Radiographic Positioning Of Skull And Vertebra PDF

Summary

This document provides information on radiographic positioning techniques for the skull and vertebrae, including morphology and surface landmarks. It details various projections and methods, such as Caldwell's, Towne's, and Haas methods, used for imaging different areas of the skull. The document also covers paranasal sinuses and their imaging.

Full Transcript

RADIOGRAPHIC POSITIONING
SKULL AND VERTEBRA

FGBREYES, RRT, CVT, MSRT
 MORPHOLOGY
The morphology, or variations in
how these attachments evolved
tells us much about the particular
animal's adaptations to their
environment.

(exceptions include Old World
primates such as humans, in
which the middle ear cavity is
Canis latrans auditory bulla
enclosed within the temporal
bone but not within a bulla).
SKULL MORPHOLOGY
MESOCEPHALIC
Average head
15 cm between parietal
eminences
19 cm from the frontal
eminence to inion
23 cm from vertex to chin.
Temporal base or petrous
pyramid forms an angle of
45° to 47° to the MSP.
SKULL MORPHOLOGY
BRACHYCEPHALIC
Short from front to back
Broad from side to side
Shallow from vertex to
base
Petrous pyramid forms an
angle greater than 47°
(approximately 54°) to the
MSP.
The width is 80% or
greater than the length
SKULL MORPHOLOGY
DOLICOCEPHALIC
Head is long from front to
back
Narrow from side to side
Deep from vertex to base.
Petrous pyramid form an
angle less than 47°
(approximately 40°) to the
MSP
The width is less than 75%
of the length.
CRANIAL TOPOGRAPHY
SURFACE LANDMARKS

Midsagittal Plane or Median Plane (MSP)
Symmetrically divides the body into left and right halves.

Interpupillary Line or Interorbital Line (IPL)
Connecting the pupils or outer canthi of the eyes

Supraorbital Groove (SOG)
Slight depression above each eyebrow.
Corresponds to the anterior fossa of the cranial vault.

Supraorbital Margin (SOM)
Superior rim of each orbit.
CRANIAL TOPOGRAPHY
SURFACE LANDMARKS
Pinna or Auricle
Large flap of cartilage at the external portion of the ear

Tragus
Small flap cartilaginous flap covering the ear.

Top of the Ear Attachment (TEA)
Superior attachment of the auricle
Same level of petrous ridge

Canthi/Canthus
Junction of the upper and lower eyelids
CRANIAL TOPOGRAPHY
SURFACE LANDMARKS
Gonion/Angle of the Mandible
The lower posterior angle on each side of the jaw or mandible

Mental Point
The midpoint of this triangular area of the chin as it appears from the
front.

Glabellomeatal Line (GML)
It is a line between the glabella and EAM Orbitomeatal Line (OML)
Frequently used positioning line located between outer canthus and the

EAM.
Also called the RADIOGRAPHIC BASE LINE.
CRANIAL TOPOGRAPHY
SURFACE LANDMARKS
Infraorbitomeatal Line (IOML)

Reids base line - often used as the imaging reference line in brain CT
scanning
Line of Frankfurt - a line extending from the most inferior point of the
orbital margin to the left tragion.

Anthropological base line - passes from the infraorbital point to the
upper border of the EAM (also known as the Frankforterline)

Base line of the cranium

It is a line which connects the infra-orbital point to the EAM
CRANIAL TOPOGRAPHY
SURFACE LANDMARKS
Infraorbitomeatal Line (IOML)

Reids base line - often used as the imaging reference line in brain CT
scanning
Line of Frankfurt - a line extending from the most inferior point of the
orbital margin to the left tragion.

Anthropological base line - passes from the infraorbital point to the
upper border of the EAM (also known as the Frankforterline)

Base line of the cranium

It is a line which connects the infra-orbital point to the EAM
CRANIAL TOPOGRAPHY
SURFACE LANDMARKS

OML AND GML
There is an approximate 8° average angle difference between the OML
and GML

OML AND IOML There is an average difference of 7° exists between the
angles of the OML and IOML

IOML AND AML There is an average difference of 15° exists between the
angles of the IOML and AML
CRANIAL TOPOGRAPHY
SURFACE LANDMARKS

Acanthiomeatal Line (AML)
It is a line between the acanthion and EAM

Interpupillary Line (IPL)
It joins the center of the two orbits or pupils

Mentomeatal Line (MML)
It is a line between the mental point (mandible) and EAM.
CRANIAL TOPOGRAPHY
SURFACE LANDMARKS

Lips to Meatal Line (LML)
It is a line between the junctions of the lips to the EAM.

Glabelloalveolar Line
Connects the glabella to a point at the anterior aspect of the alveolar
process of the maxilla.

Auricular Line
It is perpendicular to the anthropological base line and passes through
the EAM
CRANIAL TOPOGRAPHY
SURFACE LANDMARKS
SKULL AP PROJECTION

OML perpendicular to the IR

CR perpendicular to nasion.

