Skull Radiography Lecture Notes PDF

Summary

These lecture notes provide an overview of skull radiography, covering the relevant anatomy, landmarks, equipment, and indications for this specialized imaging technique. The document also discusses various positioning techniques and image quality guidelines.

Full Transcript

**SKULL RADIOGRAPHY**

In order to produce high-quality Image of the skull and minimize risk
for the patient, the radiographer must have a good understanding of the
relevant anatomy, positioning landmarks and equipment used for imaging.
This should be coupled with an ability to assess the patient\'s
condition and thus apply the correct technique in any given situation

Skull films are recognized to be among the most difficult to interpret
due to the complexity of the bony construction (numerous bones joined by
sutures) and arterial and venous markings in the diploe, all of which
may mimic fracture. Anteriorly, the complex facial skeleton is
superimposed over the lower part of the skull vault; the dense petrous
temporal bone also obscures detail. Fractures of the skull base are
important because of the risk of cerebrospinal fluid (CSF) leak and
spread of infection to the intracranial contents, but they are hard to
demonstrate due to the thin, flat nature of the bones and
superimposition of the facial skeleton and petrous bone.

Superimposition of other unwanted structures, including ponytails, hair
clips, and hair matted with blood, can cause confusion. Surgical clips
used for wound closure should not cause confusion, and they may help by
marking the site of injury.

INDICATIONS FOR SKULL X RAY

1. Trauma

2. Birth defects,

3. Infection,

Fforeign bodies,

4. Pituitary tumors, and

5. Certain metabolic and endocrine disorders that cause bone defects of
the skull

6. Seizure

7. Infertility

Radiographic anatomical terms

All radiography of the skull is undertaken with reference to a series of
palpable landmarks and recognized lines or planes of the skull. It is
vital that the radiographer possesses a good understanding of these
before undertaking any positioning

Landmarks

1.  Outer canthus of the eye: the point where the upper and lower
eyelids meet laterally.

2. Infra-orbital margin/point: the inferior rim of the orbit, with the
point being located at its lowest point.

3.  Nasion: the articulation between the nasal and frontal bones.

4.  Glabella: a bony prominence found on the frontal bone immediately
superior to the nasion.

5. Vertex: the highest point of the skull in the median sagittal plane.

6. External occipital protuberance (inion): a bony prominence found on
the occipital bone, usually coincident with the median sagittal
plane.

7. External auditory meatus: the opening within the ear that leads into
the external auditory canal.

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Lines

1. Inter-orbital (inter-pupillary) line: joins the centre of the two
orbits or the centre of the two pupils when the eyes are looking
straight forward.

2. Infra-orbital line: joints the two infra-orbital points.

3. Anthropological baseline: passes from the infra-orbital point to the
upper border of the external auditory meatus (also known as the
Frankfurter line).

4. Orbito-meatal base line (radiographic baseline): extends from the
outer canthus of the eye to the centre of the external auditory
meatus. This line is angled approximately 10 degrees to the
anthropological baseline.

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Planes

1.  Median sagittal plane: divides the skull into right and left
halves. Landmarks on this plane are the nasion anteriorly and the
external occipital protuberance (inion) posteriorly.

2. Coronal planes: these are at right-angles to the median sagittal
plane and divide the head into anterior and posterior parts

3.  Anthropological plane: a horizontal plane containing the two
anthropological baselines and the infra-orbital line. It is an
example of an axial plane. Axial planes are parallel with this
plane.

4. Auricular plane: perpendicular to the anthropological plane. Passes
through the centre of the two external auditory meatuses. It is an
example of a coronal plane.

5. The median sagittal, anthropological and coronal planes are mutually
at right-angles.

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Equipment

Radiography of the skull can be carried out using a specialized skull
unit, or with an ordinary Bucky, or simply with a stationary grid and
tube. Each method has specific advantages and disadvantages in any given
situation.

Images taken on skull units yield the highest-quality skull images. All
aspects of tube and tube support design have been optimized for skull
radiography. Their use is to be recommended when undertaking skull
radiography, provided that the patient\'s condition will allow them to
be moved on to the table.

Advantages of skull units

1.  reduction in distortion;

2.  high-resolution images resulting from a grid with a large number of
gridlines per unit length (grid lattice) and very fine focal spot on
the tube anode (typically 0.3-0.4 mm^2^);

3.  projections that are accurate and consistent as the patient is
placed in one or a limited number of positions and the tube is then
positioned around the head once this position is achieved;

4. it can be more comfortable for the patient, as only one position has
to be achieved;

5. purpose-designed circular collimators allow close collimation to the
head, reducing the dose and minimizing secondary radiation.

Disadvantages include:

1.  the table on which the patient lies is often quite narrow and
difficult to get on to; this may make it unsuitable for patients who
are unable to cooperate, since they may fall off;

2. most units are accompanied by their own technique manual requiring
the radiographer to acquire a set of skills unique to one piece of
equipment;

3. units are expensive

4.  units can be lacking in versatility for sick patients and patients
with conditions such as thoracic kyphosis.

