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Explore: Investigate The Different Radioactive Isotopes You Have Saved.

X-rays are a vital imaging tool used around the globe. Since first being used to image bones over 100 years ago, the X-ray has saved countless lives and helped in a range of important discoveries. X-rays are a naturally occurring form of electromagnetic radiation. They are produced when charged particles of sufficient energy hit a material. Over the years, scientists have shown concern over the health implications of X-rays. After all, they involve firing radiation at the patient. But, do its benefits outweigh its risks? This MNT Knowledge Center article will discuss what X-rays are, how they are used in medical science, and the level of risk that they pose. Wilhelm Röntgen is credited with first describing X-rays. Just weeks after he discovered that they could help visualize bones, X-rays were being used in a medical setting. The first person to receive an X-ray for medical purposes was young Eddie McCarthy of Hanover, who fell while skating on the Connecticut River in 1896 and fractured his left wrist. Everyone on the planet is exposed to a certain amount of radiation as they go about their daily lives. Radioactive material is found naturally in the air, soil, water, rocks, and vegetation. The greatest source of natural radiation for most people is radon. Additionally, the Earth is constantly bombarded by cosmic radiation, which includes X-rays. These rays are not harmless but they are unavoidable, and the radiation is at such low levels that its effects are virtually unnoticed. Pilots, cabin crew, and astronauts are at more risk of higher doses because of the increased exposure to cosmic rays at altitude.There have, however, been few studies linking an airborne occupation to increased incidence of cancer. To produce a standard X-ray image, the patient or part of their body is placed in front of an X-ray detector and illuminated by short X-ray pulses. Because bones are rich in calcium, which has a high atomic number, the X-rays are absorbed and appear white on the resulting image. Any trapped gases, for instance, in the lungs, show up as dark patches because of their particularly low absorption rates. Radiography: This is the most familiar type of X-ray imaging. It is used to image broken bones, teeth, and the chest. Radiography also uses the smallest amounts of radiation. Fluoroscopy: The radiologist, or radiographer, can watch the X-ray of the patient moving in real-time and take snapshots. This type of X-ray might be used to watch the activity of the gut after a barium meal. Fluoroscopy uses more X-ray radiation than a standard X-ray, but the amounts are still extremely small. Computed tomography (CT): The patient lies on a table and enters a ring-shaped scanner. A fan-shaped beam of X-rays passes through the patient onto a number of detectors. The patient moves slowly into the machine so that a series of “slices” can be taken to build up a 3D image. This procedure uses the highest dose of X-rays because a large number of images are taken in one sitting. X-rays can cause mutations in our DNA and, therefore, might lead to cancer later in life. For this reason, X-rays are classified as a carcinogen by both the World Health Organization (WHO) and the United States government. However, the benefits of X-ray technology far outweigh the potential negative consequences of using them. It is estimated that 0.4 percent of cancers in the U.S. are caused by CT scans.Some scientists expect this level to rise in parallel with the increased use of CT scans in medical procedures. At least 62 million CT scans were carried out in America in 2007. According to one study, by the age of 75 years, X-rays will increase the risk of cancer by 0.6 to 1.8 percent. In other words, the risks are minimal compared to the benefits of medical imaging. Each procedure has a different associated risk that depends on the type of X-ray and the part of the body being imaged. The list below shows some of the more common imaging procedures and compares the radiation dose to the normal background radiation that all people encounter on a daily basis. Chest X-ray:Equivalent to 2.4 days of natural background radiationSkull X-ray:Equivalent to 12 days of natural background radiationLumbar spine:Equivalent to 182 days of natural background radiationIV urogram:Equivalent to 1 year of natural background radiationUpper gastrointestinal exam:Equivalent to 2 years of natural background radiationBarium enema:Equivalent to 2.7 years of natural background radiationCT head:Equivalent to 243 days of natural background radiationCT abdomen:Equivalent to 2.7 years of natural background radiation.These radiation figures are for adults. Children are more susceptible to the radioactive effects of X-rays. While X-rays are linked to a slightly increased risk of cancer, there is an extremely low risk of short-term side effects.Exposure to high radiation levels can have a range of effects, such as vomiting, bleeding, fainting, hair loss, and the loss of skin and hair.However, X-rays provide such a low dose of radiation that they are not believed to cause any immediate health problems. The fact that X-rays have been used in medicine for such a significant length of time shows how beneficial they are considered to be. Although an X-ray alone is not always sufficient to diagnose a disease or condition, they are an essential part of the diagnostic process. Some of the main benefits are as follows: Non-invasive: An X-ray can help diagnose a medical issue or monitor treatment progression without the need to physically enter and examine a patient.Guiding: X-rays can help guide medical professionals as they insert catheters, stents, or other devices inside the patient. They can also help in the treatment of tumors and remove blood clots or other similar blockagesUnexpected finds: An X-ray can sometimes show up a feature or pathology that is different from the initial reason for the imaging. For instance, infections in the bone, gas or fluid in areas where there should be none, or some types of tumor. It is important to keep the risks in perspective.An average CT scan might raise the chance of fatal cancer by 1 in 2,000. This figure pales in comparison to the natural incidence of fatal cancer in the US of 1 in 5. Additionally, there is some debate as to whether very low X-ray exposure can cause cancer at all. A recent report on the matter, published in the American Journal of Clinical Oncology, claims that X-ray procedures carry no risk. The paper argues that the type of radiation experienced in a scan is not enough to cause long-lasting damage. The authors claim that any damage caused by low-dose radiation is repaired by the body, leaving no lasting mutations. It is only when a certain threshold is reached that permanent damage can be produced. This threshold, according to the authors, is far higher than the standard X-ray dose from any type of scan. It is important to note that these safety facts apply to adults only. CT scans in children may triple the risk of brain cancer and leukemia, especially when administered to the abdomen and chest at certain doses. They are still performed but need to be done only after discussing the risks and benefits with the child’s family. The authors go on to point out that despite being bombarded by cosmic rays and background radiation, the people of America are living longer than ever, partly because of advancements in medical imaging, such as the CT scan. Overall, the importance of making the right diagnosis and choosing the correct course of treatment makes X-rays far more beneficial than they are dangerous. Whether there is a small risk or no risk at all, the X-ray is here to stay.