Best demonstrate the frontal and parietal bones.

Petrous pyramid fills the orbit
SKULL PA AXIAL PROJECTION
CADWELL’S METHOD

Prone
Forehead and nose
OML is perpendicular to IR
MSP is perpendicular to midline of the table.
CR 15° caudad to nasion
Best demonstrate alveolar ridge fractures.
General survey examination of the cranium.
Petrous pyramid in the lower 1/3 of the orbits
SKULL PA AXIAL PROJECTION
CADWELL’S METHOD MODIFICATION

CALDWELL’S METHOD
23° caudad to nasion.
Glabellomeatal Line (GML) perpendicular to IR

20° to 25° caudad to mid-orbit
Demonstrate superior orbital fissures

25° - 30° Caudad
Demonstrate rotundum foramina
Petrous pyramid projected below the inferior
orbital margin.
SKULL PA AXIAL PROJECTION
TOWNE’S/GRASHEY METHOD MODIFICATION

OML perpendicular to film plane (chin depressed)
IOML perpendicular to film plane (Patient unable to flex their neck).

CENTRAL RAY:
1. 30° caudad to OML perpendicular to IR
2. 37° caudad to IOML perpendicular to IR
3. 40° - 60° caudad
Foramen magnum and jugular foramina
2.5 in.(6 cm) above glabella
Best demonstrate the occipital bone
Posterior clinoid process within the shadow of the foramen magnum.
Excessive angulation of CR projects the posterior C1 arch in the foramen
magnum.
Under angulation of the CR projects the dorsum sella above foramen the
magnum.
SKULL PA AXIAL PROJECTION
TOWNE’S/GRASHEY METHOD MODIFICATION
SKULL PA AXIAL PROJECTION
HAAS METHOD

Prone position Forehead and nose
OML perpendicular to IR
CR 25° cephalad to 1.5 in. inferior to the inion and exiting 1.5 in. above nasion.
Also called Reverse Towne’s projection
For hypersthenic or kyphotic, obese and other patients who cannot be adjusted
for AP axial projection.
Best demonstrate the occipital bone with magnification
SKULL PA AXIAL PROJECTION
HAAS METHOD
SKULL LATERAL

MSP is parallel to IR
IPL is perpendicular to IR
IOML perpendicular to front edge of
the cassette.
CR perpendicular to 2 inches above
EAM
Best demonstrate the parietal
bones.
Sella tursica and clivus are
demonstrated in profile.
SKULL LATERAL

Crosstable or Shoot-
Through Lateral
Projection
demonstrating traumatic
sphenoid effusion which
is an indication of a basal
skull fracture.
SVM (SUBMENTOVERTIAL) - FULL BASAL PROJECTION / SCHULLER METHOD

Head resting on vertex MSP is
perpendicular to IR
IOML is parallel to IR.
CR to ¾ inch (2 cm) anterior to level
of EAMs
Best demonstrate the base of the
skull
Demonstrate the basilar portion of
the occipital bone.
Mandibular condyles anterior to
petrous pyramids.
VERTICOSUBMENTO- FULL BASAL PROJECTION / SCHULLER METHOD

Distorted and magnified image of the
midbase due to increase OID and
angulation of CR.
Useful for studies of anterior cranial
base and sphenoid sinuses.
Best projection for foramen ovale
and spinosum.
Alternative projection for SMV
projection.
Mandibular condyles anterior to
petrous pyramids.
AXIOLATERAL - LYSHOLM METHOD

Head in lateral position.
CR 30°-35° caudad exit at a point 1
inch (2.5 cm) distal to the lower EAM
Alternative projection for SMV
projection for patient who cannot
extend their neck.
Oblique position of the lateral base
of the cranium closest to the IR.
SELLA TURSICA - LATERAL PROJECTIONS

Sella Tursica
Turkish Saddle Posterior Clinoid Process
Small extensions superior to the dorsum sellae.

Dorsum Sellae
Back of the saddle
Posterior wall of sella tursica.

Clivus
Shallow depression just posterior to the base of
the dorsum sellae.
Forms a base of support for the pons portion of
the brain.
SELLA TURSICA - PA AXIAL PROJECTION - HAAS METHOD

1) 25° cephalad to 1.5 inches Reverse Towne’s projection
inferior to the inion and
exiting 1.5 inches above 25° cephalad
nasion Dorsum sellae and posterior clinoid
processes projected within the
2) 10° cephalad shadow of the foramen magnum.
This is an alternative
10° cephalad
projection for demonstrating
Dorsum sellae is projected above
the dorsum sella, posterior the foramen magnum.
clinoid, foramen magnum and
petrous ridge.
PARANASAL SINUSES
PARANASAL SINUSES
Large air-filled cavities
Should be radiographed in erect/upright position. To demonstrate the
presence of air-fluid level.
To differentiate between shadows caused by fluid and those caused by
other pathologic conditions.
Patient must be in erect at least 5 minutes before taking the examination.

