Term
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Definition
| is the formal study of radiation protection and safety. |
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Term
| What is the purpose of health physics? |
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Definition
| Protection for occupational workers against unnecessary exposure. |
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Term
List the 4 cardinal rules of health physics or radiation protection. |
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Definition
Time, Distance, Shielding and Monitor |
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Term
How does Time effect occupational workers in radiation protection? |
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Definition
| The shorter the time exposed to radiation the better. Time is directly proportional to the amount of exporsure received. |
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Term
| What is the equation for Time Exposure |
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Definition
Exposure=Exposure rate x time ex. 22mR/hr x 36min= 225mR/hr x (36min/60hr) =135mR/hr |
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Term
| How important is distance to radiation protection? |
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Definition
Keep a large distance as possible between you and the source of radiation. The relationship is inverse square. *The most effective means of protection for radiographers. |
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Term
| What is the equation used for distance? |
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Definition
New Intensity=Old distance2 Old Intensity new distance 2 ex. radiation intensity at 90cm is 1.3R/m what would it be at 270cm. x/1.3R/m =90 2 2702 |
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Term
what direction does scatter go in? |
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Definition
| it goes in the forward direction when it comes in contact with a patient. |
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Term
| In what direction does most of the scatter go during a flouroscopic exam? |
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Definition
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Term
| What is the intensity of scattered radiation at a distance of 1 meter from the patient at a right angle? |
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Definition
0.1% (1/1000) of the entrance skin dose ex. if the entrance skin dose is 820 mR, at 1 meter and at a right angle the intensity is 0.82 mR. |
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Term
| What is the amount of radiation exposure a radiographer receives during tableside flouroscopy? |
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Definition
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Term
| How is shielding important in radiation protection? |
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Definition
| It will cut down the amount of radiation a person receives when you place some type of sheilding between you and the radiation. The sheild absorbs some of the dose. |
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Term
| What are the best sources of shields? |
|
Definition
are with a high atomic number like lead Z=82 |
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Term
| What are the 2 ways to measure shielding matials? |
|
Definition
1. Thickness of material mm of Pb equivalence lead prefered but doesn't have to be the material used. 2. Tenth Value Layer (TVL)-amount of shielding material that will reduce the amount of intensity to 1/10 of the original amount. |
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Term
| What does 1TVL = in the HVL? |
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Definition
| 1 TVL= 3.3 HVL of absorbing capability. |
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Term
How is monitoring involved in radiation protection? |
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Definition
uses a type of monitor to monitor the amount of radiation exposure received. required whenever radiation workers are at risk of receiving 10% or more of the annual total effective dose equiv of 5 REM (50mSv) per year. |
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Term
| list the options for monitoring devices. |
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Definition
1. pocket dosimeter or direct reading dosimeter. 2.Film badge dosimeter 3. Thermoluminescent dosimeter 4. Optically stimulated Luminescent dosimeter |
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Term
| What is a pocket dosimeter? |
|
Definition
give instantaneous reading of radiation received, reusable. bes used when there is a chance or high radiation. very accurate over short periods of time (day or less) Disadv.no permenent record of the exposure exists, very fragile if you drop them looses data. charge on electroscope can leak and expensive 150-200 bucks |
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Term
| Describe a film badge dosimeter. |
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Definition
| a piece of photographic paper film mounted inside a plastic holder. filters aluminum,copper, cadmium are added to determine what type of energy it is. read once a month from the optical density of the film with an H&D curve |
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Term
| What are the advantages and disadvantages of a film badge dosimeter? |
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Definition
