Diagnostic Imaging Modalities of Medical Imaging Session 1.pptx.pdf

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MODALITIES OF MEDICAL IMAGING

Radiography
 LECTURE OBJECTIVES

Discriminate between the image generation process in Radiography, CT, Molecular Imaging
(Nuclear Medicine/PET), MRI, and Ultrasound
Define terminology used to describe the appearance of the different densities when
interpreting the following imaging studies: Radiographs, CT, MRI, Ultrasound, and Nuclear
Medicine/PET
Describe the preferred clinical indications for selecting the following imaging studies as
well as their strengths and weaknesses: Radiographs, CT, MRI, Ultrasound, and Nuclear
Medicine/PET
Distinguish between the most common contrast materials used in radiology and describe
their indications/ contraindications
Considerations when ordering imaging studies

Radiography
 Question 1

Mr. Smith is a 65-year-old male with a past medical history of
hypertension, presents to the ER complaining of shortness of breath and
chest pain which started while gardening. Which of the following is the
initial study of choice?
a. CT of chest
b. MRI of chest
c. Chest Radiograph
d. Nuclear medicine V/Q scan
e. Ultrasound of the heart (Echocardiogram)

Radiography
 Question 2.

A 45-year-old male status post high-speed MVA involving blunt
trauma to the chest complains of chest pain and hemoptysis.
Which of the following is the modality of choice?
a. CT of chest
b. MRI of chest
c. Chest Radiograph
d. Nuclear medicine V/Q scan
e. Ultrasound of the heart (Echocardiogram)

Radiography
Question 3. Which of the following is the normal
image?
a. Image #1
B. Image #2

#1
#2

Radiography
 Image contrast
The difference in brightness between an area of interest and its
surroundings.
The larger the difference in brightness between different tissue
types, the easier it is to differentiate them from each other.

Radiography
 Artifacts and Interfaces

An artifact is an imaging finding that does not directly
correspond to the reality of the patient
May mimic a clinical feature, degrade image quality, or
obscure anatomy.
Radiological interfaces are between different radiodensities
The border of the heart against the lung

Radiography
 PLANAR VERSUS CROSS-SECTIONAL IMAGING

Planar images are shadows of complex three-dimensional objects e.g.
radiography
Cross-sectional images show the three-dimensional reality of anatomy e.g.
CT, ultrasound, and MRI.

Radiography
CATEGORIES

Radiating imaging Modalities (use ionizing radiation to produce
an image)
Radiography
Fluoroscopy
Mammography
Computed Tomography (CT)
Nuclear Medicine
Positron (positive electron) Emission Tomography (PET)

Non-radiating imaging Modalities (do not use ionizing radiation to
produce an image)
Magnetic Resonance Imaging (MRI)
Ultrasonography
Radiography
 Radiating Testing
Modalities that use
X-rays
RADIOGRAPHY
COMPUTED TOMOGRAPHY (CT)

Radiography
RADIOGRAPHY

Radiography
 RADIOGRAPHY

https://www.merckmanuals.com/home/sp
ecial-subjects/common-imaging-tests/plain
-x-rays#
Roentgen discovered x-rays in 1895.
Referred to as x-ray, plain film, radiograph,
and conventional radiograph
Radiography refers to the medical images
that are the “shadows” projected onto a
flat plane (planar) when x-rays pass
through a patient.

Radiography
 Five Basic Densities Seen on
Conventional Radiography

Radiography
Radiography
Radiopaque- Denser structures block x-rays better, appear white
on radiograph
Radiolucent- Less dense structures allow x-rays to pass through,
appear gray to black on radiograph.

