Entenda como o kV e o mAs influenciam na imagem radiográfica!

UniRadio Vet Online

12 Apr 202104:43

Summary

TLDRThis video script explains the workings of an X-ray machine, focusing on two key factors: milliamperage (mA) and kilovoltage (kV). The script describes how the mA controls the production of electrons by heating the filament, which ionizes tungsten atoms to generate X-rays. The kV, on the other hand, accelerates these electrons, increasing their penetration power. The interaction of these accelerated electrons with tungsten atoms creates two types of radiation: bremsstrahlung radiation and characteristic radiation, both producing X-rays. Overall, the script highlights the relationship between mA, kV, and the formation of X-rays, crucial for understanding radiology.

Takeaways

😀 The formation of X-rays occurs through a physical-chemical reaction in an X-ray tube.
😀 The X-ray tube consists of a negative side with a tungsten filament and a positive side (anode).
😀 The milliampere (mA) setting controls the negative side of the tube, heating the filament to produce electrons.
😀 The filament, made of tungsten, generates electrons when heated by the mA setting.
😀 Ionization occurs when atoms lose or gain electrons, forming a cloud of electrons around the tungsten filament.
😀 The mA setting directly influences the amount of X-rays produced by controlling the number of electrons.
😀 The kilovolt (kV) setting controls the positive side of the tube, attracting the electrons to the anode.
😀 When electrons hit the anode, they produce two types of radiation: braking radiation (producing X-rays and heat) and characteristic radiation.
😀 Braking radiation occurs when high-speed electrons are deflected by the atomic nucleus, releasing energy as X-rays and heat.
😀 Characteristic radiation happens when an electron knocks another electron out of an atom on the anode, causing an electron from a higher shell to fall to fill the vacancy, emitting X-rays.
😀 The kV setting determines the speed at which electrons travel, affecting the penetration power of the X-rays produced.

Q & A

What happens when the 'prepare' button is pressed on an X-ray machine?
-Pressing the 'prepare' button activates the negative side of the X-ray tube, which controls the milliampere setting to heat the filament and produce electrons through ionization.
What is the role of milliampere in the X-ray process?
-Milliampere controls the production of electrons in the X-ray tube. A higher milliampere results in more electrons, leading to the creation of more X-rays.
What does the filament in the X-ray tube do?
-The filament in the X-ray tube is heated to produce electrons by ionizing atoms of tungsten. This process is similar to how a light bulb or a clothes iron works, where resistance to electric current generates heat.
Why is tungsten used for the filament in the X-ray tube?
-Tungsten is used because it has a high melting point and excellent conductivity, making it suitable for producing the heat required to release electrons through ionization.
What happens when the 'exposure' button is pressed on the X-ray machine?
-Pressing the 'exposure' button activates the positive side of the X-ray tube, accelerating the electrons towards the anode. The electrons then collide with tungsten atoms, producing X-rays.
How are X-rays produced during the collision of electrons and tungsten atoms?
-The collision of high-speed electrons with tungsten atoms leads to two forms of radiation: braking radiation (X-rays and heat) and characteristic radiation (when an electron ejects an atom’s electron, causing an electron from a higher energy level to fill the gap).
What is the difference between braking radiation and characteristic radiation?
-Braking radiation occurs when an electron is deflected by the nucleus of a tungsten atom, losing energy in the form of X-rays and heat. Characteristic radiation happens when an electron from the beam displaces an electron from the tungsten atom’s inner shell, and another electron falls to fill the vacancy, emitting X-rays in the process.
How does kilovolt affect the X-ray production process?
-Kilovolt (kV) accelerates the electrons in the X-ray tube. The higher the kilovolt, the faster the electrons are accelerated, resulting in X-rays with higher penetration power.
What is the relationship between kilovolt and the penetration power of X-rays?
-The higher the kilovolt, the greater the acceleration of the electrons, which leads to X-rays with greater penetration ability, allowing them to pass through materials more easily.
How does milliampere impact the quality of an X-ray image?
-Milliampere influences the number of X-rays produced. A higher milliampere means more electrons are available to produce X-rays, which can lead to a clearer image due to more radiation being available for exposure.