Apps of nuclear physics in medicine

[anju]

how images of body organisms are are formed in positron emission tomography...?

 

[Hologram0110]

You're asking how PET scaner work?

Basically, you give a radioactive dye to someone (injected or ingested depending on what you want to image). The radioactive die emits positrons (anti-electrons) as it decays. The positrons slow down and pair up with an electron and the two annihilate each other, giving off two photons with 511 keV going in opposite directions. Some of these photons make it out of the body and get captured by detectors.

In order to form an image, you look for times when detectors on opposite sides of someone go off at the same time. You then draw a line between them. Keep doing this for thousands or millions of events. The number of lines that pass through an area tell you roughly how much dye was there in 3D.

You can do neat things like attach the radioactive dye to sugar molecules, and the body brings it to places to be metabolized. Thus you can 'see' metabolic activity, which can indicate problems like tumors.

 

[anju]

such coincidence identification is carried out by a coincidence electronic ckt .it is found that some small animal PET scanners offers possibility of recording individual single events .what's its advantages...?
advantages and working principle of FPGA based digital coincidence engines...?

 

[Hologram0110]

I'm not an expert on imaging technology, but I'll give it a shot.

In a PET scanner you want to produce an image from the pair of 511 keV photons going in opposite directions. The reason for this is it gives you two point (detectors) to draw a line between which represent possible locations for the source. Its pretty unlikely that two 511 keV photons arrive at opposite detectors at roughly the same time if they are not from the same source/event. Therefore you can use a coincidence window to identify event pairs.

If you wanted to be fancier, you could use other methods for identifying the pairs. Light travels at roughly 1 foot per nanosecond. Thus, if you knew the exact time the photon arrived at both detectors, you could figure out where on the line between them the light originated. However, nanosecond level timing is exceptionally difficult requiring very specialized electronics and accounting for the time taken by the physical processes (such as charge collection and amplification).

If you record every event instead of just coincidence pairs, you could try to use other methods to produce an image. For example, you could include the probability that particles are attenuated by the body. These methods require MUCH more computer power, but in theory can extract more information from the scan.

FPGAs is just a fancy high speed logic/electronics kits. For example you can use more complicated logic to decide if something is from the same event. For example, you don't need to assume the detectors are exactly opposite each other (because if the photons were produced off-center the line would be a cord instead of a diameter).

 

[alphy]

Nuclear physics plays a crucial role in modern medicine, particularly in the field of medical imaging. One of the most widely used applications of nuclear physics in medicine is in positron emission tomography (PET) imaging.

PET imaging uses positron-emitting radioactive isotopes, which are produced in nuclear reactors or particle accelerators, to image the metabolic activity of cells in the body. These isotopes are injected into the patient and then detected by a PET scanner, which creates detailed images of the body's internal structures and functions.

The images produced by PET scans are formed through the process of annihilation, in which a positron collides with an electron, resulting in the release of two high-energy photons in opposite directions. These photons are then detected by the PET scanner and used to create an image of the body's metabolic activity.

The ability to visualize and measure the metabolic activity of cells in the body has revolutionized the diagnosis and treatment of various diseases, including cancer, neurological disorders, and cardiovascular diseases. PET imaging has also been used in drug development and clinical trials, allowing researchers to track the effectiveness of new treatments and medications.

In conclusion, the use of nuclear physics in PET imaging has greatly advanced the field of medicine and has had a significant impact on patient care and treatment. It is a prime example of how scientific advancements can be applied to improve the health and well-being of individuals.