Radiographic Positioning & Procedures I - Lower Extremities PDF

Summary

This document describes radiographic positioning and procedures for lower extremities, focusing on sesamoids. It details various projections and methods.

Full Transcript

RADIOGRAPHIC POSITIONING AND RADIOLOGIC PROCEDURES I

Lower Extremities

Sesamoids

POSITION (OF PATIENT & FILM (SIZE & REFERENCE STRUCTURE EVALUATION
PROJECTION CENTRAL RAY
ORIENTATION) POINT SHOWN CRITERIA
PART)
Lewis Method 8 x 10 inches Lewis Method Lewis Method Lewis Method
Tangential Projection ⤷Patient in prone position. (18 x 24 cm) ❖Perpendicular and ❖ Shows a ⤷ Sesamoids free of
Lewis and Holly Methods Affected ankle elevated on crosswise for tangential to the 1st tangential any portion of the 1st
sandbags for stability and multiple metatarsophalangeal projection of the metatarsal -
folded towel under the exposures on 1 metatarsal head in Metatarsal heads
knee. IR. profile and
⤷Rest the great toe on the sesamoids.
table in dorsiflexion and
adjust it to place the ball of
the foot perpendicular to
the horizontal. Center the IR
Lewis Method to the 2nd metatarsal.
Holly Method
⤷Patient seated on the table
with the medial border of
the foot adjusted in vertical
position and plantar surface
at an angle of 75 degrees
with the plane of the IR.
⤷Patient holds toes in flexed
position with strips of gauze
Holly Method bandage.
⤷The central ray is directed
perpendicular to the head
of the 1st metatarsal bone.

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 FOOT
AP OR AP AXIAL PROJECTION ❖Patient in supine. Flex the 10 x 12 inch Directed one of two ❖AP ❖ No rotation of the
knee and place the foot on (24 x 30 cm) ways: (dorsoplantar) foot
top of the IR. lengthwise 1. 10 degrees toward projection of the ❖Equal amount of
❖Position the IR under the the heel to the base tarsal anterior to space between the
of the third the talus,
patients foot center to the adjacent midshafts of
metatarsals, or metatarsals, and
base of the 3rd metatarsal the second through
2. perpendicular to phalanges.
and adjust it so that the fourth metatarsals
the IR and toward ❖ used for
long axis is parallel to the ❖ Overlap of the
the base of the third
long axis of the foot. localizing foreign second through fifth
metatarsal.
bodies, metatarsal bases
Radiographs may be obtained by
❖determining the ❖ Visualization of
directing the central ray perpendicular to
the plane of the IR or by angling the location of the phalanges and
central ray 10 degrees posteriorly. fragments in tarsals distal to the
fractures of the talus, as well as the
metatarsals and metatarsals.
the anterior
tarsals, and.

2
 ❖performing
general surveys of
the bones of the
foot.
AP OBLIQUE PROJECTION ❖Patient in supine. Flex the 10 x 12 inch ❖Perpendicular to ❖the cuboid and ❖Third through fifth
Medial rotation knee of the affected side (24 x 30 cm) the base of the 3rd the calcaneus; metatarsal bases free
enough to have the plantar lengthwise metatarsal ❖ the cuboid and of superimposition
surface of the foot rest the fourth and fifth ❖Lateral tarsals with
firmly on the table. metatarsals; Iess superimposition
❖Place IR under the foot ❖ the cuboid and than in the AP
parallel with its long axis the lateral projection
center to midline of the cuneiform; and ❖ Lateral
foot at the level of the base ❖ the talus and tarsometatarsal and
of the 3rd metatarsal. intertarsal.
the navicular bone.
❖Rotate the leg medially ❖ Sinus tarsi
❖The cuboid is
until the plantar surface of ❖ Tuberosity of the
shown in profile.
the foot forms an angle of
❖The sinus tarsi is fifth metatarsal
30 degrees to the plane of
also well ❖ Bases of the first
the IR Increasing the angle
of the foot more than 30 demonstrated. and second
degrees tends the lateral metatarsal
cuneiform to be thrown ❖ Equal amount of
over the other cuneiforms. space between the
shafts of the second
through fifth
metatarsals.
AP OBLIQUE PROJECTION ❖Patient in supine. Flex the 10 x 12 inch ❖Perpendicular to ❖Interspaces ❖ Separate first and
Lateral rotation knee of the affected side (24 x 30 cm) the base of the third between the first second metatarsal
enough to have the plantar lengthwise metatarsal and second bases
surface of the foot rest metatarsals and ❖No
firmly on the table. Position between the superimposition of
of part. medial and the medial and
❖Place IR under the foot intermediate intermediate
parallel with its long axis cuneiforms. cuneiforms
center to midline of the foot ❖Navicular bone
at the level of the base of more clearly
the 3rd metatarsal.

