Computed Tomography Scan Review 2023 PDF

Summary

This document provides an overview of computed tomography (CT) scans, including scanning procedures and data/image acquisition. It also covers the advantages of CT over traditional radiography methods. Presented are historical background and an overview of the basic principles and equipment used in this medical imaging technique.

Full Transcript

COMPUTED TOMOGRAPHY SCAN

Jenerlito R. Casaje,RRT,MPA
Radiologic Technologist V
Philippine Orthopedic Center
 TOS

* 1.1 Illustrate scanning procedure as
well as data and image acquisition in
computed tomography scan.
 Overview of the limitation of Classic
Radiography(conventional x-ray)
* Superimposition of the three
dimensional information onto
two dimension causes the loss
of low –tissue contrast
anatomic structures
* Presence of scatter obscures
low-tissue contrast anatomic
structures
 Advantages of CT over Classic Radiography

— Three dimensional
information in the form of a
series of thin slices of the
internal structures of the
part in question
 Advantages of CT over Classic Radiography
— The system is much more
sensitive compared to
conventional radiography so
that differences in tissue can be
clearly delineated(.5%-1%)
— CT measures x-ray attenuation
of individual tissues accurately,
allowing the basic nature of
tissue to be studied

region of interest
(ROI) A user-defined
graphic outline that
calculates the average
CT number of a given
anatomic area.
 Who invented CT?
* Godfrey Hounsfield
* Engineer from EMI Ltd., London
* Developed the first clinical useful CT
scanner in 1971
* Allan McLeod Cormack -South African-
born of Tufts University in Massachusetts
independently invented a similar process
* Hounsfield and Cormack shared the
1979 Nobel Prize in Medicine
* The first EMI-Scanner was installed
in Atkinson Morley
Hospital in Wimbledon, England, and the
first patient brain-scan was done on 1
October 1971
CT development
1964 EMI (England) developed the CT scanner
(by Mr.Hounsfield)
1973 EMI released MARK 1
CT development
Basic Principle of Data Acquisition
x-ray tube Parallel beam geometry
(1st generation scanner)

x-ray beam

x-ray detector

object to be
scanned
 Milestone
* 1963- Cormack contributes the first mathematical implementation
for tomographic reconstruction in South Africa
* 1969- Hounsfield shows proof of the principles with the CT scanner
based on a radioactive source at the EMI research laboratory
* 1972- Hounsfield and Ambrose publish the first clinical scan with an
EMI head scanner
* 1975- Set up of the first whole body scanner with a fan beam
system
* 1979- Hounsfield and Cormack received the Nobel prize for
medicine
* 1983- Demonstration of electron beam CT(EBCT)
* 1989- Dr. Kalender publishes the first clinical spiral CT
* 1991- Demonstration of the multi-slice CT(MSCT)
 Gen. Source Source Collimation Detector
1st Single X-ray Tube Pencil Beam Single
2nd Single X-ray Tube Fan Beam (not enough to Multiple
cover FOV)
3rd Single X-ray Tube Fan Beam (enough to Many
cover FOV)
4th Single X-ray Tube Fan Beam covers FOV Stationary Ring of
Detectors

5th Many tungsten Fan Beam Stationary
anodes in single Ring of
large tube Detectors
6th 3G/4G 3G/4G 3G/4G

7th Single X-ray Tube Cone Beam Multiple array of
Detectors
 TOS

*1.2 Show thedifference
between reconstructing and
reformatting an image.
 Reconstruction

* process of creating a digital image
from raw data
Data collection
X-ray produces “shadow-gram”
Flattens 3D information into 2D

Detector

X-ray Tube
Data collection
* X-rays produce “shadow-gram”
Data collection
The X-ray beam passes through the X-ray tube

patient
The attenuated beam is collected
by the detector
The detector converts these
attenuated X-ray photons to an
electrical signal
The signal is passed on to the data
acquisition system (DAS)
The DAS converts the signal into a
digital form. We call this raw data Detector

DAS
Raw data (projections)
The sinogram is an image representation of raw data
Raw data reconstruction
Reconstruction Fc; also known as Filter Convolution (Fc),
Kernel, filter or Algorithm
An Fc is a mathematical process used for Raw data
reconstruction
The Fc determined how the reconstructed image will
look (soft tissue, bone, lung, etc.

