X-rays and image production

What are x-rays?

• They are high energy photons. Typically 0.01nm.Way beyond ultraviolet. 700nm=infra red 400nm=blue.

• Gamma rays are naturally occurring radiation in the same range.

How do we produce x-rays?

• Accelerate electrons at high energies (typically at over 70 kilo electron volts>70KeV ) into a tungsten target.

• 99% of the energy is released as heat and light.1% of energy is released as electromagnetic radiation in the desired range (useful x-rays). This energy is produced by the braking electron as they interact with other electrons convert their energy into electromagnetic radiation.

• Mean energy of the x-ray photons is 1/2-1/3 of KeV.• Output is proportional Zx(KV)2

How are x-rays attenuated?• This occurs by absorption and scattering of the x-rays.• Compton Scatter.-interaction with free electrons. Most of the electrons in

Carbon, Nitrogen and Oxygen are free. The photons are essentially scattered. The higher the energy of the photons, the more the scattering is in a forward direction. Dependant on Z.

• Photoelectric effect.-the energy of the photons displaces electrons in the K shell and is absorbed.

• In soft tissue PE=Compton in image contribution at about 30KeV• Photoelectric absorption increases tissue contrast but at a higher dose to

the patient.• Apart from mammography most diagnostic tests involve x-ray generated at

70 KeV or more. • The amount of signal generated at the receptor (or film blackening) is

proportional to (KV)2.mA• Therefore if you have a poor image and there is a marked difference

between radio density of the tissue being differentiated (e.g. insertion of pacing wires), then turn up the KV not the mA (less dose to the patient).

Forming the image

• Traditionally, the x-rays fix silver bromide crystal on the film to produce a radiograph (not x-ray).

• In fact the x-rays activate fluorescent screens, which give off light, which then interact with the silver bromide crystals.

• In digital films the x-rays activate multiple small detectors to produce an image.

• You should end up with an image which allows you to differentiate between bone, fat, soft tissue and gas

Post junctionalline

Ant junctionalline

Right atrium-abuts onto middle lobe

Inferior vena cavaLeft ventricle abuts onto the lingula a part of the left upper lobe

Left atrialappendage abuttsonto lingula

Right para tracheal line

Descending aorta abuttsonto posterior lower lobe

Superior megiastinum mainly onto anterior segnentof upper lobel

Aortic knuckle abutts onto apico posterior segment of upper lobe

Mediastinal structures and junctional lines

Toxic effects on patients

• Non stochastic (dose related). These should all be avoided in diagnostic radiology. Damage to skin, loss of hair, cataracts, radiation sickness.

• Stochastic (probability related). Carcinogenesis Increased probability with increased dose. Latent period of at least 5-10years.

Tissues in order of sensitivity

• Gonads

• Breast

• Bone marrow

• Lung

• Thyroid

• bone

We measure the dose in Sieverts

• 1Sv given to a thousand patients will produce 125 deaths.

• Chest radiograph 0.05mSv (flying to the US is worth about 7CXRs)

• Lumbar spine 2.15mSv• IVU 5mSv• Most tests are 0.5-5mSv• Barium Enema/CT Abdo-pelvis 8-10mSv

(this increases your cancer risk by 1 in 2000 or perhaps slightly higher)

Computerised Axial Tomography

King Tut having a CT scan

A fan of x-ray beams of high KV is produced. Essentially solve lots of simultaneous equations along the line of x-ray beam. In fact use a process of back projection and Fourier analysis.

CT IMAGES

• Typically at >150KeV. A lot of Compton scatter.• Essentially we divide the field being imaged into

lots of voxels (little cubes) and each tiny cube is allocated an attenuation value. We solve loads of equations to work out each attenuation value.

• Typically 512 x512, occasionally 1024 by 1024.• The spatial resolution is less than what is seen

on plane film.

Windowing and Houndsfield units

• Each voxel is given a value.• Densest bone (petrous temporal)-3000Hu.• Soft tissue typically 30-50Hu.• Water 0 Hu.• Fat -50 to-100Hu.• Air-1000Hu.• The problem is displaying all these values in an image

that we can interpret. The human eye can only use black through gray to white to show what we are interested in.

• We pick an appropriate level and window width.• We deal with this problem by using different settings to

interrogate different areas of interest.

Looking at the mediastinum and soft tissue of the chest.

• What is a typical value of soft tissue? Answer 30-40Hu,set this as our level.

• What is the range of values we are interested in? 150 would be enough.

• 40+150/2=115 which is bony. • 40-150/2=-35 which is fat.• This would be useless for the lungs as they look

uniformly black.• This would be useless for bone as it would al

uniformly appear white.

A

B

C

T3

Left major fissure more posterior

Left pulm artery arching over the Left main bronchus

Right main pulm artery travelling in front of Right main bronchus

T5