3
 ❖Rotate the leg laterally demonstrated than in
until the plantar surface of the medial rotation
the foot forms an angle of ❖ Sufficient density
30 degrees to the plane of to demonstrate the
the IR phalanges,
metatarsals, and
tarsals.
PA Oblique Projection Grashey Method ❖Patient in prone. Elevate IR 24 x 30 cm ❖Perpendicular to ❖Shows bones of Heel medially
Medial or Lateral Rotation the affected foot on lenghtwise the base of the 3rd the foot and the rotated 30 degrees
sandbags and folded towel metatarsal. interspaces of the ⤷First and second
under the knee. proximal ends of metatarsal bases free
❖Patient foot placed its the metatarsals. of superimposition
⤷Medial cuneiform
dorsal portion in contact
projected without
with IR parallel with its long
superimposition
axis center to the base of
⤷Navicular bone seen
the 3rd metatarsal.
in profile.
❖Rotate the heel medially
Heel laterally rotated
approximately 30 degrees to 20 degrees
demonstrate interspaces ⤷Third thru fifth
between the metatarsal. 1st metatarsal bases free
and 2nd. of superimposition.
❖ Rotate the heel laterally ⤷Tuberosity of the
20 degrees to demonstrate fifth metatarsal and
interspaces between 2nd & cuboid.
3rd, 3rd & 4th, 4th & 5th
metatarsal.

4
 LATERAL PROJECTION ❖Patient is lying on the 10 x 12 inch ❖Perpendicular to ❖Perpendicular to ❖Metatarsals nearly
Mediolateral table turning towards the (24 x 30 cm) the base of the third the base of the superimposed
affected side until the leg lengthwise metatarsal third metatarsal. ❖ Distal leg
and foot are lateral with ❖Fibula overlapping
opposite leg behind the
the posterior portion
patient.
of the tibia
❖ Elevate the patients knee
❖ Tibiotalar joint
to place the patella
❖Sufficient density
perpendicular to horizontal
with sandbag support under to demonstrate the
the knee, then center the superimposed tarsals
mid area of the foot with and metatarsals
The lateral (mediolateral) projection is the long axis parallel with
routinely used in most radiology the long axis of the IR.
departments because it is a comfortable Dorsiflex the foot to form
position for the patient to assume. 90 degree angle with lower
leg.
LATERAL PROJECTION ❖Patient is supine then 10 x 12 inch ❖Perpendicular to ❖Shows a true ❖Metatarsals
Lateromedial patient turn unaffected side (24 x 30 cm) the base of the third lateromedial usually more
until affected leg and foot lengthwise metatarsal projection of the superimposed than
placed. foot, ankle joint, in the medio-lateral
❖Elevate the patients knee and distal ends of image, depending on
to place the patella the tibia and the transverse arch
perpendicular to horizontal, fibula. of the foot
then center the IR to mid ❖ Distal leg
area of the foot with the ❖Fibula overlapping
long axis parallel with the the posterior portion
long axis of the IR. of the tibia
Whenever possible, lateral projections of ❖ Tibiotalar joint
the foot should be made with the ❖Sufficient density
medial side in contact with the IR. to demonstrate the
superimposed tarsals
and metatarsals.

