fluoroscopy equipment differentiate between fluoroscopic and radiographic examinations list the...
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FLUOROSCOPY EQUIPMENT
Differentiate between fluoroscopic and radiographic examinations
List the basic components of the fluoroscopic system and identify the function of each component
Describe a typical basic fluoroscopic image IntensifierDescribe advantages of image intensified fluoroscopy
over conventional screen fluoroscopy Identify uses of dynamic and static fluoroscopic
recording systems Discus digital fluoroscopic image acquisition Differentiate between conventional fluoroscopy,
image intensifier
fluoroscopy, and digital fluoroscopy
By the end of this Lecture the student will be able to:
Learning Objectives
• Bushberg, The Essentials of Physics and Medical Imaging, Williams & Wilkins Publisher.
• Positioning in Radiography: By k.C.Clarke.
• Text book of radiographic positioning and related anatomy;bykenneth L.Bontrager,5th edition
Websites
• http://www.e-radiography.net/
References
FLUOROSCOPY
Purpose: To perform dynamic studies. Visualize anatomical structures in real time or motion. View the motion and function of anatomic organs.
Conventional film radiography is restricted to static patient exams. If dynamic events need to e studied such as movement contrast materials through gastrointestinal tract (GIT) the image must be viewed directly using a dynamic method.
HistoryHistory Invented by Thomas A. Edison in 1896
Fluoroscopic systems
Conventional fluoroscopic systems Earliest fluoroscopic systems used phosphor screens where the
transmitted x-ray caused scintillations that were viewed directly.
Fluoroscopic systems
Direct Fluoroscopy
In older fluoroscopic examinations radiologist stands behind screen and view the image.
Fluoroscopic systems
The images of this type were of very poor quality for a number of reasons:- - Poor light output by the
fluorescent screen
- Low efficiency of the light conversion
mechanism
- Poor spatial resolution
for that fluorescent screens are no longer used since they gave high radiation dose to the operator.
Conventional fluoroscopic systems
What is an Image Intensifier ?A complex electronic imaging device that receives the remnant beam and converts it to light and increases the intensity of the light.
The image intensifier tube is contained in a glass envelope in a vacuum and mounted in a metallic container which provides protection for the components.
Fluoroscopic with image intensifiers
Fluoroscopic with image intensifiers
Image Intensifier Schematics
Fluoroscopic with image intensifiers
Input Phosphor
Constructed of cesium iodide.
Responsible for converting the incident photon’s energy to a burst of visible light photon. ◦ Similar to intensifying
screens in cassettes.
Standard size varies from 10 - 35 cm. ◦ Normally used to
identify the II tubes.
Photocathode
Thin metal layer bonded directly to the input phosphor.
Usually made of Cesium and Antimony compounds that respond to light stimulation.
Responsible for Photoemission.
Electron emission after light stimulation
The number of electrons emitted is directly proportional to the intensity of light intensity of the incident x-ray photon.
Electrostatic Focusing Lenses
A series of lenses inside the II tube to maintain proper focus of the photoelectrons emitted from the photocathode.
They contain a positive charge.They are located along the
length of the II tube.The focusing lenses assist in
maintaining the kinetic energy of the photoelectrons to the output phosphor.
Output Phosphor
Usually constructed of zinc cadmium sulfide crystals. Serves to increase illumination of the images by converting photoelectrons to light photons.
Spot Film Device Used to make
permanent images during the radiographic examination.
Film is positioned b/w the patient and the image intensifier.
When the film is needed, the radiologist actuates the control that brings the cassette in position. This changes the tube from fluoroscopic mA to radiographic mA.
During fluoroscopy, the tube is operated at less than 5 mA.
TV MONITORS
This practical and efficient viewing system was employed because of the limitations of the mirror optic viewing system.
TV monitors:
1. Enables viewing by multiple persons.
2. Monitors may be located in remote locations other than the radiographic room.
3. Image brightness and contrast can be manipulated.
4. Images may be stored on different medium for reviewing at a later time.
Fluoroscopy -Modes of operation
Manual Mode◦ Allow the use to select the exact MA and KVp required
AEC Mode◦ Allow the unit to drive the KVp and MA to optimize
dose and image quality Pulsed Digital mode
◦ Modifies the fluoroscopic output by cutting by cutting out exposure between pulses
◦ With the pulsed mode, it can be set to produce less than the conventional 25 or 30 images per second. This reduces the exposure rate.