advantages: inexpensive, 1-4 dollars a month, fairly rugged, easily handling and processing and a permanent record of radiation received. Disadv: limited range of exposure (10 - 1800mR) limited k edge 50keV. doesn't record exposures less then 10mR, sensitive to heat and humidity, only be worn 1a month and accuracy is only 50%. |
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Term
Describe a thermoluminescent dosimeter (TLD) or Tissue Equivalent dosimeter. Better device to use. |
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Definition
| uses crystal lithium fluoride or calcium fluoride. when crystal is exposed to radiation electrons jump to higher level. They emit light when heated that is equal to the amount of radiation exposed to. Average atomic number similar to human soft tissue. |
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Term
| What are the advantages and disadvantages of TLDs? |
|
Definition
Adv:Very accurate 99.9%, sensitive to wide band of energ, sensitve to wide range of radiatin 1 mR-1000R, small in size and not sensitive to heat and humidity and reusable. can be worn up to 3 months.nuc med wears ring Disadv: more expensive 20 bucks |
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Term
| Describe optically stimulated luminescent dosimeter |
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Definition
| developed in 1990 by landauer inc. Use aluminum oxide. when irradiated electrons jump to a higher energy state. exposed by a laser will cause them to return to their original energy state and release light in proportion to the original amount of radiation. adv: low cost 95 % accurate, 1mR - 500R |
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Term
| What does the FDA recommend regarding monitoring devices? |
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Definition
| wear it up on the collare and over the lead, because scatter hits face from flouro. or scatter from pts. If pregnant 2nd monitoring device worn under lead. occupational personal shouldn't be used to hold pts if possible. Other persons such as parents,older adult relatives,nurses, supply lead aprons or gloves. |
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Term
| What are the two things a pregnant radiographer do? |
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Definition
| most identify that they are pregnant, and wear a 2nd dosimeter. volunt. notify employer they are pregnant. can't receive more then .05 rem/month. normal duties should be assigned and normal radiation practice and procedures should be followed. |
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Term
| What are the four main types of radiation? |
|
Definition
useful or primary beam leakage radiation scattered radiation stray or secondary radiation |
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Term
| what is useful beam or primary beam |
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Definition
radiation that passes through xray tube window and beam limiting device. |
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Term
What is the most dangerous of radiation to a radiographer? |
|
Definition
useful beam or primary beam |
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Term
| What is leakage radiation? |
|
Definition
| all radiation passing through xray tube housing . other then useful beam. low levels of radiation |
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Term
| What is scattered radiation? |
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Definition
| Radiation that under goes a change in directin upon contact with matter. less powerful then primary beam. weaker in energy and amount. |
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Term
| How much of our exposur is from scatter radiation? |
|
Definition
90%. Main source are patients |
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Term
| What is stray or secondary radiation? |
|
Definition
sum of leakage and scatter radiation together. anything that isn't useful is secondary. |
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Term
| Who is responsible for equipment specifications? |
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Definition
| The FDA imposed equipment and design specifications that xray equipment must adhere to. title 21 CFR part 1020 and in NCRP report # 105 |
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Term
| What is the equipment specifications of the x ray tube housing in radiographic equipment? |
|
Definition
the protective cover over the x ray tube to prevent leakage radiation. must confine leakage radiation to under 100 mR/hour when measured at 1meter. 39.6 inches. close collimators put detectors 1meter away at different areas and measure radiation. |
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Term
What is xray beam quality? energy,penetrating, hardness of beam. |
|
Definition
affected by kVp usad and the amount of Aluminum a. xray generator using 3 phase = higher ave. energy in beam not like single phase. b. kVp =higher kVp =high beam energy. type of xray generator controls ave. energy c. alum. filtration effects ave. energy of the beam. more filtration used at higher kVp |
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Term
| What is the HVL and min. thickness of AL with a kVp below 50, 50-70 and above 70 kVp? |
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Definition
below 50kVp 0.5 mm Al HVL 0.3 mm Al 50-70kVp 1.5 mm Al HVL 1.2 mm Al above 70 kVp 2.5 mm Al HVL 2.3 mm Al |
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Term
| What is the equation for total filtration of beam quality? |
|
Definition
| total filtration = inherent filtration + added filtration |