5
Lateral Projection Weight Bearing ❖ Patient in upright 24 x 30 cm ❖Perpendicular to a ❖Shows a ❖Superimposed
Method (Standing) preferably in a low riser with lengthwise point just above the lateromedial plantar surface of the
for Longitudinal Arch IR groove. If not available base of the 3rd projection of the metatarsal heads
use blocks to elevate the metatarsal. bones of the foot ❖Entire foot and
foot to the level of x-ray with weight distal leg
tube. bearing. This ❖Fibula overlapping
❖ Place IR vertically on the projection is also
the posterior portion
IR groove of the stool or used to
of the tibia
between blocks. Patient demonstrate the
❖ Sufficient density
stand in natural position one structur.al status of
longitudinal arch. to visualize the
foot on each side of the IR
superimposed tarsals
with weight of body equally
and metatarsals.
distributed on the feet
AP Axial Projection Weight Bearing ❖Patient in standing upright 24 x 30 cm ❖Angled 10 degrees ❖Demonstrate a ❖Both feet centered
Method (Standing) position. crosswise for towards the heel is weight bearing AP on the image
❖Place IR on the floor and both feet on optimal. A minimum axial projection of ❖Phalanges,
one IR of 15 degrees is both feet
have the patient stand on metatarsals, and
the IR with the feet usually necessary to permitting an distal tarsals.
centered on each side, have enough room accurate ❖Correct right and
weight of the body equally to position the tube. evaluation and
left marker
distributed on the feet. CR positioned comparison of the
placement and a
Right and left markers must between the feet at tarsals and
weight bearing
be placed on the IR. the level of the base metatarsals.
marker
of the 3rd
❖Correct exposure
metatarsal.
technique to visualize
all the components
AP AXIAL PROJECTION WEIGHT- ❖Patient in upright standing 10 x 12 inch 1st Exposure ❖Shows a weight- ❖All tarsals
BEARING COMPOSITE METHOD – position standing on a (24 x 30 cm) ⤷Tube in front of the bearing axial ❖ Shadow of the leg
Standing comfortable height in a low lengthwise patient adjusted for projection of all not overlapping the
stool or the floor. a posterior bones of the foot. tarsals
❖Adjust the IR under the angulation of 15 The full outline of ❖ Foot not rotated
degrees, with the foot is
foot and center its midline ❖ Tarsals,
central ray to the projected free of
to long axis of the foot. To
base of the third the leg. metatarsals and toes
prevent superimposition of
metatarsal with the with similar densities
the leg shadow, on that of
opposite foot
the ankle joint, patient place

6
 the opposite foot backward backward. Patient to
for exposure of the forefoot carefully maintain
and one foot forward for the the position of the
exposure of the hind foot or affected foot;
calcaneus. 2nd exposure.
⤷Place the foot one
step forward Move
the tube behind the
patient, adjust it for
Composite AP Axial, Posterior an anterior
angulation of 15 degrees angulation of 25
degrees, and direct
the central ray to
the to the posterior
surface of the ankle.
⤷The central ray
emerges on the
plantar surface at
the level of the
lateral malleolus.
Composite AP Axial, Anterior angulation
of 25 degrees

Congenital Clubfoot Three deviations of the None None None
normal alignment of the
Clubfoot is called Talipes Equinovarus foot
1. Plantar flexion and
inversion of the calcaneus
(equinus).
2. Medial displacement of
the forefoot (adduction). 3.
Elevation of the medial
border of the foot
(supination).

7
 Kite Method
❖with AP and Lateral
projections is used to
demonstrate the anatomy
of the foot and the bones or
ossification centers of the
tarsals and their relation to
one another.
AP Projection ❖Infant in a supine position 8 x 10 inches ❖Perpendicular to None None
with hips and knees flexed (18 x 24 cm) the tarsals, midway
to permit the foot to rest between the tarsal
flat on the IR. Elevate the areas for a bilateral
body on a firm pillow to projection.
knee height to simplify both ❖An approximately
gonad shielding and leg 15-degree posterior
adjustment. angle of the central
❖Rest the feet flat on the IR is generally required
Demonstrate the degree of adduction of with the ankles extended to be perpendicular
the forefoot and the degree of inversion slightly to prevent to the tarsals.
of the calcaneus. superimposition of leg ❖ Kite stressed the
shadow. Hold the infants importance of
knee together so that the directing the central
legs are exactly vertical. ray vertically to
❖When the deformity is project the true
too great to permit correct relationship of the
placement of the legs and bones and
foot for bilateral images, ossification centers.
they must be examined
separately.