Radiography
 INDICATIONS
Lung pathologies- Pneumonia, lung nodules, pneumothorax,
COPD (chest film)
Chest pain- aortic dissection, cardiomegaly and other findings
may be seen on plain film (chest radiograph)
Abdominal processes- pneumoperitoneum, obstruction, other
causes of acute abdomen.
You may need to use oral contrast when imaging the
abdomen.
C-spine- initial screen for fracture/injury that may threaten the
spinal cord

Bone and joint problems- fractures, deformities, infections,
neoplasms, cartilage loss, derangement.
radiographs remain the entrance-point for virtually all bone
and joint assessments.
Radiography
RADIOGRAPHY

Strengths Weaknesses
Inexpensive Poor differentiation between
different soft tissues
Portable
2D image of a 3D object (frontal
Low amount of ionizing radiation
& lateral views needed)
to patient
Good contrast between bone,
soft tissue, lung and air (in two
dimensions)
Contrast may be used to outline
hollow viscera (gastrointestinal
tract, urinary tract)

Radiography
 FLUOROSCOPY
An application of projectional radiography that allows real-time
observation
The digital images are displayed on a television monitor and are
recorded as a movie clip or as a series of images
Uses:
Barium X-rays and enemas (to view the gastrointestinal tract)
Catheter insertion and manipulation (to direct the movement of a
catheter through blood vessels, bile ducts or the urinary system)
Placement of devices within the body, such as stents (to open
narrowed or blocked blood vessels)
Angiograms (to visualize blood vessels and organs)
Orthopedic surgery (to guide joint replacements and treatment of
fractures)
https://www.merckmanuals.com/home/multimedia/video/barium-sw
allow-fluoroscopy

Fluoroscopy
 MAMMOGRAPHY
A mammographic unit is installed with a special x-ray tube and a plastic
breast-compression device.
Only method of screening for breast cancer shown to decrease mortality.
Digital breast tomosynthesis (DBT)
also referred to as three-dimensional (3D) mammography
allows the breast to be viewed in a 3D format as multiple thin-slice images
spanning the entire breast.

MAMMOGRAPHY
MAMMOGRAPHY
IMAGES

MAMMOGRAPHY
COMPUTED
TOMOGRAPHY
COMPUTED TOMOGRAPHY

https://www.merckmanuals.com/home/multimedia/video/computed-tomo
graphy-ct-scan
An x-ray beam that rotates along a 360°circle circular pattern with
detectors rotating along the opposite side
CT descriptors are “high attenuation” (radiodense or whiter) and
“low attenuation” (radiolucent or blacker)
CT images are viewed in sequential anatomic order, examining each
slice with reference to slices above and below.

COMPUTED TOMOGRAPHY
 CT VIEWS AND CT WINDOWS

The appearance of CT images depends on the window and level set by
user.
By “altering the window settings” within the same area being scanned
different details can be seen.

COMPUTED TOMOGRAPHY
CT RECONSTRUCTION IMAGES
3D Surface Rendering- Useful for evaluating 3D Volume Rendering-A method for
bone surfaces and surfaces of tubular displaying the anatomy in a life-like, Dynamic contrast-enhanced (multi-phase) CT-
structures three-dimensional format. Most commonly used in liver, adrenal, and
pancreatic imaging, as well as CT
arteriography and venography.

MIP of Aorta - maximum intensity projection is very CT Angiography- makes use of
useful in evaluating the vasculature precise contrast timing to image
vascular anatomy

COMPUTED TOMOGRAPHY
CT INDICATIONS
Bone: useful for characterization of fractures or other local
changes in bone such as neoplasm or infection
Anything well-calcified: such as lung nodules
Blood: in trauma situations when acute hemorrhage is
suspected.
Head injury or possible hemorrhagic stroke patients, for
example, can get rapid assessment for intracranial bleeding
with non-contrast CT.
Chest and Abdomen: useful for visualizing internal organs (with
and/or without contrast)
Pelvis: Pelvic fractures/trauma (which are often acute
emergencies) usually best seen on CT-which will depict not just
bone but all the tissues, structures, and organ systems (GI, GU,
neurovascular..) involved.
Usually not used first in children/young adults due to risk of
radiation to reproductive organs. Consider ultrasound or MRI as
initial
COMPUTEDimaging
TOMOGRAPHY alternatives with no radiation risk.
 COMPUTED TOMOGRAPHY

