13.1 Principles of X-Ray Imaging

X-ray imaging is a cornerstone of medical diagnostics, using radiation to create pictures of the body's internal structures. This section dives into the nuts and bolts of X-ray generation, how X-rays interact with different tissues, and the various methods used to capture and display these images.

Understanding these principles is crucial for grasping how X-rays work in medical settings. From the basic components of an X-ray tube to the latest digital detection technologies, this knowledge forms the foundation for more advanced imaging techniques like CT and mammography.

X-Ray Generation

Components of an X-ray Tube

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• X-ray tubes generate X-rays and consist of a cathode and an anode enclosed in a vacuum tube
• The cathode is the negative electrode that emits electrons when heated by a filament (tungsten)
• The anode is the positive electrode that attracts and collects the electrons emitted by the cathode (tungsten or molybdenum)
• A high voltage potential difference between the cathode and anode accelerates the electrons towards the anode

Types of X-ray Radiation

• Bremsstrahlung radiation is produced when the electrons are decelerated by the nuclei of the anode material, causing a continuous spectrum of X-rays
• Characteristic radiation occurs when the accelerated electrons interact with the inner shell electrons of the anode material, causing them to be ejected and resulting in the emission of X-rays with specific energies characteristic to the anode material (tungsten or molybdenum)
• The energy and intensity of the X-rays can be controlled by adjusting the voltage and current applied to the X-ray tube
• Filters (aluminum or copper) are used to remove low-energy X-rays that do not contribute to imaging and can cause unnecessary radiation exposure

X-Ray Interaction with Matter

Attenuation of X-rays

• Attenuation is the reduction in intensity of X-rays as they pass through matter due to absorption and scattering
• The degree of attenuation depends on the energy of the X-rays, the thickness, and the composition of the material (atomic number and density)
• Photoelectric absorption occurs when an X-ray photon is completely absorbed by an inner shell electron, ejecting it from the atom
• Compton scattering happens when an X-ray photon interacts with an outer shell electron, transferring some of its energy and changing its direction

Contrast in X-ray Imaging

• Contrast in X-ray imaging is the difference in attenuation between different tissues or structures
• High contrast allows for better differentiation between tissues with different densities (bone vs. soft tissue)
• Low contrast makes it difficult to distinguish between tissues with similar densities (different soft tissues)
• Contrast agents (iodine or barium) can be used to enhance the visibility of specific structures by increasing their attenuation

X-Ray Detection and Imaging

Radiographic Film

• Radiographic film is a traditional method of detecting X-rays that consists of a light-sensitive emulsion coated on a transparent base
• X-rays interact with the silver halide crystals in the emulsion, creating a latent image that is developed and fixed to produce a visible image
• The optical density of the film depends on the amount of X-ray exposure and the sensitivity of the film (speed and contrast)
• Disadvantages of radiographic film include limited dynamic range, need for chemical processing, and difficulty in image sharing and storage

Digital Radiography

• Digital radiography is a modern method of detecting X-rays that converts the X-ray signal into a digital image
• Computed radiography (CR) uses a photostimulable phosphor plate to capture the X-ray image, which is then read by a laser scanner and converted into a digital image
• Direct digital radiography (DR) uses a flat-panel detector to directly convert the X-ray signal into a digital image without the need for an intermediate step
• Advantages of digital radiography include wide dynamic range, immediate image availability, ease of image processing and enhancement, and efficient image storage and sharing

Flat-Panel Detectors

• Flat-panel detectors are a type of direct digital radiography detector that consists of a large array of pixel elements
• Indirect flat-panel detectors use a scintillator (cesium iodide) to convert the X-rays into visible light, which is then detected by a photodiode array and converted into a digital signal
• Direct flat-panel detectors use a photoconductor (amorphous selenium) to directly convert the X-rays into an electrical signal without the need for a scintillator
• Flat-panel detectors offer high spatial resolution, wide dynamic range, and fast image acquisition, making them suitable for a variety of X-ray imaging applications (general radiography, fluoroscopy, and mammography)