8
 Lateral Projection ❖ Patient on his or her side 8 x 10 (18 x 24 ❖Perpendicular to None ❖ No medial or
(Mediolateral) in as near as lateral position cm) the mid tarsal area. lateral angulation of
with uppermost limb flexed, the leg
drawn forward. ❖ Fibula in lateral
❖Adjust the IR under the projection
foot and place a support overlapping the
under the knee to prevent posterior half of the
angulation of the foot tibia
ensuring lateral position. ❖ The need for
Hold the foot in position repeat exam. If slight
The Kite method lateral demonstrates with tape or protected variation in rotation
the anterior talar subluxation and the hand. is seen in either
degree of plantar flexion (equinus). image when
compared with
previous radiographs
❖ Sufficient density
of the talus,
calcaneus, and
metatarsals to allow
assessment of
alignment variation.
CALCANEUS
Axial Projection ❖Patient supine or seated 8 x 10 inches ❖Directed to the ❖Shows an axial ❖Calcaneus and
Plantodorsal with leg extended. (18 x 24 cm) midpoint of the IR projection of the subtalar joint
❖IR under the patients at a cephalic angle calcaneus. ❖ No rotation of the
ankle centered to the of 40 degrees to the calcaneus
midline of the ankle. Long long axis of the foot ❖the first or fifth
strip of gauze placed around entering the base of
metatarsals not
the ball of the foot, grasping the third metatarsal.
projected to the sides
it to hold the ankle in right of the foot
angle dorsiflexion. If the ❖ Anterior portion of
ankle cannot be flexed to
the calcaneus
place the plantar surface of
without excessive
the foot perpendicular to IR,
density over the
elevate the leg on sandbag.
posterior portion.
Otherwise two

9
 images maybe
needed for the two
regions of thickness.
Axial Projection ❖ Patient in prone position. 8 x 10 inches ❖Directed to the ❖Shows an axial ❖Calcaneus and
Dorsoplantar ❖Patients ankle elevated on (18 x 24 cm) midpoint of the IR projection of the subtalar joint
sandbags. Adjust the height at a caudal angle of calcaneus and the ❖ Sustentaculum tali
and position of sandbags 40 degrees to the subtalar joint. ❖ Calcaneus not
under the ankle so that long axis of the foot,
rotated
patient can dorsiflex the entering the dorsal
❖the first or fifth
ankle to place its long axis surface of the ankle
joint. metatarsals not
perpendicular to tabletop.
projected to the sides
Place IR against the plantar
of the foot
surface of the foot and
❖ Anterior portion of
support in position with
sandbag. the calcaneus
without excessive
density over
posterior portion.
Otherwise, two
images may be
needed for the two
regions of thickness.
Weight Bearing Coalition Method ❖Patient in upright standing ❖Angled exactly 45 None None
position degrees anteriorly
❖Center the IR to the long and directed
axis of the calcaneus with through the
the posterior surface of the posterior surface of
heel at the edge of the IR. the flexed ankle to a
To prevent superimposition point on the plantar
of the leg shadow, patient surface at the level
place the opposite foot one of the base of the
step forward. fifth metatarsal.
Demonstrate calcaneotalar coalition also
know as “coalition position”

10
 Lateral Projection ❖ Have the supine patient 8 x 10 inches ❖Perpendicular to ❖ Shows the ankle ❖No rotation of the
turn toward the affected (18 x 24 cm) the calcaneus. joint and the calcaneus
side until the leg is Center about 1 inch calcaneus in lateral ❖Density of the
approximately lateral. A distal to the medial profile. sustentaculum tali,
support may be placed malleolus placing lateral tuberosity and
under the knee. the CR at the soft tissue
❖ Adjust the calcaneus to subtalar joint. ❖ Sinus tarsi
the center of the IR. Adjust ❖ Ankle joint and
the IR so that its long axis is
adjacent tarsals
parallel with the plantar
surface of the heel.
ANKLE
AP Projection ❖Patient in supine affected 8 x 10 inch (18 ❖Perpendicular ❖Shows a true AP ❖- Tibiotalar joint
limb fully extended. x 24 cm) through the ankle projection of the space
❖Ankle joint in true AP lengthwise or joint at a point ankle joint, the ❖ Ankle joint
24 x 30 cm midway between the distal ends of the
position, then flex the foot centered to exposure
crosswise for 2 malleoli. tibia and fibula,
and ankle enough to place area
images on one and the proximal
the long axis of the foot in ❖ Talus slightly
IR portion of the talus
near vertical position. overlapping the distal
fibula
❖No overlapping of
the medial talo
malleolar articulation
❖Medial and lateral
malleoli
❖Talus with proper
density
❖ Soft tissue
LATERAL PROJECTION ❖Supine patient turn to the 8 x 10 inch (18 ❖Perpendicular to ❖ Shows a true ❖ Ankle joint
Mediolateral affected side until the ankle x 24 cm) the ankle joint, lateral projection centered to exposure
is lateral. entering the medial of the lower third area
❖ Long axis of the IR is malleolus of the tibia and ❖Tibiotalar joint well
parallel to the long axis of fibula, the ankle visualized, with the
the leg and center it to the joint, and the medial and lateral
ankle joint. Ensure that tarsals.