FEMS
Frontal Sinuses - Frontal (cranial) bone
Ethmoid - Ethmoid (cranial) bone
Maxillary Sinuses - Maxillary (facial) bone
Sphenoid - Sphenoid (cranial) bone
PARANASAL SINUSES (PNS) - LATERAL PROJECTIONS

CR 15° caudad to nasion
Best projection to
demonstrate the frontal
sinuses and anterior
ethmoidal sinuses.
Petrous ridge are
projected into lower 1/3 of
the orbits.
PARANASAL SINUSES (PNS) -WATERS METHOD

Patient head is resting on CR directed to acanthion.
chin. Best demonstrate the maxillary
MML is perpendicular to IR sinuses above the petrous ridge.
OML forms an angle of 37° Useful projection for
demonstrating the foramen
with the plane of the film.
rotundum.
Tip of the nose ¾ inch Petrous pyramids below the
from the image receptor. maxillary sinuses.
Demonstrate any
retention cyst and possible
nasal deviation
PARANASAL SINUSES (PNS) -WATERS METHOD

Any step deformity in the lines would
indicate a fracture of that particular
facial bone.
PARANASAL SINUSES (PNS) -CALDWELL’S METHOD

CR 15° caudad to nasion
Best projection to
demonstrate the frontal
sinuses and anterior
ethmoidal sinuses.
Petrous ridge are
projected into lower 1/3
of the orbits. Caldwell view showing radiographic
features of frontal sinus: Scalloping of
the superior border, septa, and
supraorbital cells
PARANASAL SINUSES (PNS) -CALDWELL’S METHOD VS. WATERS METHOD
PARANASAL SINUSES (PNS) - PARIETOACANTHIAL TRANS-ORAL PROJECTION
OPEN MOUTH WATERS

Demonstrate the sphenoid Indications
sinuses through the open It can be used to assess for
mouth. facial fractures, as well as
for acute sinusitis.
The open mouth projection
removes the upper teeth from
direct superimposition of the
sphenoid.

This is an angled PA radiograph
of the skull, with the patient
gazing slightly upwards.
PARANASAL SINUSES (PNS) - PARIETOACANTHIAL TRANS-ORAL PROJECTION
PIERRE METHOD

Head resting on nose and chin
Instruct the patient to phonate “ah” softly during
exposure.

Direct CR at 30° caudad to MSP (a line extending from
the sella tursica to the center of the open mouth)

Demonstrate an axial image of the sphenoid sinuses
projected through the open mouth.
PARANASAL SINUSES (PNS) - SUVMENTOVERTICO PROJECTION

CR perpendicular
between the angles of the
mandible.
Best demonstrate a
basal projection of the
sphenoid, ethmoid and
maxillary sinuses.
FACIAL BONES - LATERAL PROJECTIONS

Zygoma is centered to MLT
CR perpendicular to mid-
zygoma (midway between outer canthus
and EAM)
Useful for
demonstrating
depressed fractures of the frontal sinus.
Superimposed
mandibular rami, orbital
roof
FACIAL BONES - WATERS PROJECTION

Demonstrate an axial
image of the facial bones.
Best single projection
for demonstrating the
entire facial bone.
Petrous ridge below the
maxillary sinus.
Useful for demonstrating
fractures of the orbit and
fractures of the nasal
wings.
FACIAL BONES - MODIFIED WATERS PROJECTION

Prone position Demonstrates facial
Patient head is resting on bones with less axial
chin and nose. angulation.
LML is perpendicular to Petrous ridges are projected into
table lower-half of the maxillary sinuses.
OML forms an angle of Best demonstrates a
55° with the film. more direct view of the
CR Perpendicular to orbital rim as compared
acanthion with Waters projection.
FACIAL BONES - AP AXIAL PROJECTION REVERSE WATERS PROJECTION

Patient in supine position.
IOML is perpendicular to IR
30° Cephalad – CR will enter the face or
slightly below the lips and exits 2
nches above the inion.
CR must be parallel to MML.
Demonstrate an axial position of the
superior facial bone (similar to waters
projection), although the structures
are magnified.
NASAL BONE LATERAL PROJECTION - (SOFT TISSUE LATERAL)

CR perpendicular to 1⁄2 inch
inferior to nasion
Best position to demonstrate non-
displaced linear fractures of the
nasal
bone.
Soft tissue structure of
the nose.
Nasal bones
Nasofrontal suture
Anterior nasal spine
NASAL BONE SUPEROINFERIOR TANGENTIAL (AXIAL) PROJECTION

Patient in prone position or
upright seated on chair.
CR center to nasion and
parallel to GAL
Primarily used to
demonstrate medial or
lateral displacements of
fragments in fractures.
Demonstrates mid to distal
nasal bones in a tangential
perspective.
ZYGOMA - SUBMENTOVERTICO PROJECTION