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|
Term
| What is a beam restricting device in radiographic equipment? |
|
Definition
must be a variable aperature collimator with 5 specifications |
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Term
| How accurate does a beam restricting device need to be? |
|
Definition
within 2% of SID ex. if at a 40 " SID 40x0.02=0.8" margin of error exsist between the indicated value and the actual value |
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|
Term
| how should the shutters be mounted and why on a beam restricting device? |
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Definition
| should be mounted as close as possible to x-ray source (focal spot). This reduce amount of off focus or stem radiation (radiation created outside of focal spot area). |
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Term
| describe how a mirror and light bulb are used in a beam restricting device. |
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Definition
Light is used for indicating area being exposed. distance from the illuminator bulb to the mirror must be the same as the distance form the focal spot to the mirror. area of light will be the same as the area hit by x rays |
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|
Term
What is the minimum light field illumination |
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Definition
| brightness level required by FDA. 15 foot-candle(ft-cd) or 160 lux at 100cm SID. if dimmer then this considered unsafe. |
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Term
| describe the postive beam limitation in radiographic equipment. |
|
Definition
automatic collimation. senors in the bucky that measures size of image receptor and automatically adjusts the field size. Accuracy 3% of SID. |
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Term
| What is beam alignment in radiographic equipment? |
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Definition
| x-ray field aligned to center of image receptor in the bucky. must be accurate within 2% of SID |
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Term
Describe a controlled area |
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Definition
| An area occupied for radiation workers. ex control booth,x-ray room, and patient. Under the control of radiation safety officer. |
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Term
| what is the desired exposure rate an occupational worker can receive in a controlled area? |
|
Definition
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Term
| What kind of warning do controlled areas use to show their is radiation? |
|
Definition
| universal radiation sign or words using caution. |
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Term
| What does Radiation area mean? |
|
Definition
exposure can be 5mR/hr - 100mR/hr ex. diagnostic room |
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Term
| What does High radiation area mean? |
|
Definition
radiation exposure greater than 100mR/hr -500R/hr |
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Term
| What is very high radiation? |
|
Definition
| radiation exposure above 500R/hr |
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Term
| Describe uncontrolled areas. |
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Definition
areas that are occupied by the general public not under the control of a radiatin safety officer. ex. waiting rooms, offices, hallways. Receive less then 10mR/hr. |
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Term
| what is the SID indicator? |
|
Definition
| must be on all diagnostic x-ray machines and accurate within 2% of the SID. |
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|
Term
how accurate does the SID indicator have to be? |
|
Definition
|
|
Term
| what must the control panel indicate? |
|
Definition
| the conditions of exposure (kVp, mAs) and whenever the x-ray tube is energized. |
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|
Term
How does the control panel accomplish indicating kVp, mAs and when the x-ray tube is energized? |
|
Definition
by using meters,lights and audible sounds |
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|
Term
| Describe reproducibility for radiographic equipment. |
|
Definition
| the same technical factors should always create the same exposure rate at any time |
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|
Term
What is the variation rate reproducibility can't exceed? |
|
Definition
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|
Term
What is reciprocity in radiographic equipment? |
|
Definition
| when the same mAs is selected using different mA and time combinations, the radiation output should be the same. |
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|
Term
| what is linearity in radiographic equipment? |
|
Definition
any increase in mAs should produce the same increase in exposure rate (radiation output). 2 times more mAs should produce 2 times more radiation to be measured. |
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|
Term
| what is the allowe variation for linearity? |
|
Definition
|
|
Term
| what is collimator-skin distance? |
|
Definition
| a distance used to from the collimator to the patient's skin. This protects the skin from photoelectrons produced by photon interaction with materials in the collimater. |
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Term
| What is the distance for the collimator-skin distance? |
|
Definition
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|
Term
| What is source to skin distance in radiographic equipment? |
|