Raw Data
Raw data reconstruction

Raw Data
X-ray tube

Reconstruction
 Convolution filters
* Lak filter -increases amplitude
linearly as a function of frequency;
works well when there is no noise in
the data
* Shepp-Logan filter -incorporates
some roll-off at higher frequencies,
reducing high-frequency noise in
the final CT image
* Hamming filter -has even more
pronounced high-frequency roll-off, Convolution- Mathematical
with better high-frequency noise filtration used by the CT system
suppression to remove blurring artifact
during the back-projection
method of image
reconstruction.
 Bone kernels and soft tissue kernels
* Bone kernels have less high-frequency roll-off and hence
accentuate higher frequencies in the image at the expense of
increased noise(Hamming)
* For clinical applications in which high spatial resolution is less
important than high contrast resolution – for example, in
scanning for metastatic disease in the liver – soft tissue kernels
are used
* Soft tissue kernels- More roll-off at higher frequencies and
therefore produce images with reduced noise but lower spatial
resolution(Shepp-Logan)
 Multi Planar Reconstructed (MPR)
* Although diagnosis is usually made from axial
images alone, MPR or reformatting program
adds new dimension to CT imaging.
* It give different perspective of anatomy(from
axial to sagittal,coronal and even oblique)
* It is done without additional doses of
radiation
* Increased comfort to patient who cannot
assumed desired positioning
* Three dimensional MPR algorithm
* 1. MIP-maximum intensity projection-ct angio
* 2. SSD-shaded surface display
* 3. SVD- shaded volume display
Multiplanar reconstruction (MPR)
* post processing technique applied to stacks of
axial image data that can be reconstructed into
other orientations or imaging planes
 High-Resolution Ankle
Study
Axial Imaging with Multiplanar Results

Coronal Reformat

Axial Image
1 mm, Pitch 2, Emotion
Sagittal Reformat
 TOS

*1.3 Differentiate the structures
demonstrated on commonly
performed computed
tomography images
 Cerebrovascular accident
* Term used to describe stroke; no longer favored
because it implies a random, unpredictable, or
uncertain nature to the condition.
 Convolution
* Process of applying a
filter function to an
attenuation profile.
 Calcium score
* The amount of calcification on cardiac CT.
 Direct coronal
* describes position use to obtain images in
coronal plane; used for head scans to provide
images at the right angle to axial images
 High resolution scans
* use of scanning parameters that enhance
contrast resolution of an image, such as thin
slices, high matrices, high spatial frequency
algorithms and small display FOV
 TOS
*2.1 Recognize equipment and
supplies necessary to complete
commonly performed computed
tomography procedures.
 Diagnostic Applications
* Neurologic disorders
* Chest
* Abdomen
* Spine
* Musculoskeletal
* Interventional procedures:
* Abscess drainage
* Tissue biopsy
* Cyst aspiration
 Contrast media

* Its used primarily to
distinguish normal
anatomy from
pathology and to make
various diseases process
more visible
* Contrast media can be
administered
intravenously ,orally or
rectally
 IV Contrast Media
* IVU- intravenous urogram(excretory urography)
* Ionic Organic Iodide(Ionic)-High osmolality and
greater change of reaction
* Nonionic Organic Iodide(Nonionic)- Low osmolality
and less chance of reaction
* Contraindications:
* Hypersensitivity
* Anuria
* Multiple myeloma
* Diabetes mellitus
* Severe renal or hepatic disease
* Congestive heart failure
* Pheochromocytoma
* Sickle cell carcinoma
* IV Contrast media should be used only with the
approval of the radiologist and after careful
consideration of patient history
 Bolus
* preset amount of
radiopaque contrast
medium injected rapidly
per IV administration to
visualize high flow
vascular structure,
usually in conjunction
with dynamic scan; most
often injected using a
pressure injector
 Oral or Rectal Contrast Media
— Two types of contrast media for
GI tract
— Barium sulfate suspension- 1%-3%
concentration can be used for
abdominal CT(high concentration
may cause streak/beam hardening
artifacts)
— Contraindication to Barium
Sulfate(insoluble material)
— Pre-operative patient
— Patient suspected having
gastrointestinal perforation
— Bowel obstruction
— Known hypersensitivity to BaSO4
 Question
* Which of the following factors may affect a
patient’s calculated glomerular filtration rate
(GFR)?
* 1. age
* 2. sex
* 3. race
* a. 1 and 2 only
* b. 2 and 3 only
* c. 1 and 3 only
* d. 1, 2, and 3
 Answer

