
(B) radiographs,
andtendon
coronal
the
longus
(C) and transverse (D) computed tomography scans,
to the injured
tubercle
of thev
A lateral
lateral
demonstrate true extent of injury
into the radiographic
subtalar joint.
Thisshows
syndrome
findin
E, Clinical photograph
fracture
ofof
theclinical
posterior
processo
the lateral
tubercle
15,66,95,167
(arrow) with injury
of the posterior
of the talus.
trigonum
syndrome.
talusfacetand
the The
os mo
tri
diagnosis, however,
necessarily inc
normal smooth-surface
lateral process,
fracture that
of a in
fused
remember
an ao
ruption of the synchondrosis of th
Tratamiento
• Fracturas agudas =
Conservador
– Bota corta de yeso con
pie en 15º de equino
(4-6 semanas)
• Evidencia radiográfica
de unión =
Rehabilitación
• Si continua dolor 6
meses posterior (2/3 de
Px) = Escisión
quirúrgica
Fracturas de Tubérculo PosteroMedial
• Poco comunes
• También llamadas de
Cedell
(Dorsi-flexión +
Pronación)
• Masa dolorosa, firme
detrás del maléolo
medial con perdida del
contorno posteromedial.
Fracturas de Tubérculo PosteroMedial
• Radiografía
– Fragmento de
tamaño variable
situado medial y
dorsal al astrágalo
• Tratamiento
– Conservador vs
Escisión del
fragmento
Fracturas del Proceso
Lateral
Incidencia
• Mal diagnosticadas
como esguinces de
tobillo
• Son el 24% de las
fracturas del cuerpo
del astrágalo
13.1.1 Talus (Figures 13.6–13.7, 13.17
Anatomía
The talus is called the astragalus in other anim
situated between the tibia and fibula superiorly
to this bone. It rests atop the calcaneus and arti
lower member of the talocrural joint. Talar va
a. The head is the rounded, convex, distal art
of the navicular.
• Comprende la
región más lateral
del cuerpo del
astrágalo
b. The body is the squarish bulk of the bone
c. The trochlea is the saddle-shaped articula
and medial malleolar surfaces (or facets
respectively.
d. The neck connects the head of the talus to
lar facets on the neck, formed by contact w
strong dorsiflexion of the foot at the ankle
squatting facets.
face
head
• Forma:
– La pared posterior
del seno del tarso
– La esquina anterolateral de la faceta
posterior del
astrágalo
anterior
fa
neck
superior
articular surface
medial
malleolar
surface
lateral malleolar
surface
lateral process
trochlea
posterior subtalar
facet
posterior process
groove for
flexor hallucis longus
ne
Anatomía
• Involucran 2 articulaciones
– Astrágalo-peronea
– Calcáneo-astragalina
(Posterior)
• Inserciones
– Ligamento AstrágaloCalcaneo lateral
– Ligamento Astrágaloperoneo anterior
– Ligamento Astrágaloperoneo posterior
Mecanismo de Lesión
• Carga axial +
Dorsiflexión +
Eversión/Rotación
Externa
• “Snowboarder
Fracture”
Evaluación Clínica
• Síntomas parecidos a un
esguince de tobillo
• Dolor en cara lateral de
tobillo distal al maléolo
lateral
• Luxación de tendones
peroneos se ha descrito,
se deben explorar
Part
PartX X■■Trauma
Trauma
Evaluación Radiográfica
• Radiografías
– AP, Lateral y Mortaja
– Brodén (AP con tobillo
neutral y pierna con
rotación interna 20º )
• TAC
AA
BB
Figure
39-46 A A27-year-old
27-year-oldmale
malepresented
presented with
with late
late
39-46
– Ayuda aFigure
clarificar
and coronal computed tomography scan (B) demonstra
tamaño,and coronal computed tomography scan (B) demonstra
reduction
and internal fixation through a lateral appro
reduction
desplazamiento
y and internal fixation through a lateral appro
2.0-mm
screws(D).
(D).
2.0-mm
screws
conminución
B
withhigh-energy
high-energyinjuries
injuriesororthose
those managed
managed non
non
with
C
D
118,159
Nonunion,while
whilerare
rareafter
afterORIF,
ORIF, is
is freq
freq
tively.
118,159
Nonunion,
tively.
percent
of patien
lateral process talus fractures for approximately
3.5 years.
ondary
operative
Figure
39-44 90%
Anteroposterior
view
of the
ankle
with
The authors
reported
excellent and
good
clinical
legan
internally
20 degrees
suggests
a large
impingement.
Ap
results and
average rotated
American
Orthopaedic
Foot
and fractu
the lateral
process
(arrow).
(Copyright
Jesse
DeLee,
M
unable
return
Ankle Society
(AOFAS)
Hindfoot
Score
of 93
out
ofC.to
100.
activity.
The best result scores, hindfoot motion, and
least pain
were noted in patients with large fracture fragments
(type
Results
are affe
I) that were anatomically reduced and rigidly
Fifty
sis fixed.
and by
the dev
percent of patients treated nonoperatively fragment.
required secSubtalar
• Hawkins
(3 Tipos)
Figure 39-44
Anteroposterior view of the ankle with the
ondary operative debridement because of talus
nonunion
or occ
fractures
leg
internally
rotated
20
degrees
suggests
a
large
fracture
of
– Tipo I
impingement. Approximately 20% of patients were
the lateral process (arrow). (Copyright Jesse C. DeLee, MD.)
patients and is m
• Fractura simple, fragmento
unable to return to their preinjury level of athletic
grande
activity.