Video about Explore: Investigate The Different Radioactive Isotopes You Have Saved.

What Are Radioactive Isotopes? | Properties of Matter | Chemistry | FuseSchool

Learn the basics about radioactive isotopes.

The identity and chemical properties of any atom are determined by the number of protons in its nucleus. As atoms get bigger and heavier, the nuclei get bigger and heavier and the protons need a “nuclear glue” to help hold them together.

Neutrons provide this glue and prevent the positive charges of protons from repelling each other, thanks to something called the strong nuclear force.

Elements can exist with slightly different numbers of neutrons. We call these isotopes of an element.

The number of protons in isotopes of one element will always be the same; this means that the element is unchanged and so will react chemically in exactly the same way.

There is often more than one stable isotope of an element. Much of the world around us is made up of stable isotopes. However, sometimes there aren’t enough neutrons in a nucleus or there are too many for it to be stable.

Nuclei will try to stabilise themselves. If there are too many protons or too many neutrons, the nucleus can spontaneously rearrange itself and throw out particles in the process. This is essentially what happens in radioactive decay.

Isotopes that have unstable nuclei are known as radioactive isotopes or radioisotopes. The more unstable a nucleus, the faster it will try to rearrange itself into a more stable state. This is known as radioactive decay.

Radioisotopes are often used in medicine to trace aspects of body chemistry or blood flow. Atoms of radioisotopes can act as “markers”, allowing chemists to follow how a reaction sequence occurs. Radioisotopes are also used in radiotherapy to kill malignant cancer cells.

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