Cómo FUNCIONAN los RAYOS X? 🤔 | TUBO DE RAYOS X partes y funciones ☢️ | ¡RADIACIÓN IONIZANTE !

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In order to properly understand the nature of x-rays, I think it is important that

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we understand how they are generated; In this graphic we have a representation of what

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an x-ray tube is. This is a term that I want you to be very clear about because we are going

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to use it throughout the course. I want you to keep in mind what an

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x-ray tube is and how it works, you will see that it is not something complex, that it is not something abstract,

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but rather that it really is an easy mechanism to understand, at least in theory, and that it is

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important to have this type of conceptual bases, to be able to learn in the best way everything

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related to the radiographic technique, and even with the interpretation of x-rays.

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This is an illustration that represents an x-ray tube, as I have been saying, we are going to recognize

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the most important parts, before going on to talk about how it works. So

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what parts make up an x-ray tube, so first there is a high voltage current,

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that high voltage current is represented through this part of the graph, and like all

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electrical current it has a positive side and a negative side. The high voltage is important to

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generate the type of electromagnetic radiation that we want to generate at this moment, which is

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radiation or x-rays, so this is the first component, a high

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voltage electric current. That electric current is connected to a cathode and the other end to an anode;

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These are the two main structures for the operation of the x-ray tube. In

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turn, this cathode and this anode are inside a vacuum chamber. We are going to see what is

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the importance of why they should be inside a vacuum chamber. vacuum, and the vacuum chamber in

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turn is inside a chamber that has a generally lead shield, a shield that

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does not allow x-rays to escape outside where we want the x-ray beam to be emitted.

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Let's review, we have the high voltage electric current, this electric current has a

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positive and negative charge, in turn each of the ends of the charge is attached to a cathode,

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where the negative charge is, and an anode where the charge is connected . positive charge. As we can see

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what we are going to generate through a high voltage electric current, it is a

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charge or voltage gradient in which we are going to have a side charged with negatively charged electrons and a

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positive side, that voltage difference is which will allow us to have an adequate functioning.

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Another important thing is that the anode has a mechanism to rotate, this mechanism that is

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represented here means that the anode is rotating, we are going to see that this is important

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to dissipate a bit of the heat generated by radiation. As you can see, both the vacuum chamber

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and the shielding are open at one of those ends and it is where we want the

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x-ray beam to exit, so all the radiation that is generated inside the vacuum chamber and inside the

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chamber of shielding, it will only go outside through this filter, which is generally

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adapted to a collimation system to adjust the x-ray beam to what we want to irradiate.

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Now we are going to see how it works, let's remember then that we have a cathode

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charged with a negative electric charge and an anode that has a positive charge,

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then, by increasing the voltage as such of this electric current,

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what we are going to generate is a gradient of voltage, where there will be a very

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negative voltage at one end and a positive voltage at the other, and to the extent that this kilovoltage,

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in that kilovoltage differential increases, the electrons that arrive here at the cathode will come out ,

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they will go out faster with more energy towards the anode, the greater the

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potential differential becomes, that differential between the voltage. So, in radiology

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kilovoltage differentials between 50 and 150 kilovolts are used, which is quite high, that is,

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on this side we would have approximately between 50 and 150 kilovolts, and on this side we would have a

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much smaller value so that these electrons are attracted to go to the other extreme.

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What is going to happen? When we increase the voltage there will be a flow of electrons

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through the cathode, which in turn will channel them through a filament so that

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they do not go out scattered throughout the entire chamber vacuum, but all that flow of electrons

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is going to be channeled through the filament, and due to the voltage gradient, they are going to go

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looking for the anode. Remember, here is the negative charge of the electrons and here is the

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positive charge of the anode, when the electrons shoot from the filament towards the anode, they

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collide and undergo a sudden deceleration process, since the anode is usually made

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of an element with a very high atomic number, which is tungsten, and the electron cannot advance, it

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brakes is a sudden braking, and that energy that it carries detaches it, throws it into the medium,

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in the form of a photon, so that is what we are going to represent with this graph, this illustration.