CR perpendicular to
IOML to a point midway
between zygoma 1 1⁄2 - 2
inches inferior to
mandibular symphysis
Also known as the TEA
CUP OR
JUGHANDLER’S VIEW
Demonstrate the lateral
margins of the
zygomatic arches free
of superimposition
ZYGOMA TANGENTIAL POSITION: OBLIQUE INFEROSUPERIOR PROJECTION

Patient in SMV position Slightly oblique
Rotate head/MSP 15° tangential image of
toward side being one zygomatic arch
examined, then tilt chin
free of
15° toward side of
interest
superimposition.
CR Perpendicular to Useful with patients
IOML and center to who have depressed
zygomatic area of interest fractures or flat
approximately 1 1⁄2 inches cheekbones.
posterior to outer canthus
ZYGOMA TANGENTIAL POSITION: OBLIQUE INFEROSUPERIOR PROJECTION
ZYGOMA - MODIFIED FUCHS METHOD
CR - 35° caudad and
Patient in prone position enters the most prominent
Rest cheek of the point of the zygoma
affected side on table farthest from film.
Oblique position of the
AML perpendicular to IR
uppermost zygomatic arch
Rotate head so that free of superimposition.
MSP forms 45° then tilt Lateral portion of maxillary
head 15° (rotation and sinus is also well
demonstrated.
tilt ensure that CR will be Unilateral zygomatic
tangent to the lateral arch free from overlying
surface of the skull. structures.
ZYGOMA - MODIFIED TOWNE’S METHOD

30° caudad to OML
perpendicular to IR
37° caudad to IOML
perpendicular to IR
1 inch (2.5cm) above
glabella
Shows the symmetric
view of both zygoma
ZYGOMA - ZYGOMA MAY METHOD
Single zygomatic arch
Patient in prone position, free of superimposition.
neck extended. CR perpendicular to
Rest chin on table
IOML to 1 1⁄2 inches
Rotate head away from
posterior to outer
the side being
examined so that MSP
canthus.
forms 15° then tilt head Best projection for
15°. patients who have
IOML as nearly parallel to depressed fractures or
IR flat cheekbones.
ZYGOMA - ZYGOMA MAY METHOD
MASTOID AND TEMPORAL BONE AP AXIAL PROJECTION TOWNE’S/GRASHEY
METHOD

30° caudad - OML
perpendicular to IR
37° caudad - IOML
perpendicular to IR
2.5 inches (6 cm)
above glabella
Demonstrate the
petrosas above the
base of the skull.
ORIGINAL LAW METHOD
DOUBLE TUBE
ANGULATION
METHOD
Head in lateral
position.
15° caudad and 15°
anteriorly to 2 inches
posterior and 2 inches
superior to the
uppermost EAM
ORIGINAL LAW METHOD

Adjust head until MSP
This position
forms a 15° angle in
demonstrates the
relation to the table.
15° caudad to 2 inches mastoid air cells and
posterior and 2 inches internal auditory canal
superior to the uppermost of the side closest to IR
EAM Demonstrates an
Superimposed internal axiolateral perspective of
acoustic meatus (IAM) mastoid air cells closest
and external acoustic
to film.
meatus (EAM).
MODIFIED LAW
STENVERS

POSTERIOR PROFILE
POSITION
Head resting on forehead,
nose and zygoma
Downside or closest to IR
petrous bone in profile.
12° cephalad enters 3-4
inches posterior and 1 1⁄2
inferior to upside EAM and
exits 1 inch anterior do
downside EAM
MSP forms an angle of
45° in relation to table.
ARCELIN
ANTERIOR PROFILE
PROJECTION
MSP forms an angle of
45° in relation to table.
10° caudad to 1 inch and
anterior and 3⁄4 inch
superior to elevated EAM.
Reverse Stenvers
projection.
Upside or farthest from IR
petrous bone in profile.
Useful with children and
adults who cannot be
placed in prone position.
LYSHOLM

30-35° caudad to
dependent EAM
closest to IR

Also referred as the
Runstrom II method

-Recommended for pt
who cannot extend their head enough
for a satisfatory SMV.
HENSCHEN

15° caudad To
dependent EAM
closest to IR

Demonstration of
tumours of acoustic
nerve.
SCHULLERS

25° caudad to
dependent EAM
closest to IR
Demonstrate the
pneumatic structure
of the mastoid
process
ss: Cranial base
Sphenoidal sinuses
SMV

CR perpendicular to OML
centered to sagittal plane of
the throat at the level of the
EAMs.
The goal of this projection is
to project the long axis of
the EAMs, tympanic cavities
and the osseus part of the
auditory (Eustachian) tubes
immediately behind the
mandibular condyles.
Demonstrate the organ of
hearing within the petrosa.
HICKY METHOD

