Physics of Diagnostic x-ray PDF

Summary

This chapter covers the physics of diagnostic x-rays. It explains how x-rays are produced and the different ways in which x-rays are absorbed and lose energy when passing through matter, as well as how the different elements interact/absorb x-rays differently. The chapter also discusses intensifying screens and grids that are involved in maximizing the use of x-rays for image clarity.

Full Transcript

Physics of Diagnostic x- ray

CHAPTER 16
Physics of Diagnostic x- ray

By; Dr.Khalid Ghanim Al ghabsha

In the 1895 ,W.C Roentgen was studying cathode ray in his
lab.
The field of radiology has three major branches;
1.Diagnostic radiology.
2.Radiation therapy.
3. Nuclear medicine.

Production of x- ray Beams;
A high speed electron convert some or all of its energy into
an x- ray photon when it strikes an atom.

The main components of a modern x-ray unite are;
1. A source of electrons a filament ,or cathode.
2. An evacuated space in which to speed up the electrons.
3. A high positive potential to accelerate the negative
electrons.
4. A target or anode ,which the electrons strike to
produce x- rays.

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In modern x-ray tube the number of electrons
accelerated toward the anode depends on the
temperature of the filament ,and the maximum energy
of the x-ray photons produced is determined by the
accelerating voltage – kilovolt peak (K VP ).

An X-ray tube operating at 80 K Vp will produce X- rays
with a spectrum of energies up to a maximum of 80 K eV.

The kilo volt peak used for an x-ray study depends on;
1. The thickness of the patient.
2. The type of study being done.

X-ray studies of the breast (mammography) are usually
done at 25 to 50 (K VP ) ,while some hospitals use up to
350 (K VP ) for chest x-rays.
The intensity of the x-ray beam produced when the
electrons strike the anode is highly dependent on the
anode material.

In general ,the higher the atomic number (Z) of the target
,the more efficiently x-rays are produced.

The target material used should also have a high melting
point.
Nearly all x-ray tubes use tungsten targets.

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The Z of tungsten is 74 and its melting point is about 3400
oC.

Since;

P=IV
Where; P is the power at the target of an x-ray tube in
(watt).
I is in Amperes.
V is in Volt.

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Line - Focus Principle;
A technique is used for increasing the area on the target struck
by electrons to avoid overheating without increasing the
blurring of the x-ray image.

The normal rotation rate of the anode is 3600 rpm and the heat
is spread over a large area as the anode rotates.
When a short exposure is used ,the anode does not always
make a full rotation at 3600 rpm and thus its full heat capacity
is not utilized.
For this reason , special high speed anodes that operate at rates
of up to 104 rpm where developed ,since any rotating object
can cause vibration if it not carefully balanced.
A resonance will occur at exactly the operating frequency of
104 rpm.

Bremsstrahlung ;
When one of the electrons get close enough to the nucleus of
the target atom to be diverted from its path and emits an x-ray
photon. It is also means braking radiation.

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How x-rays are absorbed;
The attenuation of an x-ray beam is its reduction due to the
absorption and scattering of some of the photons out of the
beam;
I =IO e-µx
IO is un attenuated beam intensity.
I is Intensity after attenuation.
e is equal to 2.718
µ is linear attenuation coefficient.
x is thickness of the attenuator.

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Physics of Diagnostic x- ray

X-ray are not absorbed equally well by all materials. Heavy
elements such as calcium are much better absorbers of x-ray
than light elements such as carbon ,oxygen ,and hydrogen ,and
as a result ,structures containing heavy elements ,like the
bones ,stand out clearly.
The soft tissues like fat, muscles ,and tumors all absorb about
equally well and are thus difficult to distinguish from each
other on an x-ray image.

Half Value Layer (HVL) ;
It is the thickness of a given material that will reduce the beam
intensity by one half.
𝟎.𝟔𝟗𝟑
HVL = µ

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Physics of Diagnostic x- ray

The mass attenuation coefficient ( µm) is used to remove the
effect of density when comparing attenuation in several
materials.
µ is the linear attenuation coefficient which is dependent on
the energy of the x-ray photons; as the beam becomes harder,
it decreases. Since the lead is used for shielding materials.

µ
µm = 𝝆

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µ
I = IO 𝒆 − (𝝆) 𝝆x

I= IO e-µm ρ x

Since;

𝐠𝐦
ρ=
𝐜𝐦𝟑
𝐠𝐦
ρx = 𝐜𝐦𝟐
𝐜𝐦𝟐
Mass attenuation coefficient µm = 𝐠𝐦

Linear attenuation coefficient µ = cm-1

X- RAY LOSS ENERGY ;
X –ray lose energy in three ways;

1. Photoelectric Effect;
All of the photon energy is given to the photoelectrons.

2.Compton Effect ;

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Some energy is given to an electron and some goes into a
scattered photon.

3. Pair production ;
A high energy photon is converted into an electron and a
positron (β+). The positron(β+) annihilates to form two
photons of 511 KeV each that go in opposite direction.
Since, a minimum of 1.02 MeV is necessary for pair production.

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CONTRAST MEDIA ;
Materials of high (Z) are often injected into different parts of
the body by the radiologists.

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1. Compound containing iodine are often injected into the
blood stream to show the arteries.
2. An oily mist containing iodine is sometimes sprayed into the
lungs to make the airways visible.
3. Barium compounds are given by radiologists orally to see
parts of the upper gastrointestinal tract (upper GI) and barium
enemas to view the other end of the digestive system (low GI
).
4.It is possible to use air a contrast medium.

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The amount of scattered radiation at the film ;

The amount of scattered radiation at the film depend on;
1. The energy of the x –rays.
2.The thickness of the tissue,
That the x- ray beam passes through is the most important
factor, so the thicker the tissue, making the greater of the
scatter radiation.
3.The larger of the beam;
When it is greater so, the scatter also greater , and thus one
simple way of reducing radiation is by keeping the x-ray
beam as small as possible.
The most significant way of reducing the amount of
scattered radiation striking the film is by using a grid
consisting of a series of lead and plastic strips.
The strips are aligned so the un scattered x-rays from the
source will go through the plastic strips and strike the film,
while most of the scattered radiation will strike the lead
strips and be absorbed. Since the lead strips do not
produce visible shadows on the image.
This grid is called a focused grid.
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Physics of Diagnostic x- ray

It is necessary to increase the exposure ;
1. To obtain an optimum darkness (optical density) of the
film.
2. A higher exposure must be given because the lead strips
absorb some of the un scattered radiation.

Intensifying screens ;
Most x-ray image are made on a special film sandwiched
tightly between two intensifying screens – cardboards
covered with a thin coating of crystal ( Ca WO4 ) that absorb
x-rays well, and give off visible or (UV) light (fluoresce)
when struck by x- rays.
The film is coated on both sides with a light- sensitive
emulsion, and each side takes a" picture" of the light from
the intensifying screen with which it is in contact.
Intensifying screens are much more efficient for making x-
ray image than film alone.
The screens are mounted in a cassette with a compressible
felt backing that holds the film and the screens in close
contact. To get a better contact, vacuum cassettes have
been developed.

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