Definition
| focal spot of xray tube to skin. |
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|
Term
What is the purpose of the control booth in radiographic equipment? |
|
Definition
| must not be possible to make an exposure outside the fixed barrier. |
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|
Term
| how many times do xray have to scatter before entering the control booth? |
|
Definition
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|
Term
what happens to the intensity as x ray scatters? |
|
Definition
| the intensity is 0.1% (1/1000th) of the original intensity at a distance of 1 meter |
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|
Term
| How big should to floor of the control booth be? |
|
Definition
| no less then an area of 7.5ft 2 |
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|
Term
| how high should the wall of the control booth be and mounted? |
|
Definition
| must be fixed to the floor and at least 7 ft. high |
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|
Term
| if there is a door to the contol booth when can an x-ray exposure be made? |
|
Definition
|
|
Term
| where should the exposure swich be located in the exposure booth? |
|
Definition
| fixed within the booth and at least 30" away from the opening of the control booth closest the to examining table |
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|
Term
| what is the minimum size of window in the control booth and shielding requirement? |
|
Definition
shielding requirement is like a lead shield, 1.5 Pb equivalent or 30% lead by wieght. The size must be at least 1 ft 2 and 5 ft from the floor. |
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|
Term
What is the maximum tabletop thickness allowed by the FDA? |
|
Definition
no more then 1.0 mm Al equivalent. |
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|
Term
| what is a protective barrier and the two types? |
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Definition
they are designed to keep radiation from leaving the main x-ray room. types: primary and secondary. |
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Term
| where are protective barriers found? |
|
Definition
| in the walls, floors and ceiling to shield against radiation |
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|
Term
| What is a primary barrier? |
|
Definition
to protect against useful or primary beam of radiation (full strength) thicker in lead content. installed perpendicular to the x-ray beam ex. floor. |
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|
Term
| wha is the secondary barrier in protective barriers? |
|
Definition
protect against secondary or stray radiation include the control booth walls and ceiling of the x ray room |
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|
Term
How does the distance affect the barrier thickness? |
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Definition
| the distance from the x-ray source to the barrier. the closer the source is to the barrier the the more lead is needed in the barrier. |
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Term
What is the occupancy Factor (T) that affect the barrier thickness? |
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Definition
| the amount of time that an area is occupied behind the barrier. the more time spent behind a barrier the more lead is needed. |
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Term
| what is T=1, T=1/4 and T=1/16th of the occupancy factor. |
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Definition
T=1 full occupancy 100%ex. control booth, office, corridors,waiting rooms, darkrooms T=1/4 occupied by 25% of the time t=1/16 occasional occupancy. |
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|
Term
| What is workload mean in barrier thickness? |
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Definition
| workload (W) measures the amount of exposures and radiation outpur per week. |
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Term
| What is the unit for measuring workload? |
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Definition
W=mA minutea/week about 1000 mA-minure/week is considered a busy room. The busier the room the more shielding required. |
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Term
| radiographic room is in operation 5 days a week. average number of patients/days is 20 and average number of views/patients is 3. ave technique factore is 30mAs/image what is the workload? |
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Definition
| 30mAs/image(5days/week)(20patients/day)(3 images/patient)=9000mAs/week /60=150 mA-minutes/week |
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|
Term
| what is the use factor in factors affecting barrier thickness? |
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Definition
use factor (U) U=1the percentage of time that the xray beam is on and directed towards a particular barrier. also known as beam direction factor |
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Term
| what does U=1, U=1/4, and U=1/16 mean? |
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Definition
U=1 full use-beam is directed all the time . floors, doors, ceilings and walls. U=1/4 partial use-doors and walls not routinely exposed to the primary beam U=1/16 occasional use- ceilings of rooms not routinely exposed to the primary beam |
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Term
| what is the use factor for all secondary factors |
|
Definition
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|
Term
| How does kVp affect the barrier thickness? |