Strengths Weaknesses
Speed: The ability to provide very rapid Relatively high amount of ionizing radiation
acquisition of images with a large area of per scan – 10-100 times more radiation than
coverage in patients with severe/multisystem conventional x-rays
acute trauma. Subject to artifacts due to patient
movement
Contrast resolution between different tissues:
Allows for superior evaluation of abnormalities Hazards of IV contrast materials
involving hemorrhage, calcium, or gas. Cannot be done at the bedside therefore
Post-processing: The ability to obtain not for patients who have
reformations in multiple planes unstable vital signs
are in traction
in spinal immobilization frames
cannot leave the floor for other reasons.

COMPUTED TOMOGRAPHY
NUCLEAR (MOLECULAR) MEDICINE
MOLECULAR IMAGING:
NUCLEAR MEDICINE

The only imaging technique entirely dependent on
contrast agents
Uses radioactive compounds called
radiopharmaceuticals or radiotracers
After the radiopharmaceutical is carried to a tissue
or organ in the body, usually via the bloodstream,
its radioactive emissions allow it to be measured
and imaged with a detection device called
a gamma camera.
Provide targeted therapy for a variety of diseases
(Radiotherapy).

NUCLEAR (MOLECULAR) MEDICINE
 NUCLEAR MEDICINE

Single photon emission computed tomography
(SPECT) imaging
Acquires many 2D images from multiple angles, which
are then reconstructed by computer into a 3D data
set that can be manipulated to demonstrate thin slices
in any projection.

NUCLEAR (MOLECULAR) MEDICINE
POSITRON EMISSION TOMOGRAPHY
(PET) SCANS

Operate on a molecular level to produce 3D images that depict the
body's biochemical and metabolic processes.
The most commonly used target molecule in PET scanning is an analog
of glucose called fluorodeoxyglucose (FDG).
Most often used in the diagnosis and treatment follow-up of cancer.

Radiography
Videos

https://www.youtube.com/watch?v=U0SZHGfP_1A
https://www.youtube.com/watch?v=TresR2wSw40

NUCLEAR (MOLECULAR) MEDICINE
FUSION IMAGING
Fusion imaging combines anatomic
images with metabolic function
images.
PET scanning can be used in
conjunction with a CT scan
to give a more accurate
localization of an abnormality or
lesion for surgery or biopsy, or to
identify suspected metastasis.
increased specificity and sensitivity
in the cardiac, neural, and
oncological identification of
abnormalities.

NUCLEAR (MOLECULAR) MEDICINE
MOLECULAR IMAGING

Strengths Weaknesses
Highly sensitive Non-specific
Functional and anatomical Uses ionizing radiation
information
Cost of equipment
Extra care in handling of
radioactive material

NUCLEAR (MOLECULAR) MEDICINE
Non-radiating imaging
Modalities

MAGNETIC RESONANCE IMAGING (MRI)
ULTRASONOGRAPHY
 MAGNETIC RESONANCE IMAGING

https://www.youtube.com/watch?v=FvOe
zMIL9BU

Patient is placed inside the gantry of an
MRI Machine with a strong magnetic field
Hydrogen protons inside the body (act as
tiny magnets) will align in the same
direction as the main magnetic field.
Depending on the composition/pathology
of the tissue, these protons relaxes at
different speed.
MR signal is captured and processed by
the computer to form the image.
High quality cross-sectional images (in any
plane)

MAGNETIC RESONANCE IMAGING
 TISSUE DENSITIES
Compact bone and air appear black on all sequences as no
signal is emitted
Proton density-
Brighter area- the greater the concentration of
hydrogen protons.
Darker the area - the fewer the number of hydrogen
protons.
T1 weighting-
fatty tissues appear bright (adipose, yellow marrow,
CNS white matter)
T2 weighting-
fluids appear bright (CSF, mucus, urine, bile, edema
and non-clotted blood)