D. 1, 2, and 3

*GFR is calculated using the patient’s
measured serum creatinine level
and takes into account the patient’s
age, sex, and race.
 Question

* Which of the following intravenous contrast
agent administration methods provides the
greatest overall plasma iodine concentration?
* a. drip infusion
* b. bolus technique
* c. biphasic technique
* d. CT portography
 Answer
* B. bolus technique

* A bolus administration of contrast agent
requires the entire volume of material to
be injected over the shortest possible
time. Accomplished by hand or with the
use of an automatic injector, bolus
administration provides the maximum
plasma iodine concentration and
subsequent tissue enhancement.
 TOS
* 2.3 Illustrate the patient preparation
necessary for commonly performed
computed tomography contrast studies.
 Oral or Rectal Contrast Media
— Water soluble solutions (diatrizoate
meglumine and diatrizoate sodium)is an
alternative for opacification of the GI
tract
— Extreme care must be used in the
preparation of water-soluble solutions
2-5 % dilution have been found generally
safe and clinically useful (15-40%
considered hypertonic and may cause
hypovolemia)
— 20-30ml of CM to be diluted in 1,000 ml
of solution(970ml of H2O)
 TOS

* 2.2 Explain the computed tomography
acquisition protocol for commonly
performed head/neck, thorax, and
abdomen procedures.
 Head CT Scan-Protocol
— Post traumatic
abnormalities
— Suspected brain
neoplasm or masses
— Aneurysm
— Abscess
— Brain atrophy
— Brain metastasis
— Acquired or congenital
abnormalities
 Protocol for Head Trauma
— Trauma- plain study(no
contrast media required)
— Thin slices for the base of the
skull is mandatory(2/3mm)
— Two types of windows
should always be included in
filming(brain parenchyma &
bone)
— Contrast media maybe
indicated in follow-up studies
or in delayed scans
 Protocol for Stroke/CVA
* Stroke is the third leading cause of death in
the US
* Clinical Stroke Terminology
* Transient ischemic attack(TIA)- sudden
neurologic deficit persisting < 15 min. with
complete resolution by 24 hr.
* Reversible ischemic stroke(RIND)- sudden
neurologic deficit more than 24 hr. with
resolution in 3 weeks
* Completed stroke- sudden neurologic deficit
lasting more than 21 days
* CVA/ Stroke- contrast media not required
* Routine plan of head is mandatory(2/3mm
for base and 10mm for the brain)
* Bone window in not required (except for
patients who suffered head injury/trauma
due to CVA)
 Protocol for Neoplasm
* Primary CNS neoplasm are the sixth most
or Masses
common tumors in adults with an average
incidence of 5-6 per 100,000.
* Approximately 20% 0f malignant tumor diagnosed
under age 2o are brain tumors
* Key points in evaluating CT images for Neoplasm
* Lesion location and extent - intraaxial vs.
extraaxial, supratentorial vs. infratentorial, single
vs. multiple
* Tumor margin or characterization- well
circumscribed or poorly marginated,
regular or irregular, contrast Grade III astrocytoma in a 33-
enhancement(homogenous/inhomogeneous) year-old woman.
Nonenhanced studies (right)
* Mass effect- localized, focal shift/ generalized, show a mixed-attenuation
remote effects lesion (solid and cystic areas)
in the right parietal lobe with
* Edema- vasoganic, interstitial adjacent vasogenic edema.
* Brain herniation- may occur from one side to After contrast enhancement
other or from one fossa to another (left), the solid component is
enhancing.
 Protocol for Neoplasm and
Abscess
*Plain and contrast
studies is mandatory
*Routine plan of head
(2/3mm for base and
10mm for the brain)
*Brain /parenchyma
window is only
required
 Protocol for Aneurysm and AVM
* Aneurysm is an abnormal focal
enlargement of an artery
* CT is the first modality of examination that
provides an approach to selecting patients
who needs further investigation
* MRI can be performed to further
characterized the lesion
* Angiography is often necessary for the
definite examination before treatment
planning
* Plain and contrast study in most cases
* Although contrast enhancement has
allowed for the direct visualization of the
ruptured aneurysm in patients with
subarachnoid hemorrhage , most
institution would not routinely use CM.
 Protocol for Acquired or Congenital Abnormalities
* Malformation of the CNS are relatively common,
about 5-10 percent of all malformation and
approximately 1/3 of those diagnose after birth
* Encephalocele, sometimes known by the Latin
name cranium bifidum, is a neural tube defect
characterized by sac-like protrusions of the brain and
the membranes that cover it through openings in
the skull These defects are caused by failure of the
neural tube to close completely during fetal
development.
* Encephaloceles cause a groove down the middle of
the skull, or between the forehead and nose, or on
the back side of the skull. The severity of
encephalocele varies, depending on its location.
* Role of CT scan
* CT provides detail information of the bone
abnormality
* Thin slice 1-2 mm – use for image reformation
 Protocol for Intracranial Metastatic Disease