11
 lateral surface of the foot in talar domes
contact with the IR. superimposed
Dorsiflex the foot and ❖ Fibula over the
adjust it in lateral position. posterior half of the
tibia
❖ Distal tibia and
fibula, talus, and
adjacent tarsals
❖Density of the
ankle sufficient to
see the outline of
distal portion of the
fibula.
LATERAL PROJECTION ❖Supine patient turn away 8 x 10 inch (18 ❖Perpendicular ❖Shows a lateral ❖Ankle joint
Lateromedial from the affected side until x 24 cm) through the ankle projection of the centered to exposure
the leg is lateral joint, entering 1/2 lower third of the area
❖Long axis of the IR is inch (1.3 cm) tibia and fibula, ❖Tibiotalar joint well
parallel to the long axis of superior to the the ankle joint, visualized, with the
the leg and center it to the lateral malleolus. and the tarsals. medial and lateral
ankle joint. talar domes
superimposed
❖ Fibula over the
posterior half of the
It is often recommended that the lateral tibia
projection of the ankle joint be made ❖Distal tibia and
with the medial side of the ankle in
fibula, talus, and
contact with the IR.
adjacent tarsals
❖Density of the
ankle sufficient to
see the outline of
distal portion of the
fibula

12
AP Oblique Projection ❖Patient in supine position 8 x 10 inch (18 ❖Perpendicular, ❖The 45-degree ❖ Distal tibia, fibula
Medial Rotation affected extended. x 24 cm) entering between medial oblique and talus
❖Center ankle joint to the the malleoli. projection ❖Distal tibia and
IR and adjust it so that the demonstrate the fibula overlap some
long axis is parallel with long distal ends of the of the talus
axis of the leg. Dorsiflex the tibia and fibula, ❖ Talus and distal
foot enough to place the parts of which are
tibia and fibula
ankle at nearly right-angle often
adequately
flexion. Assist the patient to superimposed over
penetrated
rotate the entire leg and join the talus.
❖ Tibiofibular
t 45 degrees medially. Tibiofibular
articulation should articulation
also be
demonstrated
AP Oblique ❖ Patient in supine position 8 x 10 inch (18 ❖Perpendicular, ❖Lateral rotation ❖Subtalar joint
Lateral Rotation extended x 24 cm) entering the ankle oblique projection ❖Calcaneal sulcus (
❖ Place the plantar surface joint midway is useful in superior portion of
of the foot in the vertical between the determining the calcaneus)
position and laterally rotate malleoli fractures and
the leg and foot 45 degrees demonstrating the
and center the ankle joint to superior aspect of
the IR. the calcaneus.

AP Stress Study ⤷ Rupture of a ligament is AP Projection None None None
demonstrated by widening stress studies
of the joint space on the of the ankle
side of the injury, when joint are
without moving or rotating usually
the lower leg from supine obtained
position, the foot is forcibly following
turned towards the opposite inversion or
side. eversion injury
⤷Local anesthesia is injected to verify the
into the sinus tarsi prior to presence of
stress if the injury is recent. ligamentous
tear