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Definition
| the maximum kVp to be used in the room. A higher kVp capability unit would need more shielding. |
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|
Term
Wha is the primary protective barrier in a general purpose radiographic room? |
|
Definition
1.6mm Pb eq. (1/16) when xray tube is 5-7 ft. from barrier. |
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|
Term
| what is secondary protective barrier Pb eqv. |
|
Definition
| use 0.75mm Pb eqv. (1/32) extend from 7.3 ' to the ceiling |
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|
Term
| what is protective apparel? |
|
Definition
must be worn whenever the exposure rate could exceed 5mR/hr. usually during flouro |
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Term
| What are lead aprons, and gloves (protective material) made of? |
|
Definition
composed of lead-impregnated vinyl or rubber. newer models made of a composite of barium, tungsten, and lead. |
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Term
| what are the requirments for lead aprons? |
|
Definition
| minimum of 0.5mm Pb eqv. and covers at least 75-80 % of active bone marrow |
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|
Term
what is the percent attenuation at 0.25mm thickness at 50kVp, 75kVp and 100 kVp? |
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Definition
wt in lbs is 3-10 at 50 kVp= 97% 75kVp=66% and 100 kVp=51% |
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Term
| what is the precent attenuation of lead at .5 mm thickness at 50kVp,75kVp and 100 kVp? |
|
Definition
7-12 lbs 50 kVp=99.9% 75kVp=88% 100kVp=76% |
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Term
| what is the percent attenuation at 1.0 mm lead eqv. at 50kVp, 75kVp and at 100 kVp? |
|
Definition
13-25 lbs in wt. at 50kVp=99.99% 75kVp=98.7 % 100 kVp= 95 % |
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|
Term
| What is the lead requirment for gloves? |
|
Definition
minimum 0.25 Pb but preferred is 0.5mm Pb. |
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|
Term
| What is the lead requirement for thyroid shields? |
|
Definition
| used for general flouroscopic must be 0.5mm Pb eqv or 1.0 mm Pb eqv. |
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|
Term
| what is the lead equivalence of eye glasses? |
|
Definition
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|
Term
| What is the source skin distance (tube to table top distance) of a fixed unit inflouroscopic equipment? |
|
Definition
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|
Term
| what is the min. SSD for mobile units in flour equipment? |
|
Definition
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|
Term
| What is the SSD for special units in flouro equipment? |
|
Definition
|
|
Term
| what is the 5 min. reset timer for on fluoro equipment? |
|
Definition
| sends an alarm after 5 min. of flouro has been used. Stops fluoro until you reset it. |
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|
Term
| What is the primary protective barrier on fluoro. equip? |
|
Definition
is in the tower assembly FDA limits exposure to less then 2 mR/hr at 10 cm away. about 2.0 mm Pb equivalence |
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|
Term
|
Definition
fluoro units equiped with this can reduce exposure up to 90% |
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|
Term
| what is the maximum entrance exposure rate? |
|
Definition
rate as beam enter patient. with ABS(automatic brightness stabilization) max 10 R/min without ABS max is 5 R/min |
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|
Term
| what is restricition of field size in flour equip.? |
|
Definition
| the length or width of the useful beam at the image intensifier shall not exceed that of the visible image area by more then 3% of the SID. |
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|
Term
| What is the buckey slot cover on the flouro. equip.? |
|
Definition
Its a metal flap cover must absorbe 1TVl absorbs 90% of radiation |
|
|
Term
| what is the protective apron in the fluoro equip.? |
|
Definition
radiation comes from under the table and curtain absorbs scatter radiation from patient. must be there during exam and min. of .25 mm Pb equiv. and be a min 18x18" in size |
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|
Term
| what is the exposure switch on fluoro equip.? |
|
Definition
| must be pushed to activate fluoro. it is a deadman's switch that requires constant pressure for switch to be turned on. |
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|
Term
| What is the min. filtration required in fluoro equip.? |
|
Definition
| 2.5 mm Al eqv. because it operates at 70 kVp usually put 3.5 mm Al eqv. |
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|
Term
| What is the maximum mA allowed in fluoro equip.? |
|
Definition
| 5.0 mA max for any fluoro unit. this is because the exams can go for long periods of time. most exams done at 0.3-0.5 mA |
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|
Term
what are the same 4 things that mobile equipment has as radiographic equipment. |
|
Definition
they have the same leakage 100mR/h reproducibility 5%, collimator 2% of SID, Linearity and reciprocity 10% margin of error. |
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|
Term
What is the SSD in mobile radiography? |
|
Definition
SSD has to be 30cm or 12 " |
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|
Term
what must indicate the focal spot on mobile equipment? |
|
Definition
a mark must be present for the focal spot housing. SID indicator must be within 2% |
|
|
Term
| how long does the exposure cord have to be on mobile equip? |