* Common Parenchymal Brain
Metastases
* Adults- Lung,Breast,
Melanoma, Genitourinary
tract, Gastrointestinal tract
* Children- Sarcomas, Germ
cell tumors, Wilms tumor,
Neuroblastoma
* Plain and contrast enhanced
study
* Brain or parenchyma
window and bone window in
filming
 Chest CT Scan
— CT of the chest serve as diagnostic
adjunct to conventional
radiography, it serves as valuable
imaging modality in the staging
and management of the previously
diagnose condition
— Mediastinal and hilar lesions
— Aneurysms
— Abscess
— Cardiac and pericardial disease
— Evaluation of pulmonary
nodules(benign/malignant)
 Protocol for Chest CT
— Contrast media is required-various
methods are used(drip
infusion/bolus injection)
— Routine 10mm slice thickness from
the apex to the costophrenic angle
— Two types of windows should
always be included in
filming(mediastinum and lung
parenchyma)
— Bone window should be added in
apparent bone lesion(metastasis)
 Abdomen CT
— Because of its speed, accuracy and
ability to diagnose abdominal
abnormalities imaging of the
abdomen significantly change.
— The use of ERCP, lymphangiography
and other imaging procedures of the
abdomen was reduced
— Any abnormalities of the abdomen
and pelvis is an indication for
Abdominal CT
— Metastatic lesion of the liver,
pancreas, kidney or spleen, adrenal
pathology
— In the region of the pelvis-prostatic,
cervix, urinary bladder and ovarian
carcinomas.
— Soft tissue masses, pelvic muscle
abscess, and evaluation of the hip
joint
 TOS
* 2.4 Distinguish the type, dosage, purpose,
and route of contrast administration for
common computed tomography
procedures.
 Protocol for Abdominal CT
— Oral Contrast media
administration and volume
— Whole abdomen-700-900ml
orally 30-45mins prior to
scan, 300ml immediately
before scan,800-1000ml
enema immediately before
scan
— Upper abdomen- 400-
600ml orally 15-30 mins
prior to scan, 300 ml
immediately before scan
 Protocol for Abdominal CT
— Planning- 10mm slice thickness is
usually required for the scanning
of the abdomen with 10 mm table
increments(can do additional thin
slices in suspected areas)
— Only one window setting is
needed in filming CT of the
abdomen(narrow scale 350-
400ww and 10-40wl)
— However in study of the pelvis
where trauma is one of the
indications, bone window using
wider window width is necessary
to evaluate presence of fracture
 Protocol for the Biliary Track
* Optimal visualization of the biliary track requires
modification of the examination technique
* Factors that can affects
* 1. The use oral and IV contrast
* Use of oral can cause steak artifact across the CBD
that can cause CBD stone
* Scanning should be performed without oral contrast
or with water to distend the stomach and the
duodenum
* The use of Glucagon to decrease peristalsis can help
to improve image quality
* When evaluating the presence of intrahepatic or CBD
stones, scans should first be obtain without IV
contrast
* 2. Axial vs. Helical scanning
* 3. Slice thickness and spacing(3-5mm)
* 4. Selection of technical factors(mA/s)
 Protocol for Pancreas(mass/pancreatitis)
* For initial study of non contrast
* Start at the bottom of the pancreas or at
the iliac crest and scan upward(5mm at 5
mm interval )
* Bolus IV injection of CM (3ml/sec)
* Oral contrast of 750-1000 ml 3% iodine
water solution
* For helical scanners:
* 30-35 sec delay for arterial phase(3-5mm)
* 70 sec total delay for venous
phase(5mm)
* For follow-up study – a routine
abdominal scan is usually adequate
* Direct contrast –starts at the top of the
liver
 Protocol for the Kidney(renal neoplasm)
* CT is currently the method of choice for
evaluation/staging suspected renal neoplasm
* Both pre-and post contrast images are mandatory
* Pre contrast – 5mm at 5mm increments
* For lesion less than 2cm in diameter 3-5mm
contiguous section should be used
* At least 30-40g of iodine(150-180ml) IV contrast
injected as bolus
* Scans are obtained 60 sec after the initiation of CM
from the diaphragm to the top of the kidney(5mm at
10mm interval an 5mm at 5mm through both
kidneys)
* Helical Mode:
* 70 sec after CM initiation- using 1 sec scan time at 1:1
pitch)
* 7mm by 7mm through the liver, 5mm by 5mm
through the kidneys
 TOS

