Miscellaneous imaging II

Question 1

how does scatter reduce Contrast?

Answer 1

contrast = (P2-P1)/P
now with scatter, signal is P+ scatter
So contrast = (P2-P1)/(P+S)

Question 2

bucky factor

Answer 2

(patient entrance exposre with grid)/(patient entrance exposure without grid)
As kVp increases, bucky factor decreases

Question 3

grid ratio

Answer 3

(height of grid)/(width of holes in grid)

Question 4

grid selectivity

Answer 4

ratio of primary transmission to scatter transmission of grid

Question 5

contrast improvement factor of grid

Answer 5

(contrast achieved with grid)/(contrast achieved without grid)

Question 6

dark-field xray imaging

Answer 6

-makes scatter useful
-get infor about scattering power of specimen

Question 7

QA tests in safety code 35

Answer 7

-reproducibility- 10 exposures, small coefficient of variation
-AEC: vary kVp and thickness and ensure that OD varies less than limits
-linearity- |X1-X2|</=0.1(X1+X2)
-spectrum: min value for HVL at each energy
-max exposure rate for fluoro equipment

Question 8

breast tissues

Answer 8

glandular- makes milk
-fatty tissue
-fibrous tissue- provides support

Question 9

calcifications in breast

Answer 9

tiny mineral dposits
-small white regions on film

Question 10

microcalcification

Answer 10

sign of ductal carcinoma

Question 11

macrocalcification

Answer 11

-usually benign

Question 12

breast masses

Answer 12

can occur with or without calcifications
-cells clustered together with greater density than other tissues

Question 13

non-invasive (in situ) breast cancer

Answer 13

-ductal (milk ducts)
-lobula (milk making glands)

Question 14

invasive breast cNCER

Answer 14

-invasive ductal carcinoma starts in ducts and spreads

Question 15

energy used in mammo

Answer 15

10-15 keV
-get highest differences between glandular and infiltrating ductal carcinoma

Question 16

anode for mammo

Answer 16

Mo

Question 17

what does image quality and radiation dose in mammo depend on?

Answer 17

1. xray spectrum: anode material, operating kV, filtration
2. anti-scatter technique
3. image receptor

Question 18

limiting factor for detecting microcalcifications

Answer 18

signal difference to noise ratio

Question 19

what impacts signal difference to noise ratio?

Answer 19

-decreases as Energy increases
-decreases with thicker breasts (more attenuation)

Question 20

why ground the anode?

Answer 20

-reduces off-focus radiation which just adds dose to patient for nothing

Question 21

where is cathode in mammo?

Answer 21

at chest wall, to account for heel effect

Question 22

characteristics of modern mammo

Answer 22

-cathode is at chest wall to account for heel effect
-collimation to give shape (cuts off beam at chest edge)
-compression paddle
-detector is under the screen-film (normally for xrays it is on top). This is because low energy photons in mammo would cast a shadow on the image (high E photons pass through)

Question 23

focal spot size in mammo

Answer 23

0.3 mm and 0.1 mm

Question 24

space charge effect

Answer 24

-causes non-linear relationship between filament current and tube current

Question 25

characteristic radiation of Mo vs Rh

Answer 25

Mo: 17.5 and 19.6 keV Rh: 20.2 and 22.7 keV use Rh for thicker patients

Question 26

SID in mammo

Answer 26

65 cm

Question 27

how does focal spot change in mammo?

Answer 27

focal spot gets smaller away from chest wall

Question 28

target/filter combos in mammo

Answer 28

Mo/Mo Rh/Rh Mo/Rh No Rh/Mo Mo/Mo and Rh/Rh eliminate all energies above characterisitc Mo/Rh lets in a little bit higher energy than characteristic

Question 29

what does scatter in mammo depend on?

Answer 29

-scatter increases with increasing breast thickness and breast area, constant with kVp -reduce scatter by: -antiscatter grid -air gaps -compression

Question 30

how is mammo grid different than typical xray grid?

Answer 30

-4:1 ratio -interspace material is carbon fiber not lead (have lower E photons) -grid frequencies are 30-50 lines/cm for moving grids and 80 lines/cm for stationary

Question 31

when is grid used in mammo?

Answer 31

contact mammo

Question 32

why use moving grid?

Answer 32

grid moves while you acquire so you don't get image of grid lines in image

Question 33

how does compression help in mammo?

Answer 33

-reduce background (easier to see lesions) -fewer scattered xrays (better contrast) -reduces motion -reduces attenuation (lower dose to breast tissues)

Question 34

why use magnification in mammo?