Tilt vertical grid device
down 15°
Mastoid process below
MSP forms a 55° angle in the shadow of the
relation to the table.
occipital bone.
Perpendicular to anterior
border of the mastoid Demonstrate a tangential
process at the junction of image of the mastoid
the auricle and head
about 1 inch superior to process free of
the palpable tip of superimposition by
mastoid process
15° caudad instead of adjacent bony structures.
tilting the IR.
HICKY METHOD
LOW BEER METHOD

Head in lateral
position
Demonstrate an
image similar to
Stenvers method
33° anteriorly and 10°
cephalad to 1 1⁄2 inch
anterior to EAM
closest to IR
ZANELLI METHOD

Patient in lateral position
MSP forms an angle of 30°
open caudally to IR.
Perpendicular to IR, Distal to
the uppermost mandibular
angle farthest from the film at
TMJ closest to f

Axiolateral images of the TMJ are
demonstrated in the open and
closed mouth positions

This method uses part angulation
instead of central ray angulation
ORBITS PARIETO-ORBITAL OBLIQUE POSITION RHESE METHOD

Prone position Rest the
ZYGOMA, NOSE and CHIN to
the table.
AML perpendicular to the
plane of the film. MSP forms
an angle 53° with the plane of
the film.

Demonstrate the OPTIC
FORAMEN at the LOWER
OUTER QUADRANT.

Also known as the threepoint
landing method.
ALEXANDER METHOD

Patient in supine position.
Place IR under occiput on a
15° cranially inclined sponge.
Demonstrate the OPTIC
FORAMEN at the LOWER
OUTER QUADRANT.
AML perpendicular to the
plane of the film.
MSP forms an angle 40° with
the plane of the film.
MODIFIED PARIETOACANTHIAL MODIFIED WATERS

Prone position
CHIN and NOSE resting on the table
LML is perpendicular to IR
OML forms an angle of 55° with the IR.
CR perpendicular to acanthion.
Best demonstrates the orbital floor.
Best projection for visualizing
BLOWOUT Fracture
Provides a more direct view of the
entire orbital rims than with Waters
projection.
Also known as the Shallow Waters.
PETROUS RIDGE projected into LOWER
HALF of the MAXILLARY SINUS, below
the Infraorbital margin.
ORBITS FOREIGH BODY LOCALIZATION

VOGT BONE-FREE
POSITIONS
Made on standard
periapical or
occlusal size dental
film.
PARALLAX MOTION METHOD

Modified Waters Lateral projection
1st exposure 1st exposure is
patient is instructed made looking
to look to the cephalad
extreme right 2nd exposure
2nd exposure looking caudad
extremely looking to
the left
PFEIFFER-COMBERG METHOD

A leaded contact lens is
placed directly over the
cornea, and intraorbital and
intraocular
The contact lens embedded
around the periphery 4 lead
markers spaced at 90°
intervals.
The apparatus designed
comprises:
Contact lens localization
device Pedestal type of film
holde
MANDIBLE PA PROJECTION

Forehead and nose
Rami and lateral portion of
the body.
CR perpendicular to tip of
nose.

Chin and nose
Frontal view of the body.
For the mentum of the
mandible.
CR perpendicular to glabella
For general survey of the
Demonstrates condylar process
mandible
CR perpendicular to lips
MANDIBLE PA AXIAL PROJECTION

Forehead and nose
Mandibular Body
Mandibular Rami
CR 20°-25° cephalad to exit at
acanthion.
Well visualized elongated
view of the head of the
mandibular condyles

Chin and nose
Mandibular Body
TMJ 30° cephalad between
TMJs
Mandibular body and TMJs
MANDIBLE AXIOLATERAL PROJECTION

1. Head in true lateral position 25° cephalad to pass
RAMUS directly through the
2. 10° to 15° rotation mandibular region of
GENERAL SURVEY interest.
3. 30° rotation The goal of this projection
BODY is place the desired portion
4. 45° rotation of the mandible parallel with
SYMPHYSIS MENTI the IR.
MANDIBLE AXIOLATERAL PROJECTION
MANDIBLE SUBMENTOVERTEX PROJECTION

Head resting on vertex
Perpendicular to IOML to a point
midway between angles of
mandible (1 ½ - 2 inches inferior
to mandibular symphysis)
Demonstrate the mandibular
condyles anterior to pars petrosa
Demonstrate the HORSE-SHOE
SHAPED mandible bone
MANDIBLE PANORAMIC TOMOGRAPHY

Adjust chin rest until IOML is
parallel with the floor.
Occlusal plane will decline by
10° from posterior to anterior.
Demonstrate a single frontal
projection of the teeth, mandible,
nasal fossa, zygomatic arches, and
maxilla.
STYLOID PROCESS FUCHS METHOD
CENTRAL RAY:
Angle the top of the grid
Perpendicular to head and
device 13° downward
directed through MSP and
toward the patient.
parallel with a line extending
AML perpendicular to IR
through the EAMs.
Instruct patient to hold
If necessary modify this
the mouth open during the
projection by angling the CR
exposure to prevent the
13° caudad instead of tilting
coronoid process of the
the IR.
mandible from
Demonstrate the styloid
superimposing the styloid
process of the temporal bone
process.
within the maxillary sinus.
STYLOID PROCESS FUCHS METHOD
STYLOID PROCESS PA AXIAL PROJECTION CAHOON METHOD