Types of skull unit include the following:

 Isocentric skull unit: this is the most widely available unit and will
produce the highest-quality images. This is achieved by the design of
the equipment, which ensures that the image-receptor plate and primary
beam are always perpendicular to each other, thus eliminating
distortion. Note that the point around which the tube pivots is always
adjusted so that it is at the centre of the object of interest. The
technique used by each manufacturer will vary slightly, but all use the
anthropological baseline rather than the radiographic baseline when
describing projections.

 Lysholm skull unit: this differs from the isocentric skull unit in
that the point around which the tube pivots is always in the same plane
as the film. This has the potential to produce distorted images if large
angulations are used. The techniques used to operate these units are
very similar to those for skull radiography carried out with a simple
tube and Bucky and utilize the radiographic baseline when describing
techniques. This type of skull unit is not used widely in modern imaging
departments.

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Isocentric skull unit

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Lysholm skull unit

Positioning Tips

To describe a skull projection, it is necessary to state the following

1. The relative positions of the skull planes to the image receptor

2. The central ray relative to skull planes/image receptor

3. A centring point or area to be included within the beam.

Beam angulation

Many occipto-frontal and front-occipital projections will require the
central ray to pass along the sagittal plane at some angle to the
orbital-meatal plane. In these cases, the degree of angulation is stated
after the name of the projection. The direction of angulation is also
given. Caudo-cranial angulation (usually shortened to cranial
angulation) involves the beam pointing up the body towards the head
(written in short form as Î). If the beam is angled towards the feet,
the beam is then said to be angled cranio-caudally (usually shortened to
caudal angulation, and written in short form as J-).

The photograph below shows a fronto-occipital 30-degree caudal
projection (FO30° J-).

Occipito-frontal projections

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Projections in which the central ray is parallel to the sagittal plane
are named according to the direction of the central ray. In the
photograph above, the central ray enters the skull through the occipital
bone and exits through the frontal bone. This is therefore an
occipto-frontal (OF) projection.

Fronto-occipital projections

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Again, the central ray is parallel to the sagittal plane, except that
the central ray now enters the skull through the frontal bone and exits
through the occipital bone. This is a fronto-occipital (FO) projection.

Lateral

For the lateral projection, the central ray passes along a coronal plane
at right-angles to the median sagittal plane. It is named according to
the side of the head nearer to the image receptor. In the example below,
the beam enters the head on the left side, passes along a coronal plane,
and exits the head on the right side, where the image receptor is
located. This is, therefore, a right lateral.

![C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
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Lateral with angulation

If the central ray passes along a coronal plane at some angle to the
median sagittal plane, then the degree of angulation is stated. The
photograph below shows a right lateral with 30-degree caudal angulation
(R Lat 30°i).

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Oblique projections

As can be seen in the photograph, an oblique projection is obtained when
the central ray is at some angle to the median sagittal plane and the
coronal plane. How the projection is named will depend on two factors:
first whether the anterior or posterior portion of the head is in
contact with the cassette and second whether the left or right side of
the head is in contact with the cassette.

Forty-degree left anterior oblique

In this example, the head is rotated to the right, such that the median
sagittal plane is at 40 degrees to the cassette and the left side of the
head is in contact with the cassette (40°LAO).

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The photograph below shows how the same projection has been achieved
with a combination of tube and orbital-meatal plane angulation. In this
case, the plane has been raised 20 degrees and the tube has been given a
15-degree caudal angulation, in effect producing a total beam angulation
of 35 degrees to the orbital-meatal plane.

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Warning

When undertaking oblique skull radiography, always ensure that the beam
is angled in the same direction as the grid lattice, i.e. parallel to
the grid lines. If any angulation is applied such that beam is angled
across the grid lines, i.e. perpendicular to their direction of travel,
then a grid cut-off artefact will result and the image will need to be
repeated.

Patient preparation

Before undertaking skull radiography, the following specific
considerations should be made:

1.  Ensure that all metal objects are removed from the patient, e.g.
hair clips and hairpins.

2. Bunches of hair often produce artefacts and thus should be untied

3. If the area of interest includes the mouth, then false teeth
containing metal and metal dental bridges should be removed.

4. The patient should be provided with a clear explanation of any
movements and film positions associated with the normal operation of
the skull unit.

Useful accessories

1. The usefulness of foam pads as an aid to immobilization cannot be
overstated. The photograph opposite shows a specially designed pad
for skull radiography. It is available in a range of sizes to
accommodate different age gro

2.  Forty-five-degree triangular pads are extremely useful for
immobilizing children. They can be held by the parent and support
the head without the parent placing their hands in the primary beam.

3. Individual side markers are essential for skull radiography, as the
clip-type side markers are easily lost in the collimation,
particularly when using a skull unit.

4. Velcro straps are of great use when immobilizing a patient on a
skull unit.

General image quality guidelines and radiation protection considerations

The European Guidelines on Quality Criteria for Diagnostic Images
describe various criteria by which images should be assessed. Many of
these criteria are included with the specific projection descriptions
and in the introduction to this chapter, but some more general points
and other considerations are included below:

1. Images should have a visually sharp reproduction of all structures,
such as outer and inner lamina of the cranial vault, the trabecular
structure of the cranium, the various sinuses and sutures where
visible, vascular channels, petrous part of the temporal bone and
the pituitary fossa.