MAGNETIC RESONANCE IMAGING
 MRI INDICATIONS
Brain tumors or ischemic stokes
Tumors more visible with gadolinium
Any soft tissue pathology-
ligament or meniscal tears in the knee,
spinal disc herniation,
nerve root impingement,
bone marrow changes
Pelvic imaging (both because of the lack of radiation exposure to
reproductive organs and because of good soft tissue discrimination)-
uterine fibroids
MRI angiograms can be useful in the study of coronary or cerebral
vasculature
MAGNETIC RESONANCE IMAGING
 MRI

Strengths Weaknesses
Machines are more expensive than CT
Superb contrast between different soft Some patients are unable to have MRI due to :
tissues
claustrophobia
Lack of artifact from adjacent bone
presence of sensitive equipment
Higher resolution than CT
Internal (implanted) defibrillator or
Highlights pathological changes pacemaker.

No ionizing radiation Cochlear (ear) implant.

3D data acquisition/multiplanar Surgical clips such as those used on brain
aneurysms.
May be fused with CT scans Artificial heart valves.
Implanted drug infusion ports.
Artificial limbs or metallic joints.
Implanted nerve stimulators.
Pins, screws, plates, stents or surgical staples.
Reduced sensitivity for small calcification and
acute hemorrhage
MAGNETIC RESONANCE IMAGING
MAGNETIC RESONANCE IMAGING
ULTRASONOGRAPHY
A signal generator is combined with a
transducer.
Piezoelectric crystals in the signal generator
convert electricity into high-frequency sound
waves, which are sent into tissues.
The tissues scatter, reflect, and absorb the
sound waves to various degrees.
The sound waves that are reflected back
(echoes) are converted into electric signals.
A computer analyzes the signals and displays
an anatomic image on a screen.
The machine displays the distances and
intensities of the echoes on the screen,
forming a 2D image.
The body surface that is scanned may be:
External
transabdominal sonography
Internal
transvaginal, transrectal, and
transesophageal

ULTRASONOGRAPHY
IMAGING PLANES

Refers to adjustment in the direction of
the probe
The sagittal or longitudinal
plane is viewed with the patient's head
toward the left and feet toward the right
The transverse plane is conventionally
viewed with the patient's right on your
left side and the patient's left on your
right side

ULTRASONOGRAPHY
ULTRASOUND
INTERPRETATION
Echogenicity of the tissue - the ability to reflect or transmit
us waves in the context of surrounding tissues.
Bones, fat and stones
Bones, fat and stones produce
a hyperechoic signal.
A hyperechoic signal is bright as most ultrasound
waves are reflected.
Cartilage and muscle
Cartilage and muscle produce a hypoechoic signal.
A hypoechoic signal appears dark as most waves
pass through the tissue.
Fluid and fluid-filled structures
Fluid and fluid-filled structures produce
an anechoic signal.
An anechoic signal appears black as there is no
reflection of ultrasound waves.

ULTRASONOGRAPHY
US ARTIFACTS ARE DIAGNOSTICALLY
USEFUL:
ACOUSTIC SHADOWING
When a hypoechoic area is
located behind a hyperechoic structure
ACOUSTIC ENHANCEMENT

When structures located behind fluid
and homogeneous tissues generally
appear brighter (whiter) than other
structures
typical feature of cysts and
homogeneous solid masses, such as
lymphomas.

ULTRASONOGRAPHY
DOPPLER SONOGRAPHY
Provides valuable information regarding the presence, direction,
and velocity of blood flow.

DOPPLER DISPLAYS:

Color Doppler

Velocity and direction are color-coded.

The color above the black bar - flow toward the Doppler
beam

The color below the black bar - flow away from the Doppler
beam.