Answer 34

-can gain more resolution because you spread over more pixels (resolution increases by magnification factor) -results in more blur, but can compensate by using smaller focal spot -if you use smaller focal spot, magnification gets you better MTF -increase SNR -reduce scattered radiation and can do without anti-scatter grid

Question 35

cons of magnification in mammo

Answer 35

-small focal spot limits tube current, and extends exposure times -therefore get more motion blurring

Question 36

are parrallax and crossover issues in mammo?

Answer 36

no, because only use 1 screen (not 2 with film sandwiched)

Question 37

resolution of screen-film system

Answer 37

15-20 lp/mm intrinsic efficiency 15 % green light 545 nm

Question 38

where is AEC in mammo?

Answer 38

under cassette (unlike normal xray)

Question 39

what does AEC do?

Answer 39

maintains constant mean OD of each mammogram independent of breast thickness, breast density, and selected exposure parameters

Question 40

mammography quality standards act

Answer 40

monitor dose due to mammo

Question 41

entrance skin exposure in mammo

Answer 41

500-1000 mR for 4.5 cm breast

Question 42

HVL in mammo

Answer 42

0.3-0.5 mm Al for 25-30 kVp 1 cm in tissue

Question 43

how does breast thickness affect entrance skin exposure

Answer 43

if kVp is constant, 1 cm increase in thickness requires double the mAs and entrance skin dose is thus doubled

Question 44

Dg factor in mammo

Answer 44

Dg = Dgn X entrance skin dose Dgn converts ESE to Dg Dgn depends on breast composition, thciness, anode, HVL, kVp, determined by computer Dgn decreaes as thickness increases because the beam is attenuated more and glandular tissues gets less dose. This is compensated by increase in ESE to get OD..

Question 45

MSQA annular dose limits

Answer 45

-avg glandular dose limited to 3 mGy/film for compresses breast thickness of 4.2 cm (50% glandular and 50% adipose tissue(

Question 46

what factors affect breast dose in mammo?

Answer 46

As kVp increases, -beam penetrability increases -ESE and Dg decrease -inherent subject contrast decreases -Dgn increases As breast thickness increases, -dose increases -ESE increases -Dgn decreases

Question 47

effect of thickness and energy on Dgn

Answer 47

as thickness increases, Dgn decreaes As energy increases, Dgn increases

Question 48

typical Dgn in mammo

Answer 48

0.2 rad/R

Question 49

typical entrance skin exposure in mammo

Answer 49

1000 mR

Question 50

advtantages of screen-film in mammo

Answer 50

-high resolution -inexpensive

Question 51

cons of screen-film in mammo

Answer 51

-limited latitude -film granularity contributes to nouse -processing -can't post process

Question 52

digital has ___ latitude compared to screen film

Answer 52

wide

Question 53

digital mammo targets and filters

Answer 53

-tungsten target -Rh or Ag filter

Question 54

advantages of digital mammo

Answer 54

-improved latitude -use window and level to improve contrast -processing analysis and software -digital storage, can be transmitted for 2nd opinions -higher kVp = shorter exposure time -no film processing

Question 55

disdadvantages of digital mammo

Answer 55

-5-10 lp/mm vs 20 for film -(but digital has better contrast resolution) -4X price of screen film

Question 56

per clinical trials, which is better, screen film or digital mammo?

Answer 56

the same

Question 57

how do CR plates work?

Answer 57

-absorbed xray energy is stored -imaging plate is exposed and read -scanned by laser beam, which causes stored energy to be released as light -light is collected by light guide and sent to PMT -image plate can be reused by exposing it to bright light

Question 58

how do charged coupled devices work?

Answer 58

-has discrete pixel electronics -when visible light falls on the pixels, electrons are liberated and stored in each pixel and read out later -light released by intensifying screen is focused onto CCD surface by fiber optic tapers

Question 59

how do indirect detection flat panel detectors work?

Answer 59

-CsI converts xrays to light, which is then detected by flat panel detector -detector elements (photodiodes) build up charge when exposed to light -charge is held by capacitor and can be read out by electronics

Question 60

how do direct amorphous selenium detectors work?

