Radiology Midterm

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Definition of electomagnetic radiation: The propagation of energy thru space as oscillating electromagnetic fields.
Physical characteristics of EM radiation: No mass
No charge
Travels a speed of light
Types of EM radiation: radio waves
infrared
visible light
UV light
x-rays
γ-rays
Differences between types of EM radiation: All same speed.
Differ in wavelength/frequency.
x-rays/γ-rays=shortest wavelengths,
radio waves=longest wavelength
Speed of light (defined by wavelength): c= wavelength/frequency
Energy as related to wavelength: E α 1/wavelength
as wavelength increases, energy decreases
Origin of x-rays: from outside the nucleus by interactions between high speed particles
Origin of γ-rays: from inside the nucleus of spontaneously decaying atoms
Parts of basic x-ray tube: Filament
Target
Glass tube
Anode
Cathode
Filament: thin coiled wire that serves as the source of electrons
made of Tungsten
Part of the Cathode assembly
Thermionic Emission: Forcing a low voltage current through the filament (against its resistance) generates heat.
Heat results in the release of free electrons.
Focusing cup: Negatively charged cup surrounging the filament, prevents generated electrons from dispersing
Voltage (potential difference): Negative cathode-positive anode
Pulls and accelerates electrons away from filament, towards target
Voltage used for diagnostic procedures: 40-140 kVp
Kilovolts peak
Voltage used for therapeutic procedures: 1-4 MV (megavolt)
Target: Part of the anode.
Contains the focal spot
Focal Spot: Area of the target where the actual interactions that produce the x-rays occurs
Housing: the glass/pyrex tube that holds the vacuum.
Surrounded by a lead shield.
Purpose of the vacuum: Prevents electrons from interacting with atoms in the air.
Window: a small port in the lead shielding that allows the "useful beam" to escape
Types of interactions: Transition
Bremsstrahlung
Transition interactions: Characteristic
x-rays in a very specific energy range
Brehsstrahlung interactions: General
X-rays in a broad range of energies
Efficiency of x-ray production: very inefficient
99% of incoming electron energy is converted to heat, only 1% is converted to useable x-rays
Effective focal spot: The apparent size of the focal spot from patients point of view
Effect of increasing the size of focal spot: greater output capability,
greater heat dissipation
Effect of decreasing the size of the focal spot: greater detail of image,
done by making angle of target steeper
Two type of anodes: Stationary
Rotating
Uses of stationary anode: Portable diagnostic equipment
Therapy (when auxillary cooling is incorporated)
Limitations of stationary anode: Lower output, due to limited ability to dissipate heat
Uses of rotating anode: Fixed diagnostics
Special procedures
Low portability/portability-when greater output in required
Value of a rotating anode: Greater output capability, due to increased ability to dissipate heat
Filaments of rotating anode systems: most have two filaments
one for large focal spot, the other for small focal spot
Quantity of x-rays: = # x-rays in the beam
Quality of x-rays: = energy of x-rays in the beam
Characteristics of x-ray quality: Penetrability-higher quality=higher energy=more penetrability
Control of x-ray quality: Controlled by the kVp of the instrument
Control of x-ray quantity: Controlled by kVp-energy of electrons in the beam=amount of interactions
and mA-current in milliamps=rate of electron emissions
mAs: Current * exposure time
influences the quantity of electrons in the beam
kVp: controls tube voltage
influences the quality (mainly) & the quantity
Target loading chart: Chart used for older equiment to ensure you don't damage the tube by using settings that are too high
x-ray filters: a sheet of aluminum/copper placed between the x-ray tube and the collimator
Purpose of x-ray filters: Lower radiation exposure of the patient since low energy x-rays would otherwise be absorbed by the patient
Function of x-ray filters: To selectively remove low energy x-rays from the primary beam
Collimator: adjusted the size of the x-ray field
Function of the collimator: limit the x-ray field to only the areas of interest.
Enhance image quality by absorbing scatter radiation
Proper collimation: Should have a white border around x-ray field.