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That little yellow ball is the electron and this light that surrounded the electron is the photon. Let's

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see it again, as we see the electron leaves the filament towards the anode, attracted by the

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potential differential with great speed, but this is abruptly stopped by the anode,

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since it is made of an element with a very high atomic number and you can't get through it. But

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what happens with that energy that the electron carried, since it returns it to the medium in the form of a photon,

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and that photon is a high energy photon, we are going to see that this photon, the photons are the ones

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that make up the entire spectrum electromagnetic, and depending on the frequency of its wave it will

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be grouped into different spectra within the electromagnetic spectrum. In this case,

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the photon would come out with a frequency that corresponds to the frequency of x-rays,

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so this is the way in which x-rays are generated in medicine.

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I go back and repeat doing a kind of summary, there is a high voltage electrical charge,

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through which electrons flow from the cathode to the anode, the anode is made

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of an element with a very high atomic number, which means that it has a great density

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at the level of its atomic nucleus, and the electron is stopped once it passes with great speed,

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from the filament of the cathode to the anode it is stopped, and the energy that

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the electron carries is returned to the medium in the form of a photon, a high-energy photon

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carrying a frequency within the electromagnetic spectrum, clumps together in x-radiation.

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The reason why this chamber has to be in a vacuum is because if there were molecules of some

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kind of gas, of all the gases that make up normal air, they would interfere with the trajectory of the

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electron, and what we are looking for is that the electron does not deflect, lead to a straight path toward

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the anode. Most of the energy that is released in this process is heat, approximately

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90% of the energy in this process are not x but not heat, and that is why the anode must

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constantly rotate to dissipate the heat and also this is cooled by an oil system,

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thus also depending on the engineering of the x-ray tube, and only 10% of that energy

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is converted into x-ray type photons, only 10%. So, it is a quite inefficient process

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in which most of it is converted into heat, which is dissipated by rotating the anode and through

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a cooling system that the vacuum chamber must have; As you can see, this would generate,

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obviously, this is not a single electron, these are thousands of thousands of thousands of electrons, doing

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this process in milliseconds and in very short fractions of time, photons would come out in all

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directions, but, for a x-ray beam, leading in a definite direction the

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camera has to be plumb, yes, then that's why there has to be external shielding.

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This is the mechanism how it works in x-ray tubes in medicine,

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so again here the beam of photons that will make up the x-ray beam would come out.

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What are x-rays? To answer this question we necessarily have to know

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at least in a very basic way, the electromagnetic spectrum. The electromagnetic spectrum

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is quite broad, ranging from radio waves to gamma rays. So

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what does the electromagnetic spectrum depend on? of the wave frequency of the photon, then,

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the entire electromagnetic spectrum is made up of photons, remember that the photon is a quantum

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of energy, it is like a packet of energy and the photon has a quantum duality and it

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can behave like a particle , or as a wave. To understand the electromagnetic spectrum,

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it is easier to understand it from the wave behavior of the photon. Since every wave has a

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frequency and the frequency depends on the length of the wave, then, when the length of the

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wave is very wide, in the order of 10 to 3, we are talking about that spectrum, that photon,

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is within the spectrum of radio waves. From there the microwaves would continue,

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then the infrared, and from there we would arrive at the photons that make up visible light, that

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visible light is in the order of a very short wave frequency too, about the size of

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protozoa, this is like A comparison, then, of the size of the wavelength,

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and as you can see it is quite small, but in the quantum universe this is still very large,

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this can even be made much smaller, and if we make that wave smaller, we would arrive

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at the ultraviolet radiation, which is on the order of the size of a molecule and later

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we would arrive at x-rays, which are on the order of the size of an atom, and finally,

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the last mode of electromagnetic radiation that we know of so far is the gamma rays,

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which are about the size of an atomic nucleus, this is another form of ionizing

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radiation that is different from x-rays, so as I was saying, x-rays

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are a part of the electromagnetic spectrum, It is a part of the electromagnetic spectrum,

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where the photons that make it up have a very short wave frequency, now yes, we can

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see the technical definition. What are x-rays? they are a type of radiation within the electromagnetic spectrum

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, we already know that it is here whose wave is very high frequency as we see it here,

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and it is ionizing in nature so we are going to see right now what it means to be ionizing.