13
 ⤷The physician holds or
strap the foot when it must
be turned into extreme
stress for exposure.
Mortise Joint ❖Patient in supine position 8 x 10 inch (18 ❖Perpendicular, ❖ The entire ankle ❖ Talus
AP OBLIQUE Medial rotation affected limb extended. x 24 cm) entering the ankle mortise joint demonstrated with
❖Center ankle joint to the joint midway should be proper density
IR. Assist the patient to between the demonstrated in ❖Entire ankle
rotate the entire leg and malleoli. profile. The three mortise joint
joint 15-20 degrees sides of the ❖ No overlap of the
medially. mortise joint
anterior tubercle of
should be
the tibia and the
visualized.
superolateral portion
of the talus with the
fibula.
LEG
AP Projection ❖Patient in supine position. 18 x 43 cm or ❖Perpendicular to ❖The resulting ❖Ankle and knee
❖Adjust the patient body 35 X 43 cm for the center of the leg image shows the joints on one or more
two images on tibia, fibula, and AP projections
so that pelvis is not rotated
one IR Position adjacent joints. ❖ Ankle and knee
then adjust the leg so that
of patient
the femoral condyles are joints without
parallel with the IR and the rotation
foot is vertical. ❖Proximal and distal
articulations of the
tibia and fibula
moderately
overlapped
❖ Trabecular detail
and soft tissue for
the entire leg

14
 LATERAL PROJECTION ❖Patient in supine. 18 x 43 cm or ❖Perpendicular to ❖The resulting ❖Ankle and knee
Mediolateral ❖Turn the supine patient 35 X 43 cm for the center of the leg. image shows the joints on one or more
two images on tibia, fibula, and images
towards the affected side
one IR adjacent joints. ❖ Distal fibula lying
with the leg on the IR then
adjust the rotation of the over the posterior
body to place the patella half of the tibia
perpendicular to the IR. ❖ Slight overlap of
the tibia on the
proximal fibular head
❖ Ankle and knee
joints not rotated
❖ Possibly no
superimposition of
femoral condyles
because of
divergence of the
beam
❖Moderate
separation of the
tibial and fibular
bodies, or shafts
except at their
articular ends.
KNEE
AP PROJECTION ❖Patient in supine and 10 x 12 inch ❖Directed to a ❖The resulting ❖Open femorotibial
adjust the body so that (24 x 30 cm) point 1/2 inch (1.3 image shows an AP joint space
pelvis is not rotated. cm) inferior to the projection of the ❖ Knee fully
❖With the IR under the patellar apex. knee structures. extended if patient'
patients, flex the knee to Variable, depending condition permits
locate the apex of the on the measurement ❖ Interspaces of
patella and as the patient between the
equal width on both
extends the knee center the anterior superior
sides if the knee is
IR about ½ “below the iliac spine (ASIS) and
Radiograph of the knee may be taken normal
patellar apex. the tabletop;
with or without use of a grid

15
 ⤷ < 19 cm - 3 to 5 ❖ Patella completely
degrees caudad superimposed on the
(thin pelvis) femur
⤷ 19 to 24 cm – 0 ❖ No rotation of the
degrees
femur and tibia
⤷ ->24 cm - 3 to 5
❖Slight
degrees cephalad
(large pelvis) superimposition of
the fibular head if the
tibia is normal
❖Soft tissue around
the knee joint
❖Bony detail
surrounding the
patella on the distal
femur
LATERAL PROJECTION ❖Patient turn towards 10 x 12 inch ❖Center the IR to ❖Shows a lateral ❖ Femoral condyles
Mediolateral affected side. For standard (24 x 30 cm) the central ray image of the distal superimposed
lateral, have the knee ❖Directed to the end of the femur, ❖ Open joint space
forward and extend the knee joint I inch (2.5 patella, knee joint, between femoral
other limb behind. cm) distal to the proximal ends of condyles and tibia
❖Flex the knee 20 to 30 medial epicondyle the tibia and ❖ Patella in a lateral
degrees to show maximum at an angel of 5 to 7 fibula, and
profile
volume of joint cavity. degrees cephalad. adjacent soft
❖ Open
❖To prevent fragment ❖This slight tissue.
patellofemoral joint
separation in new or angulation of the space
unhealed patellar fracture, central ray will ❖ Fibular head and
the knee should not be prevent the joint tibia slightly
flexed more than 10 space from being superimposed (Over
degrees obscured by the rotation causes less
magnified image of superimposition, and
the medial femoral under rotation
condyle.
causes more
superimposition.)
❖ Knee flexed 20 to
30 degrees