ResultsFigure
are affected
the presenceofoflateral
subtalar
arthro39-45byClassification
process
talus frac
sis and byA,the
development
of
nonunion
of
the
fracture
Baker JF, Liu DF, Stephens MM: The management and
– Tipo II
fragment. 2010.
Subtalar arthrosis associated with lateral process
oposterior view of the ankle with the
• Conminuta que involucra
talus fractures occurs in approximately 15% to 25% of
20 degrees suggests a large fracture of
superficie
articular
y and is more frequently seen in those patients
rrow). (Copyright Jesse C. DeLee, MD.)
patients
Clasificación
proceso lateral
– Tipo
III 39-45
Figure
Classification of lateral process talus fractures as described by Hawkins
Baker JF, Liu
Stephens MM: The management and outcome of lateral process ta
•A,Fractura
enDF,
“Chip”
•2010.
Porción antero-inferior
(solo afecta articulación
sub-astragalina)
fication of lateral process talus fractures as described by Hawkins. (Modified with permission from Perera
ephens MM: The management and outcome of lateral process talus fractures. Foot Ankle Surg 16:15-20,
Tratamiento
• Basado en:
– Tamaño del fragmento
(Grande – RA + Fijación)
– Conminución (Escisión)
– Desplazamiento
• Fragmentos pequeños /
mínimamente desplazados
– Bota de yeso sin apoyo x 4-6
semanas
Procedimientos de
Salvamento
Secuelas
• Tres problemas:
Dome
DomeDome
collapse
collapse
collapse
A
A A
B
B B
– Perdida ósea
• Colapso y deformidad
• Traumática, sepsis o
necrosis avascular
Figure
39-49
The patient
had
a comminuted
Figure
39-49
Thehad
patient
had
a comminuted
Figure
39-49
The
patient
a comminuted
fracture
that
was
treated
a in
closed
talar
fracture
was
a closed
talartalar
fracture
that
was that
treated
intreated
a in
closed
manner
with
strict
non–weight
bearing.
manner
with
strict
non–weight
bearing.
manner
with
strict
non–weight
bearing.
A, Approximately
5 months
after
injury,
the the
A, Approximately
5after
months
after
injury,
A, Approximately
5 months
injury,
the
patient
developed
and
radiographs
patient
developed
and
radiographs
patient
developed
pain,pain,
andpain,
radiographs
revealed
avascular
necrosis
and
collapse
revealed
avascular
necrosis
and
collapse
revealed
avascular
necrosis
and
collapse
(arrows),
despite
non–weight
bearing.
(arrows),
despite
non–weight
bearing.
(arrows),
despite
non–weight
bearing.
B, Magnetic
resonance
image
reveals
totaltotal
B, Magnetic
resonance
image
reveals
B, Magnetic
resonance
image
reveals
total
involvement
of talus.
the
C, Talectomy
involvement
of talus.
the
talus.
C, Talectomy
involvement
of the
C, Talectomy
was was was
performed,
verifying
destruction
of talus.
the
performed,
verifying
destruction
of talus.
the talus.
performed,
verifying
destruction
of the
D, Radiographs
1 year
later.
E, Clinical
D, Radiographs
1 year
later.
E, Clinical
D, Radiographs
1 year
later.
E, Clinical
examination
1 year
later.
Patient
has returned
examination
1 year
later.
Patient
has returned
examination
1 year
later.
Patient
has
returned
to work
as
a as
mechanical
engineer.
to awork
a mechanical
engineer.
to work
as
mechanical
engineer.
– Mal unión (Mala reducción)
– Artritis severa de
articulaciones aledañas al
astrágalo
C C C
E
D
E E
D D
Artrodesis
• Identificar
articulaciones
afectadas (Deformidad)
– Tobillo
– Sub-astragalina
– Astrágalo-escafoidea
• A valorar
– Infección ¿?
– Piel en buenas
condiciones
– Procedimiento brindara
extremidad funcional
Artrodesis de Tobillo
• Se recomienda uso
de tornillos con
combinación de
placas.
• NO se recomienda
uso de clavo
retrogrado
– Involucra articulación
sub-astragalina
Astragalectomía
• Traumática o electiva
(+ Artrodesis de Blair 1608)
• Subtotal
– Ausencia de domo o
cuerpo
• Total
– Astrágalo entero removido
Astragalectomía
• Blair
– 71% Buenos Resultados
– 43% No-Unión
– 28% Pseudoartrosis
– Colapso a largo plazo +
modificación de calzado
– Procedimiento de
salvamento, no de
primera opción
Reemplazo Prostético
Astragalino
• Información limitada
• Harnroongroj et al
– 16 pacientes tratados
– Seguimiento a los 9.5 años
– Resultados satisfactorios
Fusión Tibio-Calcanea
• Utilizado cuando las lesiones
afectan articulación
subastragalina.
• Se puede realizar con:
–
–
–
–
–
Tornillos (6.5),
Placas
Clavo intramedular,
Fijación externa
Injertos vascularizados de
perone.
• Poco dolor pero
funcionalidad limitada.
Placas de Fusión
• Placas anteriores (Sanders et al)
– 100% tasa de fusión con
osteotomías y resección
cartilaginosa
– Poca satisfacción por rigidez y
limitación de actividades
– Promedio de 3 hospitalizaciones
para procedimientos (20-107
días intrahospitalarios)
– Gastos de aproximadamente
$62,174 dlls por paciente
– ¿Procedimiento de Salvamento
vs Amputación?
Otras opciones
• Fijación Externa
– Resultados variables
• Estabilización con clavo intramedular
– Clavo retrogrado supracondileo femoral.
– Únicamente rimado sin resección de
cartílago lleva a no-unión
Descargar