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Ionizing radiation, this term is going to be heard a lot in medicine, both in radiology

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and in nuclear medicine. Ionizing radiation, the simplest definition, is considered ionizing

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because it generates ions in matter, generate ions in matter, when these high-

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energy photons hit matter, they displace the electrons that make up the atoms of matter, they displace

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those electrons , whether they send them out of the atom or change their energy levels,

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in all cases the atom remains ionized and that is the effect of ionizing radiation. So

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when ionizing radiation enters the human body, what will generate the biological effect

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will be mediated by this because it generates ions. Well right now we are going to mention a little more

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about what it is that ions are formed within the human body or within any living tissue;

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but before that I want you to be clear about this difference. Ionizing radiation can be of

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two types, it can be through x-rays or it can be through gamma rays, which are not the same,

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I go back and repeat, x-rays have a wave frequency of the order of the size of an atom,

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while the wave frequency of gamma radiation is much smaller, about the size

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of the atomic nucleus. They are different radiations but both are ionizing. So, as I

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was saying now, representing the graph of the x-ray tube, if we saw we were only talking about the

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electron and the energy it gives off in the form of a photon, that is, x-rays have to do

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with extra-nuclear phenomena, that is, about the electronic orbit, at no time do we talk about

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the proton of the neutron, of all those annoying structures that make up the atomic nucleus

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called nucleons, none of this has to do with x-rays, only electrons,

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electrons that slow down and deliver their energy to the medium in the form of a photon,

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and generally this type of radiation is given by phenomena of deceleration of electrons,

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as we have seen, electrons coming from one side collide in an anode and release that high-

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energy photon. So, as we see here, they are extra-nuclear phenomena, they have more to do with the orbit

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of electrons and it is generally due to their deceleration phenomena. While the other

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type of ionizing radiation is good and this is the one used by medical radiology. The other type of

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radiation is gamma radiation, and gamma radiation is radiation of nuclear origin,

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since what I mean by nuclear origin, at least in medicine, most of the

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gamma radiation is produced by this phenomenon of disintegration of radioactive isotopes.

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Remember that an atom can have a stable nucleus, that it is in equilibrium and that it will not

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change if we do not modify it, but in nature there can be atoms with

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unstable nuclei, that is, with an odd number of protons and an odd number of neutrons, and that

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means that the atom is out of balance and is changing and that energy is delivered, that change in

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the structure of its atom, of its nucleus as such, it is delivered in the form of gamma radiation. So

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this radiation has to do with the nucleus of the atom, not with the orbit of electrons, and this type

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of radiation generally comes from isotopes and is what is used in nuclear medicine.

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So this is the big difference between radiology and nuclear medicine, both use

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ionizing radiation but in radiology x-rays are used, at least because the part that

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carries ionizing radiation, let's see which radiology has other diagnostic methods

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like ultrasound, electromagnetism, in the case of resonance, but nuclear medicine

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also produces ionizing radiation, but it does so through isotopes, which is a phenomenon

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of disintegration of these isotopes, which is a nuclear phenomenon. In both cases,

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ions are generated in matter, so the main ion that is formed, or at least the one that we know the most about,

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are the ions that form the radiolysis of water, radiolysis of water is the effect

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of radiation on water, and To summarize a bit, the type of ions that generate radiolysis

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of water are known as free radicals, among which the most important is hydrogen

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peroxide, this is the most toxic and is the one that generates a type of damage called indirect;

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Also, when ionizing radiation is very high, it can generate direct damage, especially

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in the DNA molecule, which could also be grouped into lethal damage and lethal damage,

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but that is a slightly more complex issue, which comes out as the purpose of this presentation.

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For now, I want you to be clear about what radiation is, that x-rays are part

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of ionizing radiation, but that there is also gamma radiation that is used in

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nuclear medicine and that we are not going to see this issue, we are going to focus on all in x-rays.

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X-rays, already going into detail about them, have the characteristics,

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in the first one is that they have a biological effect, then the radiation is attenuated when

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passing through the matter, which means that part of it is absorbed, producing lesions in

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living organisms and as I was saying, most of the human body is made up

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of water molecules, between 70 or 80% of the human body is water molecules, and there radiation is what

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generates radiolysis, and finally It is a somewhat long process, but what it generates in the end are

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free radicals, among which hydrogen peroxide is the most toxic and is the one that will

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mediate most of the harmful effects, at least in the doses that we use in radiology.