16
 ❖ All soft tissue
around the knee
❖ Femoral condyles
with proper density
AP Projection Weight-Bearing Standing ❖Patient in upright with the 35 x 43 cm ❖Horizontal and ❖Shows the joint ❖No rotation of the
back toward a vertical grid crosswise for perpendicular to the spaces of the knees
device. bilateral image center of the IR knees. Varus and ❖ Both knees
❖Center the knees to the Position of entering to a point valgus deformities ❖ Knee joint space
patient ½ inch below the can be evaluated.
IR, toes straight ahead with centered to the
feet separated enough for apices of the patella
exposure area
good balance. ❖ Adequate IR size
❖Patient stand straight to demonstrate the
Leach, Gregg, and Siber recommended with knees fully extended longitudinal axis of
that a bilateral weight-bearing AP and weight equally the femoral and tibial
projection be routinely included in distributed on the feet. bodies or shafts.
radiographic examination of arthritic Center IR ½ inch below the
knees because it reveals narrowing of the patellar apices.
knee joint spaces that appears normal in
the non-weight bearing study
PA Projection Rosenberg Method ❖Patient in standing 35 x 43 cm ❖Horizontal and ❖PA weight- ❖No rotation of the
Weight-Bearing Standing Flexion position with the anterior crosswise for perpendicular to bearing method is knees
aspect of the knee centered bilateral image center of the IR The useful for ❖Both knees
to the vertical grid device. Position of CR is perpendicular evaluating joint ❖ Knee joint
Position of part. patient to tibia and fibula. A space narrowing
centered to the
❖ For direct PA projection, 10-degree caudal and
exposure area
have the patient stand angle is sometimes demonstrating
upright with knees in used. articular cartilage
contact with the grid device. disease. The image
Center the IR at the level ½ is radiographing
inch below the apices of the intercondyloid
Note: For a weight-bearing study of a fossa.
the patella. Patient grasp
single knee, the patient puts full weight
the edge of the grid device
on the affected side
and flex the knees to place
the femur at 45-degree
angle.

17
 INTERCONDYLOID FOSSA
PA Axial Projection Place the patient in one of 8 x 10 inches ❖Perpendicular to ❖ Shows the ❖Open fossa
Holmblad Method three position: (18 x 24 cm) the lower leg, intercondyloid ❖ Posteroinferior
1. Standing with the entering the fossa of the femur surface of the
affected knee flexed and midpoint of the IR and the medial femoral condyles
resting on a stool at the side for all three position. and lateral ❖Intercondylar
of radiographic table. intercondylar
2. Standing at the side of eminence and knee
tubercle of the
the table with the affected joint space
intercondylar
knee flexed and in contact ❖Apex of the patella
eminence in
with front of the IR. profile. It also not superimposing
3. Kneeling on top of states that the the fossa
radiographic table as degree of flexion ❖No rotation evident
originally described by used widens the by slight tibiofibular
Holmblad. joint space overlap
❖For all positions, place the between the ❖Soft tissue in the
IR against the anterior femur and the fossa and interspaces
surface of the patients knee tibia and gives ❖Bony detail in the
and center it to the apex of improved image of intercondyloid
the patella. Flex the knee 70 the joint and eminence, distal
degrees from full extension surfaces of the femur and proximal
with 20-degree difference tibia and femur tibia.
from the central ray

PA Axial or “tunnel” projection required
that the patient assume a kneeling
position.