By convention flow within arteries are red and veins are blue

The brighter colors correspond to higher mean velocities and
the darker colors indicate lower mean velocities.

Doppler spectral

velocity is plotted on the vertical scale (y axis) and time is
plotted on the horizontal scale (x axis).

The directions towards the transducer is above the baseline
and the direction away from the transducer is below the
baseline

Doppler Sonography
ULTRASOUND IMAGING: CAROTID ARTERY

Doppler imaging looks at artery
This is a healthy artery.
The flow is smooth and all in the
same direction, like water in a
large, slow river

This is also a carotid artery.
The flow is not all in the same direction.
It is turbulent, like rapids in a river.
This is usually due to a build-up of fatty
deposits in the artery

Doppler Sonography
CLINICAL INDICATIONS US

Gynecologic exams- the lack of radiation makes ultrasound one of the most
frequently used imaging tests in both pregnancy and other gynecologic exams
Echocardiography- this very common test used to detect wall motion abnormalities in
the heart is actually a form of ultrasound.
Abdominal exams- useful to examine for cysts, bleeding, or inflammation of organs.
Checking for deep venous thromboses in the extremities, especially proximally;
Doppler effects can be used to assess volume, speed, and direction of flow
Using Doppler ultrasound to examine the severity of carotid artery blockage
Procedures- to guide procedures like biopsies, line placements, and
thoracentesis/paracentesis (removing excess fluid from the thorax or
abdomen without injuring other structures).
Examining breast masses to further distinguish cyst/fluid from focal fat or tissue
Focused assessment with sonography for trauma (FAST) –for evaluation of the
torso for free fluid suggesting injury to the peritoneal, pericardial, and pleural
cavities, particularly in cases of trauma.

SONOGRAPHY
ULTRASOUND

Strengths Weaknesses
Lack of ionizing radiation Cannot penetrate gas or bone so
lesions within/behind/ above
Low cost
cannot be visualized
Portability
Obese patients may be difficult to
Lack of use of contrast penetrate
Dependent on the skills of the
operator scanning

SONOGRAPHY
CONTRAST AGENTS
 CONTRAST AGENTS FOR
RADIOGRAPHY AND CT
To distinguish adjacent tissues in imaging, the tissues must have different
densities.
An oral or IV administration of a contrast agent is often used to create a
temporary, artificial density difference between objects.
Intravascular iodinated contrast material excreted through the renal
system
In patients with normal renal function, the kidneys eliminate almost all the
contrast agent.
The half-time in patients with normal renal function is 1 to 2 hours,
compared with 2 to 4 hours in dialysis patients.

CONTRAST AGENTS
 CONTRAST REACTIONS

Contrast reactions can be anaphylactoid or chemotoxic reactions.
Reactions may be:
Minor- heat sensation, nausea, and mild urticaria.
Intermediate- vasovagal reaction, bronchospasm, and generalized urticaria
Severe- profound hypotension, pulmonary edema, and cardiac arrest
In patients with a history of contrast allergy, pretreatment on re-exposure is usually
recommended.
Various protocols are used but typically include antihistamines and corticosteroids.

CONTRAST AGENTS
 MAGNETIC RESONANCE CONTRAST AGENTS

The two classes of MRI contrast agents are diffusion and non-diffusion agents.
Diffusion agents, with appropriate timing of imaging sequences, can delineate
vessels as well as parenchymal tissues.
Non-diffusion agents remain in the bloodstream and are primarily useful for MRA.
All the contrast agents are based on the paramagnetic properties of gadolinium.
Minor reactions such as headache and nausea occur in 3% to 5% of patients
In patients with renal impairment, a rare severe reaction, nephrogenic systemic fibrosis
(NSF), has been described
The most recent guidelines gadolinium is contraindicated in patients with AKI and in
those with chronic kidney disease stages 4 and 5 (i.e., GFR