Forehead and nose resting
on table
Demonstrates the styloid
process within or above the
maxillary sinus.
CR 25° cephalad to Nasion
STYLOID PROCESS AP OBLIQUE PROJECTION WIGBY-TAYLOR METHOD

Patient supine Patient hold his mouth
open for exposure to
Rotate the head 12°
move the coronoid
from perpendicular processes of the
toward the side being mandible inferiorly
Demonstrate an
examined Occlusal
oblique projection of the
plane of upper teeth styloid process overlying
perpendicular to plane the soft tissue of the
neck.
of IR.
CR 8° cephalad to ¼
Rest the head on the inch distal to the tip of
occiput. the mastoid process
STYLOID PROCESS AP OBLIQUE PROJECTION WIGBY-TAYLOR METHOD
STYLOID PROCESS AXIOLATERAL OBLIQUE PROJECTION FUCHS METHOD

Head in lateral position.
CR 10° cephalad and 10°
anteriorly to EAM closest to
film
Demonstrate a lateral
image of the styloid process
projected into the space
superior to the mandibular
notch.
JUGULAR FORAMINA SUBMENTOVERTICO AXIAL PROJECTION KEMP HARPER
METHOD

CENTRAL RAY:
20° caudad to 1 inch distal
to mandibular symphysis
Increased central ray 5-
10° caudad for patient who
have prominent mandible.
Demonstrate the jugular
foramina projected near or
level of the angles of the
mandible.
SUBMENTOVERTICO AXIAL PROJECTION ERASO MODIFICATION

OML forms an angle of 25° to plane
of IR.
Perpendicularly directed to 2 inches
distal to mandibular symphysis
Not as demanding position as
compared with Kemp Harper method.
Demonstrate the jugular foramina
projected near or level of the angles
of the mandible
HYPOGLOSSAL CANAL AXIOLATERAL OBLIQUE PROJECTION / MILLER METHOD
ANTERIOR PROFILE

Used to delineate the hypoglossal
canal in a patient with a hypoglossal
(12th cranial) nerve tumor.
12° caudad to 1 inch directly anterior
and ½ inch inferior to level of EAM.
Patient in supine position
MSP 45° away from side being
examined
VERTABRAL COLUMN
ANATOMY
CERVICAL VERTEBRA

INTERVERTEBRAL FORAMINA
Directed anteriorly at a 45° angle
from the MSP and 15° inferior angle to
the horizontal plane of the body.

ZYGAPOPHYSEAL JOINT
Forms 90° angle to the MSP
ATLANTO-OCCIPITAL AP OBLIQUE PROJECTIONS

Rotate head 45-60 degrees from the
side being examined.
CR perpendicular to 1 inch anterior
to EAM
Demonstrate atlantooccipital
articulation between the orbit and the
ramus of the mandible.
ATLANTO-OCCIPITAL KASABACH METHOD

1st exposure the head is rotated 40-45 degrees
to the right away from the side being examined.

2nd exposure the head is rotated the head 40 –
45 degrees to the left away from the side being
examined.

CR 10-15 degrees caudad to a point midway
between the outer canthus and the EAM

Demonstrate an AP axial oblique projection of the
dens.
FUCH METHOD

Patient in Supine position.
MML perpendicular to table
CR parallel to MML, directed to
inferior tip of mandible.
Best demonstrate the odontoid
process within the foramen
magnum.
This is an alternative projection
for the dens when the upper half
is not shown on the open-mouth
projection.
JUDD METHOD

Patient in Prone position.
OML forms an angle of 37° to
plane of IR
MML perpendicular to table CR
parallel to MML, directed to
inferior tip of mandible.
Best demonstrate the odontoid
process within the foramen
magnum.
This is an alternative projection
for the dens when the upper half
is not shown on the open-mouth
projection.
C1 AND C2 AP OPEN-MOUTH PROJECTION

CR Perpendicular to the center
of the open-mouth
30 inch (70 cm.) SID is often used
to increase the field of view of the
odontoid area.
Lower margin of upper incisor to
the mastoid tip is perpendicular
to base of the skull.

