Computed Tomography (CT) PDF

Summary

This document provides an overview of Computed Tomography (CT), including its components, advantages, and disadvantages. It discusses different types of detectors, the role of the tube, the table, and the computer in the scanning process. It also delves into image reconstruction and manipulation. The targeted audience is most likely medical students.

Full Transcript

Oral Radiology

Computed Tomography
(CT)
OMD-725
What is the difference between Plain Radiography and
Cross sectional imaging ?
Plain radiography provide 2D image for a 3D subject
Plain radiography is subjected to superimposition
Plain radiography doesn’t demonstrate soft tissue
Plain radiography acquires data manually
 Tomography
It is a specialized technique for producing radiographs showing
only a section or slice of a patient.

Each tomograph shows the tissues within that section sharply
defined and in focus.

This is to overcome the superimposition problem found in
conventional radiography

Hence CT employ tomography & computer processing to generate
3D images from 2D images using electronic detectors.
 First CT scanner - Godfrey Hounsfield and Allan Cormack.
1971 First successful scan of a cerebral cyst
1979 Nobel Prize for Physiology and Medicine

Current technology: Multislice CT, Dual-energy CT, and Spectral CT

CT enables high resolution volumetric imaging for clinical and industrial
applications. Recently, micro-CT has become popular for non-destructive
imaging of samples at 0.5 – 150 μm spatial resolution.
COMPUTED TOMOGRAPHY (CT)
CT scanners use X-rays to
produce slices as in
conventional tomography,
but:
The radiographic film is
replaced by very sensitive
crystal or gas detectors.
The X-ray tube-head rotates
around the patient scanning
one section at a time.
 System Components
1.Computer
2.Gantry
3.Table
4.Operator’s Console
 Computer &Operator’s Console
The computer has four basic
functions:
1.Control of data acquisition
2.Image reconstruction
3.Storage of image data
4.Image display
 Gantry
Gantry is a circular device that houses the Data
Acquisition system (DAS) = Tube, Detectors, Filters,
Collimators & Analog-to-Digital Converter (ADC)
 Tube
MDCT scanners operate at high tube voltage and tube current, and thus require
special x-ray tubes to meet the high demands on heat production and cooling. MDCT
units use x-ray tubes with rotating anodes.
They typically operate at (range, 80 to 140 kVp) and at high tube currents (200 to
800 mA). {Periapical 2-12 mA}
The high x-ray output minimizes exposure time and improves image quality by
increasing the signal-to-noise ratio.
To minimize patient exposure the beam is collimated to a thin fan beam before it
enters the patient. Some of the x-ray photons interact with the patient and are
scattered. To improve image quality the residual beam is again collimated to remove
the scattered photons before it reaches the detector array.
 Detectors
Function as image receptors for remnant radiation,
then converts the measurement into an electrical
signal proportional to the radiation intensity.

Two basic detector types are used: Scintillation
(solid state) and Ionization (xenon gas) detectors.
DETECTORS
1. Scintillation Crystals:
Produce light when exposed to ionizing
radiation
Previous types had long afterglow
Now replaced with silicon photodiodes
solid state detectors eg Gadolinium
Oxysulphide with no afterglow
2. Xenon Gas Ionization Chambers
Inefficient
Long chamber sizes
Cannot be used in rotate-rotate scanners
 Table
Automated device linked to the
computer and gantry

Designed to move in increments
after every scan according to the
technologists scan program.
 Evolution of CT Scanners

First Generation Second Generation Third Generation Fourth Generation

Pencil beam Small fan beam Large fan beam Large fan beam

One detector Multiple detectors Multiple detectors Detector ring

Source and detector Source and detector Source and detector Source
Translation-Rotation Translation-Rotation Rotation-Rotation Rotation
 Source-Detector Time to acquire 1
Generation Year Why Developed Anatomy Why it died?
Movement image

1 st Gen 1971 To show CT works Head Only Translate-Rotate ~5 min Slow

2nd Gen 1974 Image Faster Head Only Translate-Rotate 20sec-2min Slow

This Geometry
3rd Gen 1975 Image Faster All Anatomy Rotate-Rotate 1 sec
won.

Make images Expensive, not
4th Gen 1976 All Anatomy Rotate-Stationary 1 sec
without rings good for scatter.

Stationary- Cardiac specific,
5th Gen 1980s Fast Cardiac CT Cardiac Only 50 ms
Stationary low x-ray flux.

