Principles of Radiographic Imaging CH 18: The Grid

Determining mAs when using grid

Grid conversion factor (GCF) = mAs with the grid/mAs without the grid. This formula is the Bucky factor, too.

How do grids work?

Photons going at an angle hit the lead strips and are absorbed.

For the grid to be properly focused

the x-ray tube must be located along the convergence line.

When an off-level grid error occurs

there is an undesirable absorption of primary radiation, resulting in a decrease in exposure across the entire image

If a grid ratio is higher,

photons have to go in a straighter path in order to reach the IR

Grid-conversion factors increase

with higher grid ratios and increasing kVp.

Distance from the face of the grid to the convergence line is called the

grid radius

K factor measures a

grid's ability to improve contrast Grids with a high ratio have high K factors

amount of scatter radiation increases with

increases in pt thickness larger field sizes decreases in atomic # of the tissue and increases in kVp

Scatter increases with

increases in the volume of the tissue irradiated and decreases with increased atomic number of the tissue, and increases when kVp is increased

What does scatter do to the image

increases radiographic density or IR exposure Decreases (lowers) contrast Descreases visibility of detail

Relationship b/w the distance between the lead strips and grid ratio when height of the grid is constant

inverse relationship

What is the grid's impact on visibility of detail

it will improve visibility of detail

As lead content increases

its ability to remove scatter and increase contrast increases

A 10" air-gap has the same degree of clean-up of scatter as a

15:1 grid for a 10 cm body part

What is the highest ratio for a grid

16:1

Parallel grid types are more or less commonly employed?

less - because of an increased grid cut-off at the edges where the beam is most divergent

Higher grid ratios allow

less scatter to pass through their interspace material to reach the IR

Parallel grids are best used at

long SIDs - when the most perpendicular portion of the beam is being used

First grid

1913 - Gustav Bucky - wide strips of lead 2 cm apart and in 2 directions.

As kVp increases

scatter increases and contrast is further impaired

grid cut-off

undesirable absorption of primary radiation - excessive loss of density

Most commonly used grids

85-103 lines/inch (33-41 lines/cm)

Most grids have contrast improvement factors b/w

1.5 and 3.5 - means that contrast is 1.5-3.5 times better when using the grid.

What is the disadvantage to aluminum as an interspace material

Absorbs some primary photons - an issue at lower kVps

Potter-Bucky diaphragm

Bucky - mounted below the tabletop and holds the cassette in place below the grid. It can move the grid so grid lines will be blurred. About 17x19" in order to cover a 14x17" cassette when placed either lengthwise or crosswise.

K factor

Contrast improvement ability

Why is lead the preferred material for the opaque strips?

High atomic # - for absorption inexpensive easy to shape into thin foil

To keep the Moire effect from happening

High-frequency grids of 103 lines per inch or greater should be used for digital IR systems when a stationary grid is needed.

Grid ratio increases if

Lead strip height is constant and distance b/w strips decreases Distance b/w lead strips is constant and grid height increases

What effect do grids have on patient dose

Pt dose is increased because mAs is usually adjusted when grids are in use

On focused grids,

SID must be set at the convergence line - grids are rated for SID ranges

What does the interspace material do?

Since it is radiolucent, it allows remnant photons to pass - but will still attenuate some

Selectivity

a criteria used to measure a grid's performance - if a grid is said to have a greater degree of selectivity, that grid absorbs a greater % of scatter vs. primary radiation. Selectivity = % primary radiation transmitted / % scatter radiation transmitted

Contrast improvement ability

a criteria used to measure a grid's performance - the best measure of how well a grid functions is its ability to improve contrast. Depends on the amt of scatter produced (controlled by kVp) and the volume of irradiated tissue. As the amt of scatter radiation increases, the lower will be the contrast and lower the contrast improvement factor. Formula: K = Radiographic contrast with the grid / radiographic contrast without the grid

The Moire effect

a grid error that occurs with digital IR systems when the grid lines are captured and scanned parallel to the scan lines in the imaging plate readers. Occurs with grids in stationary fashion for exams like portable radiography or translating hip images. In order for the Moire pattern to demonstrate, grid lines must be running in the same direction as the movement of the laser beam that is scanning the imaging plate.

Reciprocating grid

a motor drives the grid back and forth during the exposure for a total distance of no more than 2-3 cm

Generally, grids are

about one inch larger than the IR size.

Higher ratio grids

absorb more scatter decrease radiographic density or IR exposure increase contrast require greater positioning accuracy more prone to grid errors

Alternate scatter reduction method

air-gap technique

focused grids with lower grid ratios

allow for greater latitude in the alignment of the tube with the grid

Why is fiber preferred at lower kVp

allows more photons to pass - doesn't attenuate as much as aluminum Also lowers the patient dose

air-gap technique

an alternative to using a grid. Primary applications in magnification radiography and, to a lesser extent, in chest radiography. The technique involves placing the pt at a greater OID, creating an air gap b/w the pt and the IR. The amt of scatter reaching the IR will be reduced.