Best demonstrate C1 and C2 free
from superimposition
Best demonstrate
zygapophyseal joint of C1 and C2
Best demonstrate Odontoid and
Jefferson’s fractures.
CERVICAL VERTEBRA AP AXIAL PROJECTION

Occlusal plane perpendicular to
the base of the skull.
CR 15˚- 20˚ cephalad, to enter at
the level of the lower margin of
thyroid cartilage to pass through
C4.
Best demonstrate intervertebral
disk space of C3-T2
CERVICAL VERTEBRA UPRIGHT LATERAL PROJECTION

Top of cassette about 1-2 inches CR horizontally directed to upper
above EAM. margin of thyroid cartilage (C4-C5).
Adding 5-to 10 lbs. weights to
Best demonstrate cervical
each arm may help in pulling
zygapophyseal joints.
down shoulders.
Most cervical injuries are best seen in
Long (72 inches or 180 cm) SID lateral projection.
compensates for increased OID
and provides for less 7 cervical vertebra demonstrated.
magnification.
CERVICAL VERTEBRA UPRIGHT LATERAL PROJECTION
CERVICAL VERTEBRA AP OBLIQUE PROJECTIONS RPO AND LPO POSITIONS

Rotate body and head 45°
15˚-20° cephalad toC4

Best demonstrate
intervertebral foramina and
pedicles farthest from the
image receptor
CERVICAL VERTEBRA PA OBLIQUE PROJECTIONS RAO AND LAO POSITIONS

Rotate body and head 45°
15˚-20° caudad toC4

Best demonstrate
intervertebral foramina and
pedicles nearest to the image
receptor
CERVICAL VERTEBRA AP WAGGING JAW PROJECTION OTTONELLO METHOD

CR perpendicular to C4
Have the patient open and
closed the mouth during
exposure to blur out the
mandible.
Use low mA and long
exposure time (minimum of 1
second)
Lower margin of upper
incisors to base of skull is
perpendicular to table.
Entire cervical column is
demonstrated.
CERVICAL VERTEBRA VERTEBRAL ARCH (PILLARS) AP AXIAL PROJECTION

Patient in supine position
Hyperextend neck
25 caudad to C7 (range20˚-
30˚caudad)
Refer as PILLAR OR
LATERAL MASS
PROJECTIONS.
Demonstrate the posterior
elements of the cervical
vertebra.
Demonstrate Pathology
involving the posterior
vertebral arch (particularly the
pillars) of C4 to C7.
VERTEBRAL ARCH (PILLARS) AP AXIAL OBLIQUE PROJECTION RIGHT AND LEFT
HEAD ROTATIONS
CR 35° caudad to spinous Demonstrate the vertebral arches or pillars when
process of C7 (Range of CR the patient cannot hyperextend the neck for the
30°-40°) AP or PA axial projection.
Rotate the patient’s head
45-50 degrees from the side
of interest.
45°-50° rotation
demonstrate the articular
process of the C2-C7 and T1
60°-70° rotation will
demonstrate the processes
of C6 and T1- T4
CERVICOTHORACIC SWIMMERS LATERAL TWINNING METHOD

Patient in erect position
Perpendicular if the shoulder
is well depressed
5° caudad if the shoulder is
not depressed
RP: Interdisk space of C7
and T1
Best projection to demonstrate C7 to T1 when
not shown on a cervical lateral projection.
Good projection to demonstrate the upper
thoracic vertebrae (T1- T4) when not shown on a
thoracic lateral projection.
Swimmers lateral upright method
CERVICOTHORACIC SWIMMERS LATERAL PAWLOW METHOD

Patient in a lateral Swimmers lateral recumbent method
recumbent position PAWLOW
METHOD
3°-5° caudad to the
interdisk of C7 and T1
MODIFIED PAWLOW:
5°-15° cephalad
This is a good projection
when C7 to T1 is not
visualized on the lateral
cervical spine or when the
upper thoracic vertebrae are
of special interest on a lateral
thoracic spine.
CERVICAL SPINE LATERAL PROJECTION HYPERFLEXION AND
HYPEREXTENSION
CR perpendicular to IR,
directed horizontally to C4
Functional study to
demonstrate range of motion
or lack of motion of cervical
vertebrae.
Performed to rule out
whiplash injuries.
Follow up examination after
spinal fusion surgery.
Spinal curvature
Range of spinal motion
Ligament stability
C1-C7
THORACIC VERTEBRA AP PROJECTION

CR perpendicular to IR,
directed horizontally to C4
Functional study to
demonstrate range of motion
or lack of motion of cervical
vertebrae.
Performed to rule out
whiplash injuries.
Follow up examination after
spinal fusion surgery.
THORACIC VERTEBRA LATERAL PROJECTION

Patient is allowed to MALE: 15° cephalad
continue breathing during FEMALE: 10° cephalad
exposure to blur out If vertebral column is not
unwanted rib and lung horizontal (support not placed
markings overlying the under lower thoracic).
thoracic vertebra. Thoracic vertebral bodies in
Use at least 2 seconds lateral profile.
exposure time. Intervertebral joint spaces
Perpendicular to T7 entering Intervertebral foramina
the posterior half of the
thorax.
THORACIC VERTEBRA LATERAL PROJECTION
THORACIC VERTEBRA OBLIQUE PROJECTIONS AP AND PA OBLIQUES
POSITIONS

