Exam 3 Ch 22- Scatter Production

Question 1

3 main factors that contribute to production of scatter-

Answer 1

kVp, field size, & patient thickness

Question 2

The only x-ray photons that are incident on an IR are-

Answer 2

those that didn’t interact with the patient

Question 3

3 main tools for controlling scatter-

Answer 3

beam restriction, grids, & compression (not talked ab a lot)

Question 4

3 types of x-rays responsible for imaging on a radiograph-

Answer 4

transmitted & scattered (both show up black) & absorbed (white, not talked ab a lot)

Question 5

image-forming x-rays-

Answer 5

incident on IR

Question 6

As SID decreases, what increases?

Answer 6

magnification

Question 7

As kVp increases, what also increases?

Answer 7

-relative compton interaction
-scatter production

Question 8

As kVp increases, what decreases?

Answer 8

-photoelectrons rapidly
-likelihood of any kind of single photon during a compton interaction

Question 9

What does compton add to a radiograph?

Answer 9

fog/scatter

Question 10

compton is scatter, but photons can-

Answer 10

scatter more than once

Question 11

Why can you not use a low kVp technique?

Answer 11

-increases pt. dose
-would have fewer transmitted photons (black)

Question 12

collimation reduces ____ ____ & improves ______.

Answer 12

reduces pt. dose & improves contrast

Question 13

How does collimation help reduce scatter?

Answer 13

by restricting the beam

Question 14

Field size affects-

Answer 14

amount of scatter produced

Question 15

As field size increases, what also increases?

Answer 15

scatter

Question 16

As field size increases, what decreases?

Answer 16

contrast

Question 17

As patient thickness increases, what also increases?

Answer 17

scatter

Question 18

with increasing pt. thickness, more x-rays undergo-

Answer 18

multiple scattering

Question 19

What does pt. thickness result in?

Answer 19

greater average angle of scatter

Question 20

What can be used to control patient thickness?

Answer 20

sometimes, compression devices

Question 21

contrast-

Answer 21

visible difference between light & dark areas of an image

Question 22

contrast resolution-

Answer 22

ability to image & distinguish the difference

Question 23

as scatter increases, what decreases?

Answer 23

contrast

Question 24

3 beam restrictors-

Answer 24

aperture diaphragm, cones & cylinders, & variable aperture collimator

Question 25

Use a grid when part thickness gets above __, ___, or __. or when kVp is ____.

Answer 25

-when part thickness gets above 10, 12, or 13
-kVp is greater than 60

Question 26

4 types of grids-

Answer 26

parallel, crosses, focused, & moving

Question 27

2 reasons to use beam restrictors-

Answer 27

-only the tissue being examined should be exposed
-large field size increases scatter & decreases contrast

Question 28

aperture diaphragm-

Answer 28

simplest & most restrictive beam restricting device (any kind of pitch aperture distorts it)

Question 29

Aperture diaphragm is designed on film to-

Answer 29

leave 1 cm around field to prove collimation

Question 30

What kind of construct is the aperture diaphragm?

Answer 30

lead/lead lined metal construct

Question 31

aperture diaphragm opening is designed to be-

Answer 31

1 cm smaller on all sides of film

Question 32

cones & cylinders is a modification to-

Answer 32

modification to aperture diaphragm

Question 33

cones & cylinders resulting exposure-

Answer 33

resulting exposure is circular

Question 34

cones & cylinders position & distal end determines-

Answer 34

field size

Question 35

What is 1 problem with cones & cylinders?

Answer 35

cone-cutting

Question 36

cone-cutting displayed by-

Answer 36

grid cut-off

Question 37

What is the collimator also known as?

Answer 37

variable aperture diaphragm

Question 38

collimator 1st stage-

Answer 38

enhances shutters designed to control off-focus radiation

Question 39

collimator 2nd stage-

Answer 39

shutters work in pairs for square/rectangle fields

Question 40

collimator allows for

Answer 40

infinite # of field sizes

Question 41

collimator is more ___ & the least ____.

Answer 41

more versatile & the least __

Question 42

collimator is the most commonly used-

Answer 42

most commonly used beam restrictor

Question 43

PBL was mandated by-

Answer 43

US FDA for all x-ray machines in 1974

Question 44

PBL was removed in 1994 bec-

Question 45

bucky tray has sensors that detect-

Answer 45

size & alignment of cassette

Question 46

synchronous motors are actuated to-

Answer 46

adjust to appropriate field size

Question 47

even with PBL, tighter collimation will-

Answer 47

reduce pt. exposure

Question 48

the grid is used to-

Answer 48

remove scattered x-ray after the subject & before IR

Question 49

the grid was firs demonstrated by-

Answer 49

gustaf bucky in 1913

Question 50

the grid consists of-

Answer 50

series of alternating radiopaque & radiolucent materials

Question 51

radiopaque materials are-

Answer 51

led

Question 52

radiolucent materials are-

Answer 52

plastic/carbon

Question 53

radiopaque strips are called-

Answer 53

grid strips

Question 54

radiolucent strips are called-

Answer 54

interspace material

Question 55

grid ratio formula-

Answer 55

height of led strips divided by width of interspace (H/D)

Question 56

high-ratio grids are more effective at-

Answer 56

“cleaning up” scattered x-rays

Question 57

grids range from-

Answer 57

5:1-16:1

Question 58

5:1 ____ cleanup-

Answer 58

85%

Question 59

16:1 _____ cleanup=

Answer 59

97%

Question 60

grids take ____ away where it shouldn’t be & adds ____.