|
Definition
| must be at least 6 ft 1.8 meters long |
|
|
Term
| How much radiation exposure comes from mobile and flouro exams.? |
|
Definition
|
|
Term
How much radiation comes from occasional exposure? |
|
Definition
|
|
Term
Describe radiation therapy. |
|
Definition
Use of radiation to treat diseases. uses radiation hormeis effect-beneficial effect from radiation. |
|
|
Term
| what is the number one disease treated with radiation therapy? |
|
Definition
|
|
Term
| how is cancer characterize and how many types are there? |
|
Definition
270 kinds. characterized as uncontrolled growth. spread of abnormal cells |
|
|
Term
| What are characteristics of cancer cells? |
|
Definition
increased amount of chromatin than normal cells and increased amount of nucleoplasm to cytoplasm ratio |
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|
Term
|
Definition
| Leukemia, bone and brain cancer. |
|
|
Term
| what is the #1 cancer that kills men and women? |
|
Definition
|
|
Term
| In 2007 how many people died of cancer in the U.S.? |
|
Definition
|
|
Term
| how many people get lung caner each year? |
|
Definition
|
|
Term
| how many people die from lung cancer each year? |
|
Definition
|
|
Term
| what is the percentage of cancer deaths from lung cancer? what precentage is from smoking and the other from radon gas? |
|
Definition
28% of cancer deaths are from lung cancer. 20 caused by radon gas and 80% caused by smoking |
|
|
Term
| how many new cases of cancers are discoverd each year? |
|
Definition
|
|
Term
what is the percentage of cancer cure after 5 years? |
|
Definition
| 63 % at 2007 1964 it was 33% |
|
|
Term
| What is early detection and treatment have to do with being cured of cancer? |
|
Definition
the earlier you detect the cancer the cure rate goes up. less then 20% of all cancers caught early are fatal |
|
|
Term
what are the factors the being cured of cancer depend on. |
|
Definition
| early detection and treatment, quality of care you receive, overall health and type of cancer. |
|
|
Term
| which cancer has the highest cure rate? |
|
Definition
Squamous cell carcinoma 96% |
|
|
Term
| which cancer has the least cure rate? |
|
Definition
|
|
Term
| How does geography affect being cured from cancer? |
|
Definition
| if there is a lot of polution, high levels of backround radiation. |
|
|
Term
how is surgery a treatment for cancer? |
|
Definition
| it cuts the whole tumor out |
|
|
Term
|
Definition
drugs used to treat cancer cytotoxins kill poison cell but bad side effects. |
|
|
Term
|
Definition
| tries to get body's own immune system to destroy cancer. |
|
|
Term
what are the three types of immunotherapy? |
|
Definition
gene therapy vaccines and monoclonal antibodies |
|
|
Term
|
Definition
| gene P53 will attack and kill cancer cells. the trick is to turn it on and turning it off. |
|
|
Term
| what is monoclonal antibodies? |
|
Definition
| when you take lymphocytes out of the blood and genetically program to attack cancer and then replace it back into the body |
|
|
Term
| describe hyperthermia for treating cancer. |
|
Definition
| cancer can't survive in body temp. over 105 degres F. They locally heat the area with ultrasonic waves, focused microwaves. |
|
|
Term
| what is bone marrow transplant in treating cancers? |
|
Definition
| used in leukemia, aplastic anemia |
|
|
Term
| describe hormone therapy. |
|
Definition
| uses certain hormones to treat cancer. ex. like breast cancer a women receives testosterone and males |
|
|
Term
| what 3 combinations of treatment is used to treat cancer? |
|
Definition
| surgery, radiation therapy and chemotherapy |
|
|
Term
| list the two cause of cancers. |
|
Definition
| External and internal causes. |
|
|
Term
| list the 5 external causes of cancer. |
|
Definition
| radiation, chemicals (plastic), viruses, diet and nutrition, and lifestyle (smoking, drinking etc..) |
|
|
Term
| list the internal causes of cancer. |
|
Definition
| hormones,DNA , and the immune system |
|
|
Term
|
Definition
| branch of medicine that deals with tumors and the study of tumors. |
|
|
Term
| list the two types of tumors. |
|
Definition
| Benign -non cancerous and malignant -cancerous |
|
|
Term
| what are the two types of malignant tumors. |
|
Definition
| epithelial and mesenchymal tissue. |
|
|
Term
| what is the origin of malignant cancers? |
|
Definition
|
|
Term
| describe epithelial cancers. |
|
Definition
called carcinoma. 2 locations of epithelial cancers- ectoderm epithelial tumor-outside of the body and endoderm epithelial tumor-on the inside of the body. |
|
|
Term
| list examples of epithelial ectoderm tumors and epithelial endoderm tumors. |
|
Definition
ectoderm ex. skin cancers and mouth tongue. endorm ex. breast cancer, thyroid cancer of GI system |
|
|
Term
| describe mesenchymal tissue or mesoderm of malignant tumors. |
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Definition
connective tissues of the body called sarcomas cancers of the lymphatic system made up of 2 parts |
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Term
list the 2 parts of mesenchymal tissues . |
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Definition
stroma- made of up normal tissue, support malignant cells, excrete hormones parenchyma-actual cancer cells that are growing and dividing. |
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Term
| what are the layers of cancerous cell found in the parenchyma of the mesenchymal tissue? |
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Definition
group 1 cell-viable and actively proliferating group 2 cell-viable but not actively proliferation group 3 cell- non-viable but intact morphologically recently dead group 4 cells- non-viable and non-intact |