*2.5 Assess images for positioning,
centering, appropriate anatomy and
overall image quality.
 Isocenter
* The absolute center of
the gantry
 In-plane resolution
* Resolution in the x y
direction.
 Reference detectors
* Included in the
detector array and help
to calibrate data and
reduce artifacts
 Images

* The HU value of water
is 0, the HU value of
dense bone is +1000,
and the HU value of
air is –1000
CT numbers or Hounsfield units
Isotropic voxels
Isotropic voxels

Not Isotropic Isotropic
0.98mm x 0.98mm x 5mm 0.98mm x 0.98mm x 1mm

5mm Collimation 1mm Collimation
Calibrated Field of View (C-FOV)
C-FOV: also known as the “scan FOV” (raw data)
C-FOV is determined by the collimation used to shape the beam
Only objects that reside within the C-FOV are imaged
The C-FOV should be slightly larger than the actual area of
interest

Large Small
Large C-FOV C-FOV C-FOV
Small C-FOV
Display field of view (D-FOV)

D-FOV: also known as the “reconstruction FOV” (image data)
D-FOV can be set to reconstruct anywhere and any size within
the C-FOV
Since no data exists outside of the C-FOV, no image can be
reconstructed there
The D-FOV is used to focus in on the area of interest
Large C-FOV

D-FOV
Field of view
Display (DFOV) Calibrated (CFOV)
Image Data Raw Data
CFOV

180mm SS 18cm
CFOV
240mm S 24cm
y 320mm M 32cm
DFOV
400mm L 40cm

500mm LL 50cm
 Image Display
* Each pixels is normally
represented by 12 bits or 4096
gray levels, which is larger
than the display range of the
monitors or film
* Window width and window
level are used to optimize the
appearance of CT images by
determining the contrast and
brightness levels assigned to
the CT image data
 Image Display
* Window level or center
* Is the CT number or HU value to be
displayed as the medium of intensities
in the image
* The window level is normally chosen
close to the average HU value of the
tissue of interest
(e.g. 10-50 HU for soft tissue)
* Window width
* It is the range of CT number displayed
around the selected center and
therefore determines the contrast
* A narrow window width provides
higher contrast than a wide window
width
 WW= 300
WL=0

WW=300
WL= 200
FIRST 300/2=150
SECOND 150-200=-50
THIRD 150+200=350
GRAY SCALE =-50 to 350
 TOS
* 3.1 Illustrate the technological
* advancements in computed tomography
application from single slice to helical/spiral,
multi slice, and computed tomography
angiographies
 Helical(Spiral) Scanners
* The x-ray beam central ray entering
the patient follows a helical path
during the scan
} The relationship between the patient
and tube motion is called pitch, which
is define as the table movement
during each revolution of x-ray tube
divided by the collimation
with(thickness)
} Pitch=TM/ST
} eg. For 5mm section thickness, the
patient may move 10mm during the 1
second it takes for the tube to rotate
through 360 degrees, and the pitch
would thus be equal to 2
Multi-slice Spiral CT Scanners
In multi-slice spiral CT scanners, instead of
one row set of detectors, there are multiple
rows.