The encasing is

an aluminum cover to protect the lead strips and interspace material - to protect them from damage

Oscillating grid

an electromagnet pulls the grid to one side and then releases it during exposure. Moves in a circular motion within the grid frame

Grid cut-off results in

an excessive loss in density

Where are grids placed?

b/w the patient and the IR

A focused grid has a tube side and a receptor side

based on the angulation of the grid strips. Proper tube/grid alignment is essential to prevent undesirable absorption of primary radiation - grid cut-off

Why does mAs need to be increased when using grids

because density is decreased

A grid is employed when

body part thickness is over 10 cm kVp is above 60 - because scatter becomes enough of an issue to degrade the image

If one grid is 8:1, 103 lines per inch, and another is 12:1 ratio and 103 lines per inch,

both have the same frequency - the 12:1 means the lead strips are higher

What radiation do grids absorb

both scatter and some transmitted photons

What angulation is OK on linear grids

cephalic or caudal - parallel to grid lines in the Bucky system

long focal range grids (60-72")

chest radiography

field size can be kept to a minimum by

collimation

total quantity of lead in the grid

combo of the grid ratio and frequency - it is the grid's lead content that is most important in determining the grid's efficiency at cleaning up scatter.

Adding grids decrease

density

Focused grids

designed so that the central grid strips are parallel and as the strips move away from the central axis, they become more and more inclined. The strips would finally intersect at a point in space known as the convergence line.

Grid

device used to improve the contrast of the radiographic image by absorbing scatter radiation before it can reach the IR.

GCF and mAs have a

directly proportional relationship

An off-level grid error can occur with a

focused grid and it is the only positioning error possible with a parallel grid.

Which grid has a front and back

focused grids

Which grid is designed for a particular SID range

focused grids

Errors are more common with

focused grids - due to the decreased positioning latitude

Off-focus

focused grids are used at very specific distances identified as the focal range labeled on front of the grid. When a grid is used at a distance other than specified, an off-focus error results. The lead strips no longer match the divergence of the beam. Results in grid cut-off along the peripheral edges of the image.

short focal range grids (14-18")

for use in mammography

How is grid total lead content measured

grams/cm - determines its efficiency in removing scatter

Higher ratio grids require

greater accuracy in their positioning and are more prone to grid errors

Higher grid ratios require

greater positioning accuracy to prevent grid cut-off

Focused grids with low grid ratios allow

greater positioning latitude - means lead strips are further apart or are shorter - photons don't have to be perfectly aligned. Can be less accurate.

Angling across the grid strips results in

grid cut-off

Off-focus errors result in

grid cut-off along the peripheral edges of the image.

Grid lines can be seen when

grids are used in a stationary fashion - especially with low-frequency grids

criss-cross or cross-hatched grids

grids that place 2 linear grids on top of one another at right angles. No tube angulation is permitted since angulation would result in grid cut-off.

Linear grids

grids with lead strips running in only one direction. More common in clinical practice - can be used when performing procedures that require tube angulation ALONG the LONG AXIS of the grid.

Lead content is greater in a grid that

has a higher grid ratio and lower grid frequency

Grids with higher grid ratio and higher lead content

have greater selectivity

positioning latitude

how perfectly does the pt have to be so there's no grid cut-off

Direction in which the grid moves

important if it is to accomplish the job of blurring the grid lines. Must move at a right angle to the direction of the lines. Back and forth across the table and not top to bottom

1920, Hollis Potter

improved Bucky's grid design. Realigned the strips in just one direction, thinner strips, and then designed it to move during exposure.

What will an increase mAs do for the patient

increase pt dose

parallel grids

made with the lead and interspace strips running parallel to one another - they would never intersect.Less commonly employed than focused grids. Some grid cut-off will occur along the lateral edges, especially at short SIDs, because the strips don't try to coincide with the divergence of the x-ray beam. Best employed at long SIDs because beam will be straighter, more perpendicular beam.

Grid ratio

major influence on the ability of the grid to improve contrast. It is the ratio of the height of the lead strips to the distance between the strips. Grid ratio = h/d. If height is constant, decreasing the distance b/w the strips results in an increase in the grid ratio.

Moving the grid

makes the lead strips blur and are no longer visible on the image.

Lead content measure is

mass per unit area - or grams per square cm.

Focused grids with high grid ratios require

more positioning accuracy to avoid grid cut-off. Lead strips are closer together or have taller strips - photons may be cut-off. Need more positioning accuracy.

High grid ratio, high grid frequency and high lead content (grams/cm) means

more scatter absorption less density increased contrast

Mounted Bucky grids

move - reciprocating or oscillating - upon hitting exposure grid lines run parallel to the long axis of the table grid lines are blurred due to motion - moved at rt. angle to lines

Less scatter will reach the IR if the pt is

moved farther away - results in improved contrast without the use of the grid - air-gap

Grids used for flim/screen mammography studies

moving grids

Grid choice

must be made in the equipment purchase phase of quality control. Not easily changed. Generally made by the department administrator in collaboration with the radiologist.

