You have probably come across the question what are free radicals in the body and are wondering exactly what they are. These are simply highly reactive molecules manufactured in the body. They are manufactured through a natural body process as an end product of oxidation (metabolism), and by exposure to readily available toxins in the environment such as ultraviolet light and tobacco smoke.
It is worth noting that they often come as an unpaired electron, and for them to be stable, they have to constantly search for another lone electron in which they will bound. Another thing worth noting is they are often responsible for a myriad of processes and complications in the human system, top among them tissue damage, aging, and a couple of diseases linked to these radicals.
The best explanation of these molecules is that they are termed as "free" because they are always in search of other molecules to make them stable. They are further termed as "radicals" because they are available in millions and can find a pair to stabilize with from so many other molecules. It is worth mentioning that the stabilization process can wreak havoc on an otherwise healthy system. This is because it starts a snowball effect once the lone molecule finds a pair, the donating molecule assumes the new title of "free radical", and the chain continues.
Some of the diseases linked to these include cancer, heart disease, glaucoma, rheumatoid arthritis, Alzheimer's disease, Parkinson's disease, and mucular degeneration often associated with aging.
The good news is that the lone molecules can be stabilized and the degenerating effect brought to a halt, all thanks to antioxidants. Note that the process of stabilization destroys so many healthy tissues, hence the need to put to an end to the degenerative process.