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It will also have a luminescent effect that produces fluorescence in certain substances

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called phosphors, this was initially used when a

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chemical development of the radiographic plate was made, today chemical development is not used so much,

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in fact it is already very scarce , what is done is to use a type of digital receivers,

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which capture the intensity of the photons and it is not done so much in a chemical development,

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but that is how radiology began with a chemical development, through luminescence,

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the effect of luminescence. The photographic effect is that, also through the luminescent effect, they

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impress and produce images on photographic film. And the ionizing effect, as we

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said, is actually called ionizing radiation because it ionizes matter.

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A bit of history, x-rays were discovered by the German physicist Wilhelm

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Conrad Röntgen in 1895 and he discovered them incidentally while working

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with cathode rays, in fact the x-ray tube is very similar to a cathode ray

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tube. He determined that these rays created highly penetrating but invisible radiation,

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which penetrated great thicknesses of paper and even thin metals. He

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used photographic plates and made the first human X-ray, using his wife's hand.

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At that time I call them unknown rays or x-rays, a man who to this day maintains,

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because he did not know that they were just that they were generated by cathode rays when colliding with certain

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materials. For this discovery, Röntgen received the Nobel Prize in Physics in 1901.

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With respect to the biological effects of x-rays, this is a fairly broad topic,

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radiobiology studies it extensively, but I only want to mention two aspects:

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that the rays the biological effects of x-rays could be grouped into two broad categories,

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deterministic effects and stochastic effects. Deterministic effects are those

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related to the type of radiation, radiation dose, exposure time,

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exposed organ, and age. What do I mean by deterministic, here we have to take into account

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the radiation dose, if we are more likely to have biological effects on the DNA,

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if we use high doses of radiation, while if we use low doses of radiation,

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the probability of damage in the DNA, or through either directly or indirectly will be much

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less. The same with the exposure time, it will be more likely that we will have more biological effects

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and if the exposure time is prolonged and it will be much less if we use

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short disposition times. The same happens with the organs, it is also more likely that we will have

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more effects and irradiate organs that have a high mitotic rate, such as the

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thyroid gland or the female or male gonads, differently from how we would irradiate, for example,

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only muscle. Also age, children for example when they are growing have a

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high mitotic rate and at that time the DNA is more susceptible to being damaged. Deterministic is that

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we can calculate the probability of damage, yes, we know that the higher the dose, the greater the risk,

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the longer the exposure time, the greater the risk. There are some organs that are more susceptible to radiation damage

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and also the age of the patient, so this is deterministic. On the other hand

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, we call the other biological effects stochastic because they depend solely

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on chance. Generally, 90% of the biological effects of x-rays are deterministic,

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that is, we can control them. But there are 10% effects of biological rays, of x-rays,

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that we will not be able to control and that is called stochastic. And all this damage,

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the biological effect generally at the dose that we handle in radiology,

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is through free radicals that are formed by radiolysis of water.

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There is also direct damage to the DNA, a helix can break, the double helix, well,

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as I was saying, this is part of the lethal, sublethal damage, but it occurs with very

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high doses of radiation. We have generally seen them in nuclear accidents, in nuclear plants,

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we know, for example, in the lethal dose of radiation of a human being, we know, for example, that with an

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exposure of 3 to 4 cybers, immediate death occurs in approximately 50% of cases. human beings

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, so these are data that we bring from the accidents at nuclear plants.

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But most of the biological effects in radiology doses, at least in radiology,

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are very low doses and in the order of millisieverts, not cyber but millisievers,

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and are given by free radicals, which are formed from radiolysis of water,

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among them the most toxic hydrogen peroxide and that these can be formed,

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by deterministic effects that are 90% and that we can control, and the stochastic ones

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that are less but that will always exist and we cannot control them alone they depend on chance.

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So this video tutorial is up to here, in the next one we are going to create a little bit of the

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exposure factors, we are going to talk about that topic. Thank you very much for your attention until then.