Rotate the body 20° from Posterior Oblique Position
true lateral so that Best demonstrate zygapophyseal
joint farthest from the image
midcoronal plane forms an
receptor.
angle of 70° from plane of Anterior Oblique Position
the image receptor. Best demonstrate zygapophyseal
CR perpendicular to T7. joint closest to image receptor.
LUMBAR VERTEBRA AP PROJECTION
Patient in supine position
with knees flex. CENTRAL RAY 1. Perpendicular at
The knees are flexed to the level of the iliac crest for
decrease the lordotic curve lumbosacral studies.
of the lumbar. 2. Perpendicular to L3 for Lumbar
PA PROJECTION: reduce study.
patient dose and The erect position may be useful
sometimes used for upright
to demonstrate the natural
studies of the lumbar spine.
weight-bearing stance of the
It is also the preferred
position for patient who
spine.
has excruciating pain to Demonstrate the lumbar bodies,
reduce the physical intervertebral disk spaces.
discomfort associated with
the examination
LUMBAR VERTEBRA AP PROJECTION
LUMBAR VERTEBRA LATERAL PROJECTION

Flex knees to straighten the Lumbar spine not horizontal to
spine and helps open table.
intervertebral disk spaces. 1. Male – 5 degrees caudad
CENTRAL RAY: 2. Female – 8 degrees caudad
Lumbar Spine horizontal to Demonstrate the lumbar bodies,
table. intervertebral disk spaces and
1. Perpendicular at the level of transverse process,
the iliac crest for lumbosacral Best demonstrate the
studies. intervertebral foramina.
2. Perpendicular to L3 for Good projection for
Lumbar study. demonstrating compression
fractures.
LUMBAR VERTEBRA LATERAL PROJECTION
LUMBAR VERTEBRA OBLIQUE PROJECTIONS

Rotate body 45 degrees. Best demonstrate the scotty dog.
30˚ for L5 to S1. Best demonstrate the
A 30° rotation best zygapophyseal joint.
demonstrate the lumbosacral
processes Neck - Pars Interarticularis
A 50˚ oblique from plane of Ear - Superior articular
tabletop best visualizes the process
zygapophyseal joints at L1 to L2. Eye - Pedicle
CR perpendicular to 1-1 ½ Nose - Transverse process
inches above iliac crest (L3) Front legs - Inferior
articular process Body -
Lamina
LUMBAR VERTEBRA OBLIQUE PROJECTIONS

Posterior Oblique position Anterior Oblique position
Best visualize zygapophyseal Best visualize zygapophyseal
joint nearest to image receptor. joint farthest to image receptor
LATERAL L5 TO S1 FRANCIS METHOD
Patient in lateral position,
locate both iliac crest
Draw an imaginary line
between the interiliac plane
Adjust CR angulation to be
parallel with the interiliac line.
5°-8° caudad to 1 ½ inch
inferior to iliac crest and 1 ½
inch anterior to posterior
surface of the body.
An alternate technique to
demonstrate the L5-S1 junction
when the spine is not horizontal.
GOOD PROJECTION FOR
RULING OUT
SPONDYLOLISTHESIS.
LUMBOSACRAL JUNCTION AND SACROILIAC JOINTS AP AXIAL AND PA
AXIAL PROJECTION:
CENTRAL RAY: AP AXIAL
MALE 30˚cephalad
FEMALE 35˚cephalad at the
level of the ASIS PA AXIAL

MALE 30˚caudad

FEMALE 35˚cephalad at the
level of the ASIS Demonstrate
an open L5- S1 intervertebral
disk space.
LUMBOSACRAL JUNCTION AND SACROILIAC JOINTS AP AXIAL AND PA
AXIAL PROJECTION
5th LUMBAR PA AXIAL OBLIQUE PROJECTION KOVACS METHOD

Rotate the pelvis 30 degrees
anteriorly from the lateral
position.
CR 15-30 degrees caudad to
superior edge of the upside iliac
crest.
Best demonstrate the L5
intervertebral foramen
SACROILIAC JOINTS AP OBLIQUE PROJECTIONS:
SACROILIAC JOINTS AP OBLIQUE PROJECTIONS:
SACROILIAC JOINTS PA OBLIQUE PROJECTIONS:
PA PROJECTIONS CHAMBERLAIN METHOD
SACRUM AND COCCYX AP AND PA AXIAL PROJECTIONS
SACRUM AND COCCYX AP AND PA AXIAL PROJECTIONS
SACRUM AND COCCYX LATERAL PROJECTIONS
SACRAL VERTEBRA CANAL AND SACROILIAC JOINTS AXIAL
PROJECTION / NOLKE METHOD
LUMBAR INTERVERTEBRAL DISK; WEIGHT BEARING METHOD
SCOLIOSIS RADIOGRAPHY PA AND LATERAL PROJECTIONS
FERGUNSON METHOD
AP PROJECTION; RIGHT AND LEFT BENDING
SPINAL FUSION SERIES LATERAL PROJECTION; HYPERFLEXION AND
HYPEREXTENSION
THANK YOU FOR YOUR KIND
ATTENTION!