Answer 60

-when xrays stroke the selenium layer, electrons are released and they travel to the detector elements under direction of electric field -no blurring- path of electrons is controlled by electric field

Question 61

pros and cons of flat panel detectors in mammo

Answer 61

-at lower spatial frequency, flat panels have a higher DQE than CR plate and screen-film -expensive

Question 62

tomosynthesis in mammo

Answer 62

-no grid -taken at different angles -helps resolve overlapping tissues -low dose exposures -needs high DQE selenium detector -images acquired from different angles separate structures at differing heights -reconstruct image using backprojection

Question 63

stereo breast biopsy

Answer 63

-use 2 xray images at angles to get depth of lesion -needle targets coordinates

Question 64

dual energy contrast enhanced digital mammo

Answer 64

-images are acquired pre and post contrast -exploit differences in iodine u below and above iodine k-edge -low energy- 26-30 keV -high energy- 45 keV -images are subtracted by weighted log subtraction

Question 65

mammo image quality QA tests

Answer 65

-artifact evaluation -HVL evaluation -resolution evaluation -dose evaluation -image quality evaluation -SNR and CNR evaluation

Question 66

HVL requirement for mammo

Answer 66

-HVL > kVp/100 + some constant constant 0.03-0.3 mm depending on filter

Question 67

how to do dose evaluation in mammo

Answer 67

-Use ACR mammo phantom -stimulates xray attenuation of a 4.2 cm compressed breast (50% glandular, 50% adipose) -measure ESE -use conversion tables to get Dg -Dg< 3 mGy

Question 68

image quality evaluation in mammo

Answer 68

-use ACR phantom -must see at least 4 largest fibres, 3 largest speck groups, and 3 largest masses

Question 69

MRI for breast imaging

Answer 69

-breast MRI and mammo recommended for women at risk -MRI more useful for detecting invasive breast cancer but less so for microcalcifications

Question 70

Is US useful in breast cancer screening?

Answer 70

no, because it cannot detect microcalcifications it can detected: -distinguish solid lump from cyst -guide biopsy needles -detect metastases in lymph nodes

Question 71

what is US useful for?

Answer 71

-imaging soft tissues that are radiologically similar

Question 72

US- what converts electrical signal into mechanical vibration?

Answer 72

transducer

Question 73

US typical pulse duration and pulse repetition time

Answer 73

-duration = 1 us -repetition = 1 ms

Question 74

propagation of US through homogeneous medium vs through heterogeneous medium

Answer 74

homogeneous= attenuation heterogeneous = reflection or refraction

Question 75

what info does time span of echo give?

Answer 75

-info about depth/distance of boundary

Question 76

what info does amplitude of echo give?

Answer 76

-info about degree of physical difference between the 2 media

Question 77

sounds velocity in tissue, air, bone

Answer 77

tissue: 1540 m/s air: 330 m/s bone: 4100 m/s

Question 78

equation for frequency bw vs pulse duration in US

Answer 78

delta f * delta t = 1/(2pi)

Question 79

velocity of sound in a medium

Answer 79

c = lambda f

Question 80

decibel

Answer 80

dB = 10log10(I2/I1) -3dB = 0.5 + 3 dB = 2

Question 81

dB/cm loss

Answer 81

4.343 * u

Question 82

frequency dependence of rate of attenuation in US

Answer 82

dB/cm = dB/CM at 1 MHz * f for muscle, blood, soft tissue dB/cm = dB/cm at 1 MHz * f^2 for water, bone

Question 83

in US, what do incident, reflected, and refracted waves have in common?

Answer 83

frequency

Question 84

Snell's law

Answer 84

(lamda1/lambda2) = c1/c2 sin(theta1)/sin(theta2) = c1/c2 -if c1=c2, no refraction -if theta1=theta2, no refraction

Question 85

US fraction of energy reflected (R) and transmitted (T)

Answer 85

R = [(z1/cos(thetat) - z1/cos(thetai))/((z2/cost(thetat)+z1/cost(thetai))] ^2 T = 1-R Z = density * c

Question 86

what is transducer made from?

Answer 86

piezoelectric crystal -crystal with no bulk polarization, but with local zones of polarization

Question 87

US axial resolution

Answer 87

axial resolution = N * lambda -N = # of complete cycles of wavelength lambda contained in a single pulse

Question 88

US lateral resolution

Answer 88

-lateral resolution = lambda * F /(2a) F= focal length 2a = aprerture of transducer

Question 89

DOF in US

Answer 89

-defines volume for which the beam provides beam echoes from boundaries and max lateral resolution -within DOF, beam intensity is -3dB (or 50%) of max intensity or greater

Question 90

trade-off between resolution and penetration in US

Answer 90

-axial and lateral resolution are improved by increasing frequency -but dB/cm is proportional to f or f^2 -penetration thus decreases with increasing f

Question 91

optimal transducer material

Answer 91

-would have impedance = skin impedance so less energy is reflected at transucer-skin interface -the more energy is reflected at the interface, the less energy is available for producing echoes -reflection increases with differences between acoustic impedances

Question 92

impedance matching gel

Answer 92

helps to match impedance of transducer to that of kin Zmatch = square root (ZtransducerZskin)

Question 93

natural resonance frequecy in US

Answer 93

-Q value --frequency at which electrical energy is most efficiently converted into mechanical energy freson= Ct/2t Ct= velocity of sound in crystal t= thickness of crystal