Single spiral vs multislice spiral
Multi-slice

4 Slice 8 & 16 Slice 32 & 64 Slice
Z-Axis

1mm x 15 1mm x 12

0.5mm x 4 0.5mm x 16 0.5mm x 64

1mm x 15 1mm x 12

30,464 Elements 35,840 Elements 57,344 Elements
In MDCT scanners a single gantry rotation can
produce multiple slices. Therefore, MDCT
provides longer and faster z axis coverage per
gantry rotation.
MSCT Detector Configurations
 TOS
* 3.1 Illustrate the technological
* advancements in computed tomography
application from single slice to helical/spiral,
multi slice, and computed tomography
angiographies
 Bolus triggering
* Method of individualizing
the scan delay using the
contrast bolus itself to
initiate the scan. It uses a
series of low-radiation
scans to monitor the
progress of the contrast
bolus. Once an adequate
level of enhancement is
achieved, the table
moves to the starting
level and scanning
begins.
 ß-blockers
* Pharmaceuticals used
to reduce motion
artifact on cardiac CTA
images by temporarily
lowering a patient’s
heart rate
Maximum-intensity projection (MIP)
* 3D technique that
selects voxels with the
highest value to display
* reconstruction of
brightness pixels from
stack of image data
into a 3D image
 Virtual bronchoscopy
* A form of volume
rendering designed to
reveal the inside of the
airways. The technique
is also called
endoluminal imaging.
Parenchyma contrast protocol

Scan protocols must be different for best organ specific
contrast enhancement

Late
Early arterial
Arterial Venous

10s 30s 50s 70s 90s 110s

Cortico
Medullary nephrographic
Phase Phase

10s 30s 50s 70s 90s 110s

Pancreatic
Arterial Phase Venous

10s 30s 50s 70s 90s 110s
Liver Hypervascular tumor

Non contrast Early AP (20s) Late AP (35s)

Mix phase (45s) PVP (65s) Late phase (90s)
Liver Hypovascular tumor

Non contrast Early AP (20s) Late AP (35s)

Mix phase (45s) PVP (65s) Late phase (90s)
 TOS
*3.2 Apply the methods for
reducing radiation dose to the
patient and the radiologic
technologist's exposure to scatter
radiation.
 Bow tie filters
* Mechanical filter that removes soft, or
low energy, x-ray beams, minimizing
patient exposure and providing a
more uniform beam intensity
 Automatic tube current modulation
* An equipment option that will
make changes in tube current
(mA) based on the estimated
attenuation of the patient at a
specific location.
* The estimations are derived
from scout views done in both
the antero posterior and
lateral projections or from the
previous slices. From these
views, the mA will be
programmed to vary by
location along the length of
the patient. The exact details
of the option vary by
manufacturer.
 Beam pitch
* Table movement per
rotation divided by
beam width.
* The acronym CTDI is used to describe which of the
following?
* a. a specialized CT imaging technique used to
measure bone mineral density
* b. a quality control test that measures the accuracy of
the laser lighting system
* c. the radiation dose to the patient during a CT scan
* d. a high-speed CT scanner used for cardiac imaging
* C. the radiation dose to the patient during a CT scan

* The CT dose index (CTDI) is used to quantify the
radiation dose received by the patient during a CT
scan. It involves the use of an ionization chamber to
accurately measure radiation exposure for a given set
of technical factors.
 Question

* Which of the following technical factors
has a direct effect on patient dose?
* a. matrix size
* b. algorithm
* c. mAs
* d. window level
 Answer

* C. mAs

* With no consideration of image quality, reductions in
mA and/or scan time (seconds) are direct methods of
decreasing patient dose during a CT exam.
 Question

* Which of the following devices is used to
measure the patient dose from a CT
examination?
* a. Geiger counter
* b. proportional counter
* c. ionization chamber
* d. film badge
 Answer
* C. ionization chamber

* An ionization chamber is a device used to
accurately measure radiation exposure.
Radiation causes ionization within the
chamber, which is measured by an
electrode.
* The amount of charged particles is
proportional to the radiation exposure. The
ionization chamber is an extremely accurate
device that is used to quantify radiation
exposure from a CT scan.
Thank You