In 5th generation CT the x-tube in this design is a scanning x-ray
tube, where the electrons are steered magnetically (like in old TVs)
rather than physically moving the x-ray tube. This method allows for
very fast acquisitions and is ideal for cardiac scanning. However,
these scanners did not have full volumetric coverage.
A) In First-generation CT scanners, to acquire every slice across the part of the
body, the X ray tube and detectors has to be moved linearly before rotating
the position of X ray tube to acquire images at different projection angles. It
used a pencil beam of one degree. One of the disadvantages is that scanning
time is between 25-30 mins. & resolution was very poor. The x-ray beam was
collimated at the source and at the surface of the detector to minimize scatter
radiation reaching the detector.

B) In Second-generation CT scanners, it used a narrow fan beam of 10 degrees
which results in a linear array of 30 detectors. Since it is a narrow fan beam, 2nd
generation ct scanner still requires a Translate/Rotate process. Scanning time was
improved than the first generation CT scanners. More number of detectors contributed
to a more scattered radiation. It decreased the resolution of the image.
C) In Third-generation CT scanners, both the x-ray source and the detector
array rotate around the patient in a circular path. It used a larger fan beam
of 40 – 60 degrees & Larger array of detectors (more than 800). The patient is
moved incrementally between each rotation of the source.

At the end of each revolution, the table advanced
through the gantry, while the x-ray tube-detector
assembly returned to its original position to unwind
the attached wiring that supplied power and
transferred data from the detector to the computer.
D) In Fourth-generation CT scanners, the x-ray tube
rotates around the patient, and the remnant beam
is detected by a fixed circular array. to overcome
detector drift (ring artifact in third generation). One of
the disadvantage of 4th generation ct scanner is the
lesser usage of detectors, only 1/4th of detectors are in
use at a single time. Stationary detector requires a
larger acceptance angle for radiation, therefore it is
more sensitive to scattered radiation than third
generation CT scanners.
The table movement through the gantry, typically 1 to 5 mm, positioned the
patient for imaging of the next slice. CT scanners that use this type of “step and
shoot” movement for image acquisition are called incremental scanners. The
final image set consists of a series of spaced or overlapping images in the axial
plane.
In the early 1990s, Helical (Spiral) CT imaging was introduced. In helical scanners,
the patient is moved continuously through the gantry, and the x-ray source moves
continuously around the patient in a circle.
This was due to the use of “slip-ring”
technology that eliminated the need for
directed wired connections to the moving
x-ray tube and detector. Markedly
decreased scan time. In CT scanners,
the x-ray source emits a collimated fan
beam.
Multislice CT (MSCT)
One problem quickly encountered with single slice (single detector row) helical scanning (SSCT) was
excess stress on the x ray tube. That is, the x ray tube would heat to extreme temperatures as very high
energy was deposited onto the anode. This problem limited the ability to perform thin slice imaging
necessary for acceptable imaging.
The primary difference is SSCT uses a one dimensional detector
arrangement where many individual detector elements are arranged
in a single row. In MSCT, each detector in a single row is long enough
in the slice thickness direction (z axis). Each individual detector in
each row is then divided into multiple detector elements forming a
two-dimensional array. By increasing the number of detector rows,
the z axis coverage slab thickness increases thereby decreasing the
number of gantry rotations necessary to image the selected field of
view (scan length), theoretically reducing the strain on the x ray tube.
Multi-detector CT (MDCT), also referred to as multi-slice CT (MSCT), was
introduced in the late 1990s and has now become the most widely used CT
scanner design across the world.

(MDCT) array having 64 to 128 rows (could reach up to 640). In these scanners,
all parts of the detector array arc are equidistant from the x-ray source. It has
considerably reduced scan times, limiting motion artifact from breathing or heart
contractions
Third Generation Multidetector Helical CT
(multi-slice/ multirow CT)

In multi-detector CT, the gantry contains up to 256
rows of detectors instead of just one raw.
Third Generation Multidetector Helical CT
Advantages

– Less exposure time
– Less motion artifact from breathing,
peristalsis or heart contractions; this is
important for patients who cannot
hold their breath for long periods and
for pediatric and trauma patients.
– Better quality of axial, reformatted,
and three-dimensional images
Third Generation Multidetector Helical CT
Disadvantages

– Higher patient dose than single-
slice scanners.
Equipment and Theory
The circular gantry houses
the X-ray tube-head and the
detectors.
The patient lies down with
the part of the body to be
examined within the gantry.
The level and thickness of
the section to be imaged are
selected.
Equipment and Theory
The X-ray tube-head rotates around
the patient scanning that section.
Each set of detectors produces an
attenuation or penetration profile.
The computer calculates the
absorption at points on a matrix
formed by the intersection of all the
attenuation profiles.
 Each point on the matrix is called a pixel
Typical matrix sizes are 512 X 512 or
1024 X 1024 pixels.
Smaller pixel size = greater image resolution
The area being imaged by each pixel has a
definite volume, depending on the thickness
of the slice, called a voxel.
COMPUTED TOMOGRAPHY (CT)
 Matrix : is array of numbers arranged
in a rows and columns.