Limits the radiation exposure to patient & holder
Function of Grids: Reduce the amount of scatter radiation striking the x-ray film.
Compton Scattering: Most important form of scatter radiation.
Caused by a primary x-ray photon hitting a dislodging a electron in the patient, turning it into a secondary x-ray, which strikes film randomly
Effect of scatter radiation: Produces fog= a decrease in image quality, overall grayness to the film
Factors affecting amount of scatter radiation: tissue density
total volume being x-rayed
-field size
-thickness of patient
As each increases scatter increases.
kVp
Grids: Plates with alternating lead & aluminum strips. 80-160 strips/inch
Focused Grids: Strips are angles to match the angle of the primary beam.
Need to increase mAs when using, b/c not absorbed
Grid ratio: "One of the most important factor when buying."
Ratio=height of strip:distance between them
Most 8:1/10:1
Advantages of higher grid ratio: â†‘ grid ratio=â†‘image quality
Removes more scatter
Disadvantages of higher grid ratio: â†‘grid ratio=â†‘ absorption of primary beam as well.
Have to use higher mAs.
Much more expensive.
Bucky tray: Device in tables that shakes the grid during exposure.
â†‘ image quality, by blurring gridlines
Types of grid cutoff artifacts: Lateral decentering
Angled
Upside-down
Cause underexposure of film
Lateral decentering: Most common cutoff
Focused Grid is not centered, so angle of strips doesn't match angle of beam.
Causes general underexposure, with apparent gridlines
Angled grid artifact: Caused by grid being tilted, relative to beam/film.
Common in Large animal.
Severe underexposure, â†‘gridlines seen
Upside-down grid artifact: caused by=== upside-down grid
completely absorbs beam, except in very center
X-ray film emulsion: A gelatin mixture with silver halide crystals
1 layer in ultrasound
both sides coated in diagnostics
Conversion of silver halide to image: Crystals absorb energy (x-ray or light), release photoelectrons, which are caught by silver ions-converted to metallic silver during development
Function of intensifying screens: intensify x-rays that hit it, allowing for lower radiation use.
Actually responsible for most of the film exposure that occurs
Types of intensifying screens: Fast
Detail
How intensifying screens work: contain light-emitting phosphors in plastic support.
When an x-ray hit it releases a burst of light that exposes the film.
Fast screens: thick phosphor layer
larger phosphor crystals
for short exposure, lower detail, used for LA films
Detail screens: Thin phosphor layer
smaller phosphor crystals
much greater detail, but need higher mAs.
Used for head/extremity films
Intensifying screen artifacts: Screen craze
Screen dirt
Different color of screens for color sensitive film: Blue-sensitive=Calcium tungstate
Green-sensitive=Rare earth
Rare Earth screens: For Green-sensitive screens (orhto film).
far more efficient than Calcium tungstate screens=lower mAs
Screen Craze artifacts: Sharp white dots or irregular lines
superimposed over the radiograph
Caused by cracks/scratches in intensifying screen
Cassettes: Hold film & intensifying screen.
Must be light-proof-felt strips around outside
Cassette components: Radiolucent material on top (carbon fiber/aluminum)
Lead on back-absorbs backscatter.
Foam on inside to keep film/screen together.
Artifacts of the cassette: Light leak artifacts
Film-screen artifacts
Film-screen contact artifacts: Caused when film & intensifying screen aren't touching=decreased image detail
Affects of radiation on the body: Main effect is on DNA; causes damage that leads to cell death/ mutation or prevents cell reproduction
Units of Radiation: rad
gray
rad: =Radiation absorbed dose
gray: (IU)
1 gray=100 rads
Radiation dose equivalent: rad*quality factor=
based on type of radiation, & how much damage it can do
Units of radiation does equivalent: Rem-Radiation equivalent Man

sievert=Sv -(IU)
1mSv = 0.1 rem
1 rem = 10 mSv
Yearly limits of Radiation exposure: maximum of 5 rem/year
(5000 mrem)
Sources of radiation exposure: Background radiation
Man-made sources
Sources of Background radiation: Cosmic radiation
Earth's Crust
Interal exposure
Man-made sources of radiation: x-rays, MRI, tv, luminous watches, nuclear fallout

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