Do grids prevent all scatter?

no

What effect do grids have on the production of scatter

no impact - they can only have an impact on scatter that is already produced

if K = 1

no improvement in contrast has occurred

Off-level grid error

occurs when the tube is angled across the long axis of the grid strips - improper tube or grid positioning. Common problem in portable procedures when detents do not ensure alignment Possible with both focused and parallel grids The ONLY error possible with parallel grids Results in loss of density/exposure across the entire image

what is the only grid positioning error that can occur with parallel grids

off-level error

what grid positioning errors are possible with focused gridgs

off-level, off-center, off-focus and upside-down

Grid types

parallel grids focused grids

Stationary grids are used for

portable exams grid lines will be evident

higher grid ratios

proper alignment of the grid with the tube is more critical

If mAs must be increased,

pt dose will increase

The efficiency of a grid in cleaning up or removing scatter can be

quantitatively measured.

Interspace material

radiolucent - aluminum and fiber. Aluminum is more common - easier to use in manufacturing and is more durable; higher atomic # than fiber, so it absorbs more low-energy scatter. Also can absorb primary photons (disadvantage with low kVp techniques). Fiber is preferred when using low kVp techniques - pediatric radiography.

What's in a grid

radiopaque lead strips side by side and separated by an interspace material which is radiolucent - usually aluminum

Grid materials

radiopaque strips of a dense material of high atomic #. Lead - inexpensive and easy to shape into very thin foil.

Exposure latitude

range of exposure factors that can be used for good diagnostic image.

Movements of grids

reciprocating oscillating

Very high-frequency grids (103-200 lines/inch)

recommended for stationary grids used with digital IR systems to minimize the possibility of seeing the grid lines on the image

ICRU Handbook 89 defines 2 criteria to measure a grid's performance

selectivity and contrast improvement ability

If a grid is used at a distance other than specified

severe grid cut-off will occur.

Upside -down

severe peripheral grid cut-off will occur. Radiation will pass thru the grid along the central axis where the grid strips are most perpendicular and radiation will be increasingly absorbed away from the center. Tech should check the tube side prior to using a focused grid. Divergence of the lead strips oppose the divergence of the beam. Drastic loss of density.

Grid cut-off is most pronounced at a short or long SID?

short

high frequency grids are recommended for

stationary grids to minimize grid lines on the image

grid uses

stationary position or mounted in a Potter-Bucky diaphragm

As the lead content of a grid increases

the ability of the grid to remove scatter and improve contrast increases

Grid radius

the distance from the face of the grid to the point of convergence of the lead strips

The higher the K factor

the greater the contrast improvement

The higher the K factor,

the greater the contrast improvement

the greater the degree of lateral decentering

the greater the grid cut-off

The better a grid is at removing scatter

the greater will be the selectivity of the grid

Grid cassette

the grid is built into the cassette - requires reloading b/w exposures using the grid. Inconvenient when multiple images are needed.

The greater the atomic number of the tissue

the less will be the scatter produced

Primary disadvantage of the air-gap techique

the loss of sharpness (recorded detail, resolution) that results from an increased OID

The patient is the source of

the majority of scatter

The higher the grid ratio,

the more mAs will need to be increased

grid frequency

the number of grid lines per inch or cm. A range in frequency of 60-200 lines/inch (25-80 lines/cm).

In order to pass through the interspace material in a grid with higher grid ratios

the scattered photon would have to be more closely aligned to the direction of the primary photon in order to reach the IR

The volume of tissue that is irradiated in controlled by

the thickness of the pt and the exposure field size

Scatter is bad because

they change direction in a random fashion and does not correspond to the patient's anatomy

interspace material is

thicker and usually made of aluminum

A grid's shape

thin, flat rectangular

Grids with higher grid frequencies have

thinner lead strips

High frequency grids have

thinner lead strips

Purpose of the grid

to improve (increase) contrast by absorbing scatter, thus decreasing radiographic density or digital IR exposure

What is the grid's main purpose

to improve contrast

What is the purpose of the interspace material

to keep the lead strips apart

Poor images can result from improper

use of the grid - occur mainly with grids that have a focused design because they are made to coincide with the divergence of the x-ray beam. Tube must be centered to the grid and aligned at the correct distance.

When converting from one grid ratio to another

use this formula: mAs1/mAs2 = GF1/GCF2 - need to use a table to determine GCF

Lead strips are

very thin foil

grid cut-off

when the primary beam is angled INTO the lead, the lead will absorb an undesirable amount of primary radiation resulting in this problem.

improper grid positioning most commonly occurs

with stationary grids in mobile procedures or decub views. eg. - a pt's weight is not evenly distributed on the grid - so the grid may not be properly aligned to the tube.

A grid with higher lead content

would have a greater selectivity

Off-center

x-ray tube must be centered along the central axis of a focused grid to prevent an off-center (off-axis or lateral decentering) grid error. Most of the perpendicular portion of the x-ray beam will not correspond to the most perpendicular portion of the grid - decrease in exposure across the entire image