2. Important image details should be in the 0.3-0.5 mm range.

3.  A 400 (regular) speed imaging system is recommended (regular
conventional film/screen combination).

4. Use 70-85 kV tube voltage.

5. Whenever possible, use an occipito-frontal (postero-anterior) rather
than a fronto-occipital (antero-posterior) technique, since this
vastly reduces the dose to the eyes.

6. 24 X 30-cm cassettes are generally used for plain skull radiography.

![C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
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Patient immobilized using Velcro straps

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Immobilization pads used in skull radiography

![C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
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Immobilization of a child using 45-degree foam pads

**Skull Technique**

Non-isocentric skull technique should be undertaken when there is no
isocentric skull unit available or the patient's condition will not
allow them to be transferred on to the skull unit table. Images are
acquired using a 24 X 30-cm cassette. Grid cassettes are used when it is
impossible to use a Bucky grid system.

**Lateral (Supine)**

**Position of patient and cassette**

1. The patient lies supine, with the head raised and immobilized on a
non-opaque skull pad. This will ensure that the occipital region is
included on the final image.

2. The head is adjusted, such that the median sagittal plane is
perpendicular to the table/trolley and the interorbital line is
perpendicular to the cassette.

3. Support the grid cassette vertically against the lateral aspect of
the head parallel to the median sagittal plane, with its long edge 5
cm above the vertex of the skull.

4. Use a pad that ensures the head is raised far enough from the table/
trolley surface.

5. This is the projection of choice for the majority of trauma cases on
a trolley.

**Direction and centering of the X-ray beam**

1. The horizontal central ray is directed parallel to the interorbital
line, such that it is at right-angles to the median sagittal plane.

2.  Centre midway between the glabella and the external occipital
protuberance to a point approximately 5 cm superior to the external
auditory meatus.

3. The long axis of the cassette should be coincident with the long
axis of the skull.

**Image features**

1. The image should contain all of the cranial bones and the first
cervical vertebra.

2. The clinoid processes of the sella turcica should also be
superimposed~ ~ 

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**Lateral - erect**

This position may be used for a cooperative patient. Variations from the
supine horizontal beam technique are noted below, but all other imaging
criteria remain the same.

**Position of patient and cassette**

1. The patient sits facing the erect Bucky and the head is then
rotated, such that the median sagittal plane is parallel to the
Bucky and the inter-orbital line is perpendicular to it.

2. The shoulders may be rotated slightly to allow the correct position
to be attained. The patient may grip the Bucky for stability.

3. Position the cassette transversely in the erect Bucky, such that its
upper border is 5 cm above the vertex of the skull.

4. A radiolucent pad may be placed under the chin for support.

**Direction and centering of the X-ray beam**

1. The X-ray tube should have been centred previously to the Bucky.

2. Adjust the height of the Bucky/tube so that the patient is
comfortable (NB: do not decentre the tube from the Bucky at this
point).

3. Centre midway between the glabella and the external occipital
protuberance to a point approximately 5 cm superior to the external
auditory meatus.

4. Check the position of all planes immediately before exposure, as the
patient probably will have moved.

**Important Notes**

1. This projection can also be performed with the patient prone on a
floating-top table.

2. The projection may be performed usefully on babies in the supine
position, with the head rotated to either side.

3.  An air/fluid level in the sphenoid sinus (an indicator for a
base-of-skull fracture) will not be visible if the patient is imaged
with a vertical central ray. This is not relevant in young babies,
as the sinus is not developed fully.

**Occipito-frontal-OF**

Occipito-frontal projections can be employed with different degrees of
beam angulation. The choice of projection will depend upon departmental
protocol and the anatomy that needs to be demonstrated.

**Position of patient and cassette**

1. This projection may be undertaken erect or in the prone position.
The erect projection will be described, as the prone projection is
uncomfortable for the patient and will usually be carried out only
in the absence of a vertical Bucky.

2. The patient is seated facing the erect Bucky, so that the median
sagittal plane is coincident with the midline of the Bucky and is
also perpendicular to it.

3. The neck is flexed so that the orbito-meatal base line is
perpendicular to the Bucky. This can usually be achieved by ensuring
that the nose and forehead are in contact with the Bucky.

4. Ensure that the mid-part of the frontal bone is positioned in the
centre of the Bucky.

5. The patient may place the palms of each hand either side of the head
(out of the primary beam) for stability.

6. 24 X 30-cm cassette is placed longitudinally in the Bucky tray.
Ensure that the lead name blocker will not interfere with the final
image.

**Direction and centring of the X-ray beam**

1. The central ray is directed perpendicular to the Bucky along the
median sagittal plane.

2. A collimation field should be set to include the vertex of the skull
superiorly, the region immediately below the base of the occipital
bone inferiorly, and the lateral skin margins.

3. It is important to ensure that the tube is centred to the middle of
the Bucky.

4. Centre 2.5cm below the inion

**Exposure factors and FFD**

75KVP, 20mAs, 100cm

**Occipito-frontal caudal angulation**:

10, 15 and 20 degrees

~ ~ The technique used for these three projections is similar to that
employed for the occipito-frontal projection, except that a caudal
angulation is applied. The degree of angulation will depend on the
technique, e.g. for an OF20°i projection, a 20-degree caudal angulation
will be employed.

~ ~ Ensure that the central ray is always centred to the middle of the
Bucky once the tube angulation has been applied and not before.