 Pixel : is a single square, or picture
element, within the matrix.

 Voxel: is the depth or the volume of
pixels
 Each voxel is given a CT number or
Hounsfield unit between
+ 1000 and -1000, depending on the
amount of absorption within that block
of tissue.
Air: -1000 (Black)
Water: 0
Dense bone: +1000 (White)

Each CT number is assigned a
different degree of grayness, forming
a visual image which is displayed on
a television screen.
- 1000 +1000

+800

- 600
 Image
manipulation

Window level Window width
The CT n° selected for the The range selected for the
center of the range, various shades of grey,
Depending on whether the A narrow range allows
lesion under investigation is subtle differences between
in soft tissue or bone. very similar tissues to be
detected.
 Image manipulation
Bone window
Soft tissue window
Image manipulation
2. Image Reconstruction

The information obtained from the original axial scan can be
manipulated by the computer to reconstruct:
Coronal cuts
Sagittal cuts
Cuts in any other plane
3-dimensional images.
Axial cut
Coronal cut
Indications of CT
Intracranial disease
Bony fractures
Developmental
Anomalies
Sinuses
Oroantral fistula
Cysts
Follicular cyst maxilla
Benign Tumours
Malignant Tumours
Infection

sequestrum
Salivary Gland Lesions
 Preoperative assessment of
alveolar bone height and thickness
before inserting implants
CT guided biopsy
 Advantages over Conventional Film-based
Tomography
Very small amounts, and differences, in X-ray absorption
can be detected.
This enables:
Detailed imaging of intracranial lesions
Imaging of hard and soft tissues
Excellent differentiation between different types of tissues,
both normal and diseased
 Advantages over Conventional Film-based
Tomography
Images can be manipulated
Axial and coronal tomographic sections of the skulls are
obtainable
Reconstructed images can be obtained from information
obtained in the axial plane
Images can be enhanced by the use of IV contrast media
providing additional information.
 Disadvantages
The equipment is very expensive
Facilities are not widely available
High dose of radiation
Risks associated with IV contrast agents.
Metallic objects, such as fillings may
produce marked streak or star artifacts
Disadvantages

 Metal streaking artifacts occur because
of the near-complete absorption of x-ray
photons by metallic restorations. They
appear as opaque streaks in the occlusal
plane
Ring artifacts: are a CT phenomenon that occurs due to the miscalibration or
failure of one or more detector elements in a CT scanner. Less often, it can be
caused by insufficient radiation dose or contrast material contamination of the
detector cover.
Partial Volume Artifact: when a single voxel represents tissues of differing densities
(e.g., bone and soft tissue), the resulting CT number for that voxel is an intermediate
value that does not accurately represent either tissue. This artifact will occur when the
object being imaged is smaller than the size of an individual reconstructed voxel.
Beam-Hardening Artifact: manifest as dark streaks
between two highly attenuating structures, such as
compact bone, dental implants, and dental
restorations.
 Dual Energy CT Scan
A dual energy CT (DECT) scanner is fairly new technology
that uses both the normal X-ray and also a second less
powerful X-ray to make the images. This gives DECT
additional advantages over standard CT for a wide range of
tests and procedures
 Dual Energy CT Scan
It can selectively increase or decrease the effects of some chemical substances in
the body, making some abnormalities clearer on the images taken; for example,
iodine is a commonly used substance in X-ray contrast agents, and DECT can
selectively increase its effects to produce better images of blood vessels (CT
angiography)
Images with and without contrast agents can be obtained using a single examination
instead of two separate examinations.
It can detect particular substances in the body that can be useful for patients with
kidney stones to see what type of stone is present and assist in deciding the type of
treatment required
It can significantly improve image quality if patients have metal in the area being
scanned, specially with metal artifact reduction software (MARS)
 Faculty of
Dentistry