Answer 60

takes away black, adds white

Question 61

scatter puts ____ where ____ should be-

Answer 61

puts black where white should be

Question 62

grid frequency-

Answer 62

Number of grids per cm/inch

Question 63

high frequency grids show-

Answer 63

less distinct grid lines than low frequency grid

Question 64

frequency is increased by-

Answer 64

adding grid strips & thinning interspace material

Question 65

purpose of interspace material-

Answer 65

maintain precise separation b/w delicate led strips

Question 66

aluminum advantages-

Answer 66

-less visible grid lines
-nonhygroscopic
-easier to manufacture precise specifications

Question 67

non hygroscopic-

Answer 67

doesn’t attract water molecules

Question 68

interspace materials used are-

Answer 68

aluminum or plastic fiber (neither preferred, they do ab the same)

Question 69

aluminum disadvantages-

Answer 69

-absorption of primary beam resulting in higher pt. dose as mAs is compensated
-at low kVp, pt. dose may be increased by up to 20%

Question 70

grid casing is primarily made of-

Answer 70

aluminum or plastic

Question 71

grid casing provides-

Answer 71

rigidity & helps seal out moisture

Question 72

grid casing helps-

Answer 72

maintain cassette contact & protects grid

Question 73

grid casing job-

Answer 73

hold precise manufactured grid strips together in its proper place & seals out moisture from getting in

Question 74

contrast improving factor (k)-

Answer 74

ratio of contrast of a radiograph w: grid to the contrast of radiograph made w/o grid

Question 75

k for most grids-

Answer 75

b/w 1.5 & 2.5

Question 76

bucky factor (B) also called-

Answer 76

grid factor

Question 77

bucky factor (B) increase in-

Answer 77

amt. of technique required to achieve the same receptor exposure on a radiograph

Question 78

bucky factor (B) increases-

Answer 78

pt. dose

Question 79

parallel grid properly used-

Answer 79

results in grid cut off on lateral margins

Question 80

in a parallel grid, why doesn’t grid cut-off occur on top & bottom?

Answer 80

beam divergence doesn’t’t cross grid lines

Question 81

optical density decreases towards-

Answer 81

edges

Question 82

parallel grids more pronounced at-

Answer 82

short SID

Question 83

parallel grids clean up scatter-

Answer 83

in only 1 direction

Question 84

cross/cross hatch grids clean up scatter-

Answer 84

in all directions

Question 85

2 serious disadvantages of cross/cross hatch grids-

Answer 85

-positioning in critical
-any tube angle against grid will produce grid cut-off

Question 86

focused grids designed to-

Answer 86

minimize grid cut-off

Question 87

focused grids when used properly-

Answer 87

grid cut-off not visible

Question 88

focused grids are marked with-

Answer 88

intended focus distance & which side of grid faces tube

Question 89

in focused grids, led strips are angled to-

Answer 89

match beam divergence

Question 90

Dr.Hollis improved on Bucky’s grid by-

Answer 90

moving grid during exposure

Question 91

moving grids are called-

Answer 91

potter-bucky diaphragm

Question 92

2 types of moving grids-

Answer 92

-reciprocating (to & fro movement)
-oscillating (circular motion)

Question 93

disadvantaged of moving grids-

Answer 93

increased OID, increased image blur, & bulkiness of mechanics

Question 94

virtual grids are-

Answer 94

reconstructions of captured data

Question 95

virtual grids algorithms can-

Answer 95

identify scatter & remove their effect from radiograph

Question 96

virtual grids lead to-

Answer 96

lower pt. dose w: high quality images

Question 97

most common problem of grids-

Answer 97

improper positioning

Question 98

off-level grid-

Answer 98

most often caused by tube head mis-positioning

Question 99

off-level & off-center grids are

Answer 99

the same thing

Question 100

off center grid, tube is off center ___ & called ____ _____.

Answer 100

off center laterally, called lateral decentering

Question 101

off-center grid causes grid cut-off along-

Answer 101

entire radiograph

Question 102

off-focus grid is a focused grid using-

Answer 102

wrong SID

Question 103

off-center grids are further from focus distance the more-

Answer 103

severe the grid cut-off

Question 104

grid cut-off is more severe toward-

Answer 104

periphery (edges)

Question 105

off center grids have to have-

Answer 105

what side is toward the tube & what the focal distance is

Question 106

upside down grid-

Answer 106

if turn grid upside down, entire grid is an x-ray catcher

Question 107

proper grid ratio selection depends on 3 things-

Answer 107

-kVp increases, grid ratio should increase
-degree of clean up increases as ratio increases
-pt. dose in general- as ratio increases, dose increases

Question 108

pt. radiation dose increases w:-

Answer 108

increasing grid ratio

Question 109

high-ratio grids are used with-

Answer 109

high kVp exams

Question 110

pt. radiation dose at ____ ____ is less than at ____ ____.-

Answer 110

at high kVp is less than @ low kVp

Question 111

air-gap technique-

Answer 111

method of removing radiation scatter w/o using grid

Question 112

air-gap technique is an alternative to-

Answer 112

grids

Question 113

air-gap technique increases-

Answer 113

OID to 10-15 cm

Question 114

air-gap technique allows scattered x-rays to-

Answer 114

miss IR

Question 115

disadvantage of air-gap technique-

Answer 115

increase magnification & loss of recorded detail