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Resident Physics Lectures
Fluoroscopic Imaging (year 1) George David Associate Professor of Radiology Medical College of Georgia
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Early Fluoroscopy Radiologist directly viewed fluorescent screen
screen covered with lead glass for protection Low light levels 10-30 minute dark adaptation required by wearing red goggles
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Human eye light receptors
rods (scotopic vision) respond to very low light levels night vision peripheral vision poor visual acuity poor gray shade detection cones (photopic vision) high direct vision acuity blind at low illumination levels
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Image Intensifiers evacuated glass envelope vacuum tube
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Image Intensifier Input Output x-rays ==> light X-rays
Small viewing screen
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Image Intensifier Components
input phosphor x-rays to light photocathode light to electrons electrostatic focusing lens steer those electrons accelerating anode speed up those electrons output phosphor electrons to light
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Input Phosphor Cesium iodide (CsI) x-rays ==> light
CsI crystal needles perpendicular to substrate minimizes lateral light diffusion or scattering improves resolution typical image tube resolution 3 - 5 line pairs / mm
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Input Phosphor K-Edge of phosphors absorbs ~ 2/3 of incident beam
CS ==> (36 keV) I ==> 33.2 keV well suited to average fluoro beam energy 30 to 40 keV absorbs ~ 2/3 of incident beam absorption energy
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light photons ==> electrons
Photocathode light photons ==> electrons attached to input phosphor minimizes light diffusion Photo-emissive metal light causes emission of photoelectrons # photoelectrons emitted proportional to incident light from input phosphor
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Electrostatic Focusing Lens
lenses + - Several electrodes plated to inside glass envelope + voltage applied to electrodes voltages determine magnification mode focuses each point of input phosphor to a point on output phosphor inverts & reverses image Side-side Top=bottom Black-white
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Accelerating Anode in neck of image tube + 25 - 35 kV charge
accelerates electrons faster electrons produce more light when they strike output phosphor
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electrons ==> light
Output Phosphor Small viewable fluorescent screen inch diameter converts electron’s kinetic energy to light ~ 50 fold increase in # light photons over input phosphor Output Phosphor electrons ==> light
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Output Phosphor thin aluminum layer on back of output phosphor
prevents screen’s light from re-entering tube & reaching input phosphor Output Phosphor - X Aluminum
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Output phosphor viewing
direct uses lenses & mirrors television high quality closed circuit television chain
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Image Tube Parameters Brightness Gain Conversion Factor
ratio of II brightness to a “standard” screen Conversion Factor light output per radiation rate input Deterioration over time 10% decline in brightness / year typical must increase patient exposure to get same light intensity
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II Gain (Intensification Factor)
Output phosphor brightness “standard” screen brightness typically ~ 10,000
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II Gain (Intensification Factor)
Brightness gain = minification gain X flux gain Minification gain making image smaller also makes it brighter Flux gain acceleration of electrons toward output phosphor Electrons +
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Minification Minification gain
12” mag mode 9” mag mode Minification gain Area of (effective) input phosphor Area of output phosphor Smaller image Less magnification More minification Larger gain Larger image More magnification Less minification Smaller gain
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Minification Gain image brighter because output screen smaller than input screen changes with magnification mode (9”, 6”, etc) changes by about 2X for each mag mode typically 81 for 9” mode (output phosphor about 1” diam) 36 for 6” mode 16 for 4” mode Highest magnification Lowest Minification gain Lowest magnification Highest Minification gain 6” 12” 9”
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Auto-Brightness Generator senses image brightness and modulates beam intensity to hold brightness constant Lowest magnification Highest Minification gain Lowest dose Highest magnification Lowest Minification gain Highest dose 12” 6” 9”
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Flux Gain Caused by high + voltage of anode
acceleration of electrons in tube Does not change with magnification mode typical value ~ 50
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Contrast Ratio of brightness at center of image with & without blocking center typically 10:1 to 20:1 Light Meter Lead
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Image Tube Contrast degrades over time depends on collimation
tube properties input phosphor photon absorption output phosphor electron absorption light backscatter from output phosphor to input phosphor Light Meter Lead
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Other II Characteristics
Lag persistence of illumination after irradiation insignificant for modern tubes Distortion Image intensifier has rounded bottom Electron steering better in center than in periphery unequal magnification straight lines appear bent pincushion effect
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Vignetting loss of brightness in image periphery caused by
periphery displayed over larger area of input screen decreases brightness poorer periphery focus
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Multi-Field Image Tubes
Dual, 3X, 4X field sizes common Image focused by adjusting voltage on focusing electrodes (electronic lenses) By law, collimators must cone in during mag operation X-ray field should match imaged field 9 “ 6”
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Magnification Advantages Disadvantages Magnifies anatomy
improves spatial resolution Disadvantages smaller field of view increased radiation intensity (but less tissue exposed) decreased minification gain 9 “ 6”
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Digital Fluoroscopic Receptors
Flat Panel Digital Technology Now used for angiography / cardiology and some portable C-arms No spatial distortion
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