Fluoroscopy Units
Smaller facilities may use one fluoroscopic system for a wide variety of procedures
Larger facilities have several units dedicated to specific applications, such as:
Gastrointestinal units Remote fluoroscopy rooms Peripheral angiography units Cardiology catheterization units Biplane angiography units Mobile fluoroscopy – C arms units
Fluoroscopy Units 1/An over table model Where the x-ray tube is placed above the table top, and the
image intensifier under the table surface.
2/An under table model Where the x-ray tube is placed under the table surface , and the
image intensifier over the table top.
Fluoroscopy Units
Fluoroscopy Units
An under table model
Fluoroscopy Units
The table have the ability to tilt from horizontal to vertical
Where the x-ray tube and image intensifier are fixed to c-arms.
Mostly used in surgical theatres.
3/Single or bi-planar cine –fluoroscopy model
Fluoroscopy Units
Remote control systems
Fluoroscopy Units
Digital fluoroscopy is currently most commonly configured as a conventional fluoroscopy systemThis method uses digital detector technologies (eg, flat-panel "direct" detection of x rays and charge- coupled device technology) The analog video signal is converted to a digital format with an analog-to-digital converter (ADC).
Digital FluoroscopyDigital Fluoroscopy
General Rule
(ALARA Principle) As Low As Reasonably Achievable
Radiation Protection
Longer usage
more exposure
Radiation Protection
TIME Take foot off fluoro pedal if physician is not viewing the TV monitor
Use last image hold (freeze frame)
Five-minute timer
Use pulsed fluoro instead of continuous fluoro
Pulsed Low-Dose provides further reduction with respect to Normal
Dose continuous mode:
Use record mode only when a permanent record is required
Record beam-on time for review
Radiation Protection
Distance is large factor for reducing exposure.Inverse Square law“ When you double the distance the exposure rate is decreased by 4 times ”
Radiation Protection
DISTANCE- One step back from
tableside: cuts exposure by factor of 4
- Move Image Int. close to patient:
less patient skin exposure less
scatter- Source to Skin Distance
(SSD):
38 cm for stationary fluoroscopes30 cm for mobile fluoroscopes
Radiation Protection
X-ray Tube Position Position the X-ray tube under the patient not above the patient.
The largest amount of scatter radiation is produced where the x-ray beam enters the patient.
By positioning the x-ray tube below the patient, you decrease the amount of scatter radiation that reaches your upper body.
Radiation Protection
ShieldingIncreasing the amount of shielding around a source of radiation will decrease the amount of radiation exposure.
To avoid scatter Be sure to shield all directions.
Shielding
-+
Radiation Protection
SHIELDING- Lead aprons: cut exposure by factor of 20- Proper storage (hanging vs. folding)
Radiation Protection
Protection tools
34
curtain thyroid shieldEye goggles
Lead Apron
Radiation Protection
CollimationCollimate tightly to the area of interest.
Reduces the patient’s total entrance skin exposure. Improves image contrast. Scatter radiation to the operator will also decrease.
Radiation Protection
Radiation Protection
• Familiarity with specific fluoro units
Factors influencing dose:
patient size
kVp, mA and time
tube - patient distance (SSD)
Image Intensifier - patient distance
image magnification vs. patient dose
x-ray field collimation
oblique's vs. perpendicular views
Safety in Fluoroscopy
Radiation Protection
Safety in Fluoroscopy Standard Operating Procedures
- each clinical protocol / procedure
- modes of operation, image recording
- emphasis on minimizing duration
- risk / benefit on a case-by-case basis
Equipment quality control
- periodic PMs
- prompt calibrations
- post radiation output values
- check aprons, shields, gloves annually
Radiation Protection
Final Summary Golden rules” Keep the II close to the patient
Do not overuse magnification modes
Keep the x-ray tube at maximal distance from patient
Use higher kVp where possible
Wear protective aprons and radiation monitors, and know where
scatter is highest
Keep your distance, as far as is practicable
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