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Term
| List the 2 types of radiation effects on tumors to kill the tumors. |
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Definition
direct-radiation is directly killing cells. make sure to kill all group 2 cells because of sensitivity. indirect radiation- to kill tumor radiation destroys tumor bed, nutrients that supply the tumor . |
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Term
| what is curative treatment for treating cancer? |
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Definition
a treatment designed to cure patient of the disease |
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Term
| what is palliatve treatment? |
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Definition
| when there is no hope for a cure but done to try to help relieve the symptoms or prolong a persons life |
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Term
| what is internal therapy? |
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Definition
radiation incorporated into their body tissues. ex. thyroid cancer-inject or swallow Iodine 131. |
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Term
| what is brachy therapy,plesia or seed? |
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Definition
tiny seeds of radioactive material implanted into diseased organ or tissue. ex. cervical cancer |
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Term
what is external beam therapy or teletherapy? |
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Definition
distance source from body like cobalt 60, linear accelerator,neutron accelerator, and proton accelerator. |
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Term
| what is cobalt 30 in exteranal beam therapy? |
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Definition
| creates gamma rays taht are 1.3 meV inexpensive |
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Term
| what is a linear accelerator in external beam therapy? |
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Definition
more commonly used. create a bunch of electrons accelerate at a high speed and hit an anode or target. create xray up to 60 meV |
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Term
what is neutron accelorator? |
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Definition
| whole accelorate creates neutrons. go a specific depth. |
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Term
| what is a proton accelerator? |
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Definition
similar to a neutron accelorator , goes to a specific depth and stops. fewer side effects and can be focused more specifically. |
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Term
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Definition
uses powerful magnetic fields. transfer of vibrating energy from one system into another. sends radiowaves. can be cross sectional and 3D |
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Term
| who developed the NMR and when? |
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Definition
| Doctors Bloch and Purcell in 1930-1940 |
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Term
| What was the NMR used for? |
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Definition
| process used for chemical analysis. took certain chemicals. each element creates its own frequency of radiowave. |
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Term
| who was the first Dr. to create and an image with the NMR and when? |
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Definition
| 1972 and Dr. Paul Lauterberg |
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Term
| when was the first MRI done on patients? |
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Definition
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Term
when a pt. is put in the MRI what happens to its Hydrogen atoms? |
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Definition
they line up with the magnetice field and create radio waves (sent perpendicular to direction of mag. field). H atoms get knocked out of alignment. to get back to alignment use energy to so. energy released is RF (which is used for imaging) |
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Term
| what is the technical name for wobbling? |
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Definition
when H atoms are spining on its axis. term is precussion. |
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Term
| what is the realignment process? |
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Definition
relaxation when atoms line up or when wobbling stops. T-1 time it takes to realign back with main magnet. T-2 time it takes precussion to stop. |
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Term
| describe the primary magnet. |
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Definition
supplies main mag. field. superconductive electromagnet can conduct with no resistance. |
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Term
| what is the primary mag. filled with and why? |
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Definition
| filled with He and keep electric current going with out having the mag plugged in. |
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Term
| what are the secondary coils on and MRI? |
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Definition
| designed to focus main mag to area of focus. to slice where you are scanning. |
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