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 PA Axial Camp Coventry ❖Patient in prone and 8 x 10 inches ❖Perpendicular to ❖Demonstrate an ❖ Open fossa
adjust the body so that it is (18 x 24 cm) the long axis of the unobstructed ❖ Posteroinferior
not rotated. leg and centered to projection of the surface of the
❖Flex the knee to either a the knee joint (over intercondyloid femoral condyles
40- or 50-degree angle and popliteal fossa and the ❖Intercondylar
rest the foot on a suitable depression). Angled medial and lateral
eminence and knee
support. Center the upper 40 degrees when intercondylar
joint space
half of the IR to the knee the knee is flexed 40 tubercle of the
❖ Apex of the patella
joint to project the joint to degrees of 50 intercondylar
degrees when the eminence. not superimposing
the center of the IR. Adjust
knee is flexed 50 the fossa
Note: Intercondyloid fossa projection is the leg so that the knee has
degrees ❖ No rotation
also used to detect loose bodies (“joint no medial or lateral
mice”) rotation. evident by slight
tibiofibular overlap
❖Soft tissue in the
fossa and interspaces
❖ Bony detail of the
intercondylar
eminbence, distal
femur and proximal
tibia
AP Axial Beclere Method ❖Patient in supine and 8 x 10 inches ❖Perpendicular to ❖Shows the ❖Open intercondylar
adjust the body so that it is (18 x 24 cm) the long axis of the intercondylar fossa
not rotated. tibia entering the fossa, ❖Posteroinferior
❖Flex the affected knee knee joint ½ inch intercondylar surface of the
enough to place the long below the patellar eminence and femoral condyles
axis of the femur at an apex. knee joint. ❖ Intercondylar
angle of 60 degrees to the eminence and knee
long axis of the tibia. IR joint space
under the knee and position ❖No
it so that it coincide with the
superimposition of
central ray. Adjust the leg so
the fossa by the of
that femoral condyles are
the patella
equidistant from the IR.
❖ No rotation
evident by slight
tibiofibular overlap

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 ❖ Soft tissue in the
fossa and interspaces
❖ Bony detail on the
intercondylar
eminence, dista
femur and proximal
tibia.
PATELLA
PA Projection ❖Patient in prone. If the 8 x 10 inches ❖Perpendicular to ❖PA projection of ❖Patella completely
knee is painful place a (18 x 24 cm) the mid-popliteal the patella superimposed by the
support under the thigh and area exiting the provides sharper femur
leg to relieve pressure. patella. recorded detail ❖ Adequate
❖Center IR to the patella. than in the AP penetration for
Adjust the position of the projection because visualization of the
leg to place the patella of the closer patella clearly
parallel with the plane of IR object-to-image through the
by rotating the heel 5-10 receptor distance superimposing femur.
degrees laterally ❖ No rotation
Lateral Projection ❖Patient in lateral 8 x 10 inches ❖Perpendicular to ❖Shows a lateral ❖Knee flexed 5-10
Mediolateral recumbent position (18 x 24 cm) the IR entering the projection of the degrees
❖Patient to turn toward the knee at the mid patella and ❖Open
affected side and place patellofemoral joint. patellofemoral patellofemoral joint
support under the ankle. joint space. space
Flex the unaffected knee ❖ Patella in lateral
and hip and place profile
unaffected foot in front of ❖Close collimation
affected limb. The affected
knee is flexed 5-10 degrees
because increasing the
flexion reduces the
patellofemoral joint space.
❖Adjust the knee in lateral
so that femoral epicondyles
are superimposed and
patella perpendicular.

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 PATELLA AND PATELLOFEMORAL JOINT
Tangential Hughston Method ❖ Patient in prone with the 8 x 10 inches ❖Angled 45 degrees ❖Shows ❖Patella in profile
foot resting on radiographic (18 x 24 cm) cephalad directed to subluxation of the ❖Open
table. for unilateral patellofemoral joint. patella and patellofemoral
❖ IR under the patients 24 x 30 cm patellar fractures articulation
crosswise for and allows
knee then slowly flex the ❖ Surfaces of the
bilateral radiographic
affected knee so that the femoral condyles
examination assessment of the
tibia and fibula form 50-60 ❖ Soft tissue of the
degree angle from the table femoral condyles.
femoropatellar
with the foot resting on the
articulation
collimator or support it in
For a tangential radiograph of the patella, ❖ Bony recorded
position.
the patient maybe placed in any of the detail on the patella
following body positions: prone, supine, and femoral condyle
lying on the side, seated on the table,
seated on the radiographic table with the
leg hanging over the edge or standing
Tangential Projection ❖ Patient in supine or 8 x 10 inches ❖Perpendicular to ❖Shows vertical ❖Patella in profile
Settegast Method prone. Prone is preferable (18 x 24 cm) the patellofemoral fracture of the ❖ Open
because the knee can be joint space if bone and the patellofemoral
flexed to a greater degree perpendicular if not, articulating articulation
and immobilization is central ray surfaces of the ❖ Surfaces of the
easier. If the patient is angulated patellofemoral
femoral condyles
seated on the table, hold depending on the articulations.