Question 94

characteristic frequency in US

Answer 94

-tau -time it takes for crystal to decay from resonant state to unexcited state -want short tau so that after excitation, crystal can quickly detect echoes -tau = Q/(2pifres) -tau can be decreases with electronic or mechanical damping

Question 95

fresnel zone in US

Answer 95

-near zone -zone over which beam retains the cross-sectional area of the crystal

Question 96

fraunhoffer zone

Answer 96

-far zone -beam diversges with phi= arcsin(1.2lambd/D) D= diameter of transducer

Question 97

3 measures to quantify intensity of US beam

Answer 97

It= W/A = time-averaged power/effective area of transducer surface Tspta = energy flow through area through time, at pt of peak intensity within beam, as average over long period- spatial peak temporal averaged Isppa= intensity at pt of peak instensity within beam as average over single pulse- spatial peak pulsed average

Question 98

focused transducers in US

Answer 98

-improves lateral resolution, beam penetration, and echo strength -use curved piezoelectric crystal- get constructive interference at a pt -or use flat crystal with focused acoustic lens -drawback is that focal pt is fixed...

Question 99

phased array crystal in US

Answer 99

-array of crystals that can be excited independently -by exciting crystals with certain time delays, depth focusing (increasing or decreasing focal length) and steering (moving focal pt laterally) can be achieved

Question 100

scattering vs reflection in US dependence on object dimension (d)

Answer 100

-d>>> lambda- get strong echoes -d<< lambda- get scattering (speckle) -d~lambda- get graininess- adds structure to the texture

Question 101

A-mode

Answer 101

-fast -only shows depth at which boundaries occur along single line in medium -no image -depth of echo = C * echo time /2

Question 102

M-mode

Answer 102

-only single line through medium -image rapid movement -stationary boundaries make horizontal lines -moving boundaries make periodic oscillations -

Question 103

B-mode

Answer 103

2D image in real time -intensity of pixel is proportional to echo intensity received corresponding to that pixel

Question 104

US echo signal processing

Answer 104

-don't want attenuation effect, what is of value is ratio of reflected to transmitted -echoes at deeper regions produce weaker intensity due to attentuation and reflection at boundary -echo may be many orders of magnitude smaller than transmitted pulse and therefore echo signals are subjected to log amplification instead of linear amplification

Question 105

time gain compensation

Answer 105

in US, compensates for attenuation effects by amplifying echoes by amt. proportional o time since the pulse transmission -log amplification and time gain compensation reduce the effects of attenuation, but cannot improve the loss of signal due to noise from echoes from deep structures

Question 106

noise rejection electronics

Answer 106

-can be used to remove weaker signals from real echoes -risk rejecting weak echoes

Question 107

doppler US

Answer 107

-measure flow rates for vessels -frequency shift in echo results from interaction of pulse with a moving structure -not like M-mode, which measures motion of large organs

Question 108

formula for doppler US

Answer 108

delta f / ftrans = +/- 2 (vblood/c) * cos(theta) theta = angle between beam direction and that of flow +2 if towards transducer, minus if away

Question 109

continuous vs pulsed US beams for doppler US

Answer 109

-both can be used -simpler to demodulate a continuous beam (composed of a single frequency), than to demodulate a pulse containing many frequencies

Question 110

sound waves cannot...

Answer 110

travel in vaccuum

Question 111

frequency of sound waves

Answer 111

infrasouns < 15 Hz audible 15Hz-20 kHz ultra sound > 20 kHz US - 0.8- 15 MHz

Question 112

to get final attenuation in US...

Answer 112

add up dBs

Question 113

what is Z in US

Answer 113

z = density * c "Rayl" acoustic impedance

Question 114

does everyone but patient wear Pb apron in fluoro?

Answer 114

yes

Question 115

x-ray equipment must abide by what?

Answer 115

FDA radiation emitting devices act

Question 116

how to determine CT slice thickness for helical scanning

Answer 116

measure FWHM of bead senstivity profile as functiun of z position

Question 117

how do you QA the function of AEC?

Answer 117

by measuring resulting OD

Question 118

dose limit for techs and students training on DI equipment

Answer 118

1 mSv/year

Question 119

max leakage radiation from x-ray tube

Answer 119

1 mGy/h at 1 m from focal spot

Question 120

how to measure CT uniformity

Answer 120

subtract CT number at middle from that of periphery -should be within 2 HU of baseline and baseline should be within 5 HU

Question 121

shielding calcs for CT

Answer 121

NCRP 147 secondary only

Question 122

radiation symbols on CT equipment

Answer 122

xrays-attention-rayonx -trefoil symbol or xray tube in upside down triangle