Essential image characteristics

 All the cranial bones should be included within the image, including
the skin margins.

 It is important to ensure that the skull is not rotated. This can be
assessed by measuring the distance from a point in the midline of the
skull to the lateral margin. If this is the same on both sides of the
skull, then it is not rotated.

![C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
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Positioning for occipito-frontal skull projection

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Positioning for OF10° skull projection


Positioning for OF20° skull projection

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Alternative positioning for OF20°4 using a straight tube with the
orbito-meatal baseline raised 20 degrees

![C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
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**Image appearance of different OF caudal angulations**

The degree of beam angulation can be evaluated from an assessment of the
position of the petrous ridges within the orbit:

\- Occipito-frontal: the petrous ridges should be completely
superimposed within the orbit, with their upper borders coincident with
the upper third of the orbit.

\- OF10°i: the petrous ridges appear in the middle third of the orbit.

\- OF15°i: the petrous ridges appear in the lower third of the orbit.

\- OF20°i: the petrous ridges appear just below the inferior orbital
margin.

**Note**

As the beam angle increases, more of the orbital region is demonstrated
and less of the upper part of the frontal bone anterior parietal bones
is shown. Thus, the site of the suspected pathology should be considered
when selecting the beam angle, e.g. an injury to the upper orbital
region is best evaluated with an OF20°i projection.

**Common faults and remedies**

1. Rotation: ensure that the patient\'s head is straight immediately
before the exposure is made.

2. Incorrect beam angulation: it is worth remembering that greater beam
angulations will result in the petrous ridges appearing further down
the orbit. If an OF20°i is undertaken and the petrous bones appear
in the middle third of the orbit, then a greater angle should have
been applied, in this case a further 10 degrees.

**Notes: alternative technique**

 Patients often find it difficult to maintain their orbito-meatal
baseline perpendicular to the film, as this is an unnatural position and
they are likely to move.

~ ~ Instead of angling the beam to achieve the desired position of the
petrous ridge within the orbit, a vertical central ray, i.e.
perpendicular to the film, can be used. The desired angulation for the
projection can then be achieved by raising the orbito-meatal baseline by
the desired angle, e.g. for an OF20°i, the chin can be raised such that
the orbito-meatal baseline will be at an angle of 20 degrees to the
horizontal (see photograph). Similarly, for an OF10°i, the orbito-meatal
line will be raised by 10 degrees.

**Fronto-occipital**

Fronto-occipital projections of the skull will demonstrate the same
anatomy as occipito-frontal projections. The orbits and frontal bone,
however, will be magnified, since they are positioned further from the
image receptor.

Such projections should be carried out only when the patient cannot be
moved and must be imaged supine. These projections result in increased
eye dose and loss of resolution of anterior skull structures due to
increased object-to-film distance (OFD).

Position of patient and cassette

1. The patient lies supine on a trolley or Bucky table, or with the
posterior aspect of the skull resting on a grid cassette.

2. The head is adjusted to bring the median sagittal plane at right-
angles to the film and coincident with its midline. In this
position, the external auditory meatuses are equidistant from the
cassette.

3. The orbito-meatal baseline should be perpendicular to the cassette.

**Direction and centring of the X-ray beam**

All angulations for fronto-occipital projections are made cranially.

1. The central ray is directed perpendicular to the cassette or Bucky
along the median sagittal plane 

2. A collimation field should be set to include the vertex of the skull
superiorly, the base of the occipital bone inferiorly, and the
lateral skin margins. It is important to ensure that all of the tube
is centred to the middle of the Bucky.

**Technical factors**

- centering point. the central ray is centered at the glabella

- collimation. laterally to include soft tissue. superiorly soft
tissue.

- orientation. portrait.

- detector size. 24 cm x 30 cm.

- exposure. 75 kVp. 8-10 mAs.

- FFD. 100 cm.

- grid. yes.

**Fronto-occipital CRANIAL angulation:**

**10, 15 and 20 degrees**

1. The technique used for these three projections is similar to that
employed for the occipito-frontal, except that a cranial angulation
is applied. The degree of angulation will depend on the projection
required.

2. Remember that the cassette or Bucky must be displaced superiorly to
allow for the tube angulation, otherwise the area of interest will
be projected off the film. For a 20-degree angle, the top of the
cassette will need to be 5 cm above the skull vertex.

3. Remember that increasing the degree of cranial angulation will
project the petrous ridges further down the orbits.

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**Half-axial, fronto-occipital 30 degrees caudad - Towne\'s projection**

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FO 30°T \'Towne\'s projection\'

**Position of patient and cassette**

1. The patient lies supine on a trolley or Bucky table, with the
posterior aspect of the skull resting on a grid cassette.

2. The head is adjusted to bring the median sagittal plane at right-
angles to the cassette and so it is coincident with its midline.

3. The orbito-meatal base line should be perpendicular to the film.

**Direction and centring of the X-ray beam**

1. The central ray is angled caudally so it makes an angle of 30
degrees to the orbito-meatal plane.

2. Centre in the midline such that the beam passes midway between the
external auditory meatuses. This is to a point approximately 5 cm
above the glabella.

3. The top of the cassette should be positioned adjacent to the vertex
of the skull to ensure that the beam angulation does not project the
area of interest off the bottom of the image.

4. If the patient\'s chin cannot be depressed sufficiently to bring the
orbito-meatal baseline perpendicular to the film, then it will be
necessary to increase the angle of the tube more than 30 degrees to
the vertical.

**Image features**

1. The sella turcica of the sphenoid bone is projected within the
foramen magnum.

2. The image must include all of the occipital bone and the posterior
parts of the parietal bone, and the lambdoidal suture should be
visualized clearly.

3. The skull should not be rotated. This can also be assessed by
ensuring that the sella turcica appears in the middle of the foramen
magnum.

**Reverse Towne\'s**

![C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
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Reverse Towne\'s, alternative positioning

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Under angled Towne\'s

Occipito-frontal 30-degree cranial angulation - reverse
Towne\'s projection

**Position of patient and cassette**

1. This projection is usually undertaken with the patient in the erect
position and facing the erect Bucky, although it may be performed
prone.

2. Initially, the patient is asked to place their nose and forehead on
the Bucky table. The head is adjusted to bring the median sagittal
plane at right-angles to the cassette and so it is coincident with
its midline.

3. The orbito-meatal baseline should be perpendicular to the cassette.

4. The patient may place their hands on the Bucky for stability.

**Direction and centring of the X-ray beam**

1. The central ray is angled cranially so its makes an angle of 30
degrees to the orbito-meatal plane.

2. Adjust the collimation field, such that the whole of the occipital
bone and the parietal bones up to the vertex are included within the
field. Avoid including the eyes in the primary beam. Laterally, the
skin margins should also be included within the field.

**Image features**

1. The sella turcica of the sphenoid bone is projected within the
foramen magnum.

2. The image must include all of the occipital bone and the posterior
parts of the parietal bone, and the lambdoidal suture should be
visualized clearly.

3. The skull should not be rotated. This can also be assessed by
ensuring that the sella turcica appears in the middle of the foramen
magnum.

**Notes**

1. This projection will carry a lower radiation dose to sensitive
structures than the equivalent antero-posterior projection

2.  Positioning may be easier to undertake on patients who find it
difficult to achieve the position required for the equivalent
antero-posterior half-axial projections.

**SUBMENTO-VERTICAL**

**Position of patient and cassette**

The patient may be imaged erect or supine. If the patient is unsteady,
then a supine technique is advisable.

**Supine**

1. The patient\'s shoulders are raised and the neck is hyperextended to
bring the vertex of the skull in contact with the grid cassette or
table.

2. The head is adjusted to bring the external auditory meatuses
equidistant from the cassette.

3. The median sagittal plane should be at right-angles to the cassette
along its midline.

4. The orbito-meatal plane should be as near as possible parallel to
the cassette.

**Erect**

1. The patient sits a short distance away from a vertical Bucky.

2. The neck is hyperextended to allow the head to fall back until the
vertex of the skull makes contact with the centre of the vertical
Bucky.

3. The remainder of the positioning is as described for the supine
technique.

**Direction and centring of the X-ray beam**

 The central ray is directed at right-angles to the orbito-meatal plane
and centred midway between the external auditory meatuses.

Important image features

1. A correct projection will show the angles of the mandible clear of
the petrous portions of the temporal bone.

2. The foramina of the middle cranial fossa should be seen
symmetrically either side of the midline.

**Notes**

~ ~ This projection involves positioning that is very uncomfortable for
the patient. It is well worth ensuring that the equipment is prepared
fully before commencing the examination, so that the patient need
maintain the position for only a minimum period.

 The position is achieved much more easily if a skull unit is used,
since the object table and tube can be adjusted to minimize
hyperextension of the neck.

![C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
Radiography - by A. S. Whitley\_files\\image092.jpg](media/image34.jpeg)

Submento-vertical (SMV) using skull unit

**SELLA TURCICA: LATERAL**

**Position of patient and cassette**

1. The patient sits facing the erect Bucky and the head is then
rotated, such that the median sagittal plane is parallel to the
Bucky and the inter-orbital line is perpendicular to the Bucky.

2. The shoulders may be rotated slightly to allow the correct position
to be attained. The patient may grip the Bucky for stability.

3. The head and Bucky heights are adjusted so that the centre of the
Bucky is 2.5 cm vertically above a point 2.5 cm along the baseline
from the external auditory meatus

4. A radiolucent pad may be placed under the chin and face for support.

**Direction and centring of the X-ray beam**

 A well-collimated beam is centred to a point 2.5 cm vertically above a
point 2.5 cm along the baseline from the auditory meatus nearer the
X-ray tube..

**OPTIC FORAMINA AND JUGULAR FORAMINA**

The main indication for imaging these foramina is detection of tumour
(e.g. glomus jugulare tumour, optic nerve glioma), which currently
requires imaging by CT and/or MRI for full evaluation.

**Optic foramina: postero-anterior oblique**

The optic canal opens into the rear of the bony orbit at the optic
foramen. The canal passes forwards and laterally at approximately 35
degrees to the median sagittal plane and downwards at approximately 35
degrees to the orbito-meatal plane. This is the path that the central
ray must take to demonstrate the foramen.

Both sides are usually imaged separately for comparison by undertaking
postero-anterior oblique projections of the cranium.

**Position of patient and cassette**

1. The patient lies prone or, more commonly, erect with the nose, cheek
and chin of the side being examined in contact with the Bucky or
cassette table.

2.  The centre of the orbit of the side under examination should
coincide with the centre of the Bucky or cassette table.

3. The median sagittal plane is adjusted to make an angle of 35 degrees
to the vertical (55 degrees to the table).

4. The orbito-meatal base line is raised 35 degrees from the
horizontal.

**Direction and centring of the X-ray beam**

With the beam collimated well, the horizontal central ray should be
centred to the middle of the Bucky.

This is to a point 7.5 cm above and 7.5 cm behind the uppermost external
auditory meatus, so that the central ray emerges from the centre of the
orbit in contact with the table.

~ ~ A small lead side-marker can be placed above the superior orbital
margin.

![C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
Radiography - by A. S. Whitley\_files\\image094.jpg](media/image36.jpeg)

C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
Radiography - by A. S. Whitley\_files\\image095.jpg

![C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
Radiography - by A. S. Whitley\_files\\image096.jpg](media/image38.jpeg)

C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
Radiography - by A. S. Whitley\_files\\image097.jpg

![C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
Radiography - by A. S. Whitley\_files\\image098.jpg](media/image40.jpeg)

**JUGULAR FORAMINA: SUBMENTO-VERTICAL**

**20 degrees caudad**

The jugular foramina lie in the posterior cranial fossa between the
petrous temporal and occipital bones on each side of the foramen magnum.
Both sides are imaged simultaneously on a single image by undertaking a
submento-vertical (SMV) 20 degrees caudad projection.

**Position of patient and cassette**

 As per the SMV projection described previously

**Direction and centring of the X-ray beam**

~ ~ Using a well-collimated beam, the central ray is angled caudally so
that it makes an angle of 70 degrees to the orbito- meatal plane and
centred in the midline to pass midway between the external auditory
meatuses.

Notes: alternative technique

 With the patient\'s neck less extended, the head can be positioned
with the orbito-meatal plane at an angle of 20 degrees to the Bucky, in
which case a horizontal central ray will make the required angle of 70
degrees to the base plane

C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
Radiography - by A. S. Whitley\_files\\image099.jpg

Temporal bones

These projections are traditionally difficult to perform. They are also
difficult to interpret, especially if the examination is not of the
highest quality. Modern CT with direct coronal imaging affords exquisite
demonstration of temporal bone detail and has largely obviated the need
for these projections.

Frontal-occipital 35 degrees caudad

Position of patient and cassette

 The patient may be supine in the midline of the table or erect with
their back to an erect Bucky.

~ ~ The head is adjusted to bring the external auditory meatuses
equidistant from the table, so that the median sagittal plane is at
right-angles to, and in the midline of, the table.

~ ~ The chin is depressed so that the orbito-meatal line is at
right-angles to the table.

 A small (24 X 30-cm) cassette is placed transversely in the cassette
tray and is centred to coincide with the angled central ray.

Direction and centring of the X-ray beam

~ ~ A caudal angulation is employed, such that it makes an angle of 35
degrees to the orbito-meatal plane.

~ ~ The beam is centred midway between the external auditory meatuses.

~ ~ Collimate laterally to include the lateral margins of the skull and
supra-inferiorly to include the mastoid and petrous parts of the
temporal bone. The mastoid process can be palpated easily behind the
ear.

![C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
Radiography - by A. S. Whitley\_files\\image100.jpg](media/image42.jpeg)

C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
Radiography - by A. S. Whitley\_files\\image101.jpg

![C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
Radiography - by A. S. Whitley\_files\\image102.jpg](media/image44.jpeg)

C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
Radiography - by A. S. Whitley\_files\\image103.jpg

Patient positioned for SMV projection

Frontal-occipital 35 degrees caudad

Essential image characteristics

 The sella turcica of the sphenoid bone should be projected within the
foramen magnum.

 The skull should not be rotated. This can also be assessed by ensuring
that the sella turcica appears in the middle of the foramen magnum.

~ ~ All of the anatomy included on the radiograph opposite and line
diagram below should be included.

Common faults and remedies

~ ~ Under-angulation: the foramen magnum is not demonstrated clearly
above the petrous ridges. This is probably the most common fault, since
the patient may find it difficult to maintain the baseline perpendicular
to the film.

 If the patient's chin cannot be depressed sufficiently to bring the
orbito-meatal base line perpendicular to the film, then it will be
necessary to increase the angle of the tube more than 35 degrees to the
vertical. A 35-degree angle to the orbito-meatal plane must be
maintained.

Submento-vertical

As an alternative, an SMV projection (see p. 246 for details) collimated
down to include only the petrous and mastoid parts of the temporal bone
is a further projection that has been employed to demonstrate the
anatomy of this region.

![C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
Radiography - by A. S. Whitley\_files\\image104.jpg](media/image46.jpeg)

Mastoid - lateral oblique

25 degrees caudad

Position of patient and cassette

 The patient sits facing the erect Bucky. The head is then rotated,
such that the median sagittal plane is parallel to the Bucky and the
inter-orbital line is perpendicular to the Bucky.

 The shoulders may be rotated slightly to allow the correct position to
be attained. The patient may grip the Bucky for stability.

~ ~ The auricle of the ear adjacent to the table is folded forward to
ensure that its soft-tissue outline is not superimposed over the region
of interest.

 Position the mastoid process in the middle of the Bucky.

 An 18 X 24-cm cassette is positioned longitudinally in the Bucky and
is centred to coincide with the central ray and mastoid process.

Direction and centring of the X-ray beam

 A 25-degree caudal angulation is employed and centred 5 cm above and
2.5 cm behind the external auditory meatus remote from the cassette.

 Collimate to the area under examination.

Essential image characteristics

 Ensure that all of the mastoid air cells have been included within the
image. The size of these structures can vary greatly from individual to
individual.

Common faults and remedies

 Failure to centre far enough posteriorly might exclude part of the
mastoid air cells from the image if these structures are very well
developed.

 Failure to ensure that the auricle of the ear is folded forward will
result in a soft-tissue artefact. Check that the ear is in the correct
position just before the exposure is undertaken.

Note

Examine both sides for comparison.

C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
Radiography - by A. S. Whitley\_files\\image105.jpg

![C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
Radiography - by A. S. Whitley\_files\\image106.jpg](media/image48.jpeg)

C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
Radiography - by A. S. Whitley\_files\\image107.jpg

![C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
Radiography - by A. S. Whitley\_files\\image108.jpg](media/image50.jpeg)

C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
Radiography - by A. S. Whitley\_files\\image109.jpg

Mastoid - profile

Position of patient and cassette

 The patient lies supine on the table, with the orbito-meatal baseline
perpendicular to the table top.

 From a position with the median sagittal plane perpendicular to the
table, the head is rotated through an angle of 35 degrees away from the
side under examination, such that the median sagittal plane now makes an
angle of 55 degrees to the table.

~ ~ The vertical tangent to the skull should now be at the level of the
middle of the mastoid process under examination, so that the mastoid
process is in profile.

~ ~ Finally, the head is moved transversely across the table so that the
mastoid process being examined is in the midline of the table.

Direction and centring of the X-ray beam

~ ~ The central ray is angled caudally so that it makes an angle of 25
degrees to the orbito-meatal plane and is centred to the middle of the
mastoid process on the side under examination.

 Collimate tightly around the mastoid process.

Notes

~ ~ Both sides are often imaged for comparison.

~ ~ A small lead side-marker should be included within the collimation
field.

Petrous bone: anterior oblique (Stenver's)

Position of patient and cassette

 The patient may be prone or may be more comfortable being examined
erect and facing a vertical Bucky.

 The middle of the supra-orbital margin on the side being examined is
centred to the middle of the Bucky.

 The neck is flexed so that the nose and forehead are in contact with
the table and the orbito-meatal line is perpendicular to the table.

 From a position where the median sagittal plane is perpendicular to
the table, the head is rotated toward the side under examination, such
that the median sagittal plane is now at an angle of 45 degrees to the
table. This brings the petrous part of the temporal bone parallel to the
cassette.

~ ~ The neck is extended so that the orbito-meatal line is raised five
degrees from horizontal.

 An 18 X 24-cm cassette is placed transversely in the Bucky and is
centred at a level to coincide with the central ray.

Direction and centring of the X-ray beam

 A 12-degree cephalad beam angulation is employed, i.e. at an angle of
seven degrees to the orbito-meatal plane, to separate the occiput from
the petrous bone.

~ ~ Centre midway between the external occipital protuberance and the
external auditory meatus furthest from the cassette.

~ ~ Collimate to the mastoid and petrous parts of the temporal bone
under examination.

Note

This projection is now more or less redundant due to the superior
diagnostic capabilities of CT.

![C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
Radiography - by A. S. Whitley\_files\\image110.jpg](media/image52.jpeg)

C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
Radiography - by A. S. Whitley\_files\\image111.jpg

![C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
Radiography - by A. S. Whitley\_files\\image112.jpg](media/image54.jpeg)

C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
Radiography - by A. S. Whitley\_files\\image113.jpg

![C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
Radiography - by A. S. Whitley\_files\\image114.jpg](media/image56.jpeg)

Cranium: Isocentric skull technique

Introduction

The use of the isocentric technique offers considerable advantages over
the techniques described previously and will produce images of much
higher quality than those produced with just a tube and Bucky or
stationary grid. The reasons for this are as follows:

 The central ray and cassette are always perpendicular to each other,
thus eliminating distortion.

 The patient is always supine, thus increasing comfort and efficiency
of immobilization.

 The patient\'s head needs to be placed in only one or a limited number
of positions. Positioning is then achieved by moving only the skull
unit. Again, this increases patient comfort.

 Skull unit movements are very precise and the constant position of the
patient\'s head facilitates accurate corrections to inadequately
positioned radiographs.

 It is easier to reproduce images when follow-up projections are
requested or to correct errors if an image needs to be repeated.

The Orbix skull unit is one of the most widely used skull units, and the
descriptions of technique that follow will be based on this unit. Other
manufacturers produce units with slightly different designs, and the
reader is advised to consult the handbook supplied with the individual
unit. It is worth noting, however, that many of the basic principles
used in positioning are very similar, regardless of which unit is
employed.

C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
Radiography - by A. S. Whitley\_files\\image115.jpg

![C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
Radiography - by A. S. Whitley\_files\\image116.jpg](media/image58.jpeg)

Basic principles of use

All positioning and tube movement is described using the following
planes and lines:

~ ~ median sagittal plane;

~ ~ anthropological plane;

~ ~ anthropological baseline;

~ ~ auricular plane.

As can be seen from the pictures opposite, the skull unit consists of a
tube and cassette holder mounted on an arm (known as the tube arm). This
is attached via another arm, which is fastened to the ceiling (the
ceiling arm). The table upon which the patient rests can also be moved,
allowing a third plane of movement.

An imaginary pivot point about which the tube arm and ceiling arm rotate
is known as the isocentre. When positioning, the height of the tube arm
and the patient table are arranged in such a way that the isocentre sits
in the middle of the anatomical area of interest. The isocentre will
then remain in this position, regardless of what angulation is applied
to either the tube or the ceiling arm.

Basic position

One of the advantages of isocentric skull radiography is that the
positioning for the various projections undertaken is achieved from one
starting position. This is known as the basic position. Once this has
been achieved, the patient will remain stationary and the desired
projection can be achieved simply by moving the tube arm, ceiling arm
and table.

To achieve the basic position, the various tube arm and table movements
are used in conjunction with the unit-centring lights to achieve the
following:

 The patient lies supine on the skull unit table, with the vertex of
the skull close to the top of the table. The median sagittal plane
should approximate to the middle of the table. The head should rest on a
dedicated foam pad skull support.

~ ~ Both the tube arm and the ceiling arm are positioned by the side of
the patient, such that they are perpendicular to the median sagittal
plane (see photograph). The tube arm angulation should be set to zero.

 The table is moved so that the patient's median sagittal plane is
coincident with the vertical line of the cross of positioning light on
the light beam diaphragm (A on photograph).

 The patient's infra-orbital plane should be perpendicular to the
tabletop and will coincide with the vertical beam of the cross light
found on the axis of the tube arm. It may be necessary to move the table
along its longitudinal axis in order to achieve this. Immobilize with
Velcro headbands once in this position.

 The table height may have to be raised (perhaps in conjunction with
the height of the tube arm) to ensure that the centre of the cross light
found on the axis of the tube arm is positioned over the external
auditory meatus (B on the photograph). The table is usually used at its
maximum height.

 Finally, once the above position is achieved, the millimetre
positioning scales that measure table movements should be set to zero.

Once the basic position has been achieved, a basic skull series can be
undertaken by making the following modifications to the basic position:

C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
Radiography - by A. S. Whitley\_files\\image117.jpg

Position of skull unit for basic position

![C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
Radiography - by A. S. Whitley\_files\\image118.jpg](media/image60.jpeg)

Positioning lights for achieving the basic position

C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
Radiography - by A. S. Whitley\_files\\image119.jpg

Positioning for occipito-frontal 20-degree projection

![C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
Radiography - by A. S. Whitley\_files\\image120.jpg](media/image62.jpeg)

Positioning for half-axial Towne\'s projection

C:\\Users\\SONY\\Downloads\\The Skull - Clark\'s Positioning In
Radiography - by A. S. Whitley\_files\\image121.jpg

Positioning for lateral projection

Occipito-frontal projection

 From the basic position the table is moved down 40-60 mm (depending on
the head size) along its longitudinal axis, such that the positions of
cross lights on the light beam diaphragm move superiorly in relation to
the patient\'s head.

 Confine the beam to the size of the head using the iris collimator.

 The tube is now positioned under the patient\'s head in the
postero-anterior position. To achieve this, the ceiling arm will have to
be moved so that it is parallel to the median sagittal plane. This
allows the tube arm to swing round into the correct position. Once this
has been achieved, the ceiling arm is returned to its original position
by the right side of the patient.

 A 10-degree caudal angulation will be applied for an 20- degree
occipito-frontal projection, zero-degree caudal angulation will be used
for a 10-degree occipito-frontal projection, and a 10-degree cranial
angulation will be used for an occipitofrontal projection. (Remember
that the anthropological baseline is used in isocentric skull
radiography. This is deviated from the orbito-meatal base line by 10
degrees.)

Half-axial, reverse Towne\'s

projection

~ ~ Position as above, except that a 40-degree cranial angulation is
applied with the tube arm in the postero-anterior position.

~ ~ The resulting image will be free from the distortion evident when
using non-isocentric techniques.

Lateral

 From the basic position, the table is moved down 40-60 mm (depending
on the head size) along its longitudinal axis, such that the positions
of cross lights on the light beam diaphragm move superiorly in relation
the patient\'s head.

 Swing the ceiling arm round through 90 degrees, such that it is
parallel with the median sagittal plane.

 The tube arm is now moved 90 degrees, such that the central ray will
be perpendicular to the median sagittal plane. It can be rotated in
either direction, so a left or right lateral can be obtained. It is
preferable, however, to arrange the cassette on the side of the
patient\'s head that is closest to the injury.

~ ~ Confine the beam to the size of the head using the iris collimator.

In all of the projections described, ensure that the cassette holder is
moved as close as possible to the patient\'s head before exposure. This
will minimize magnification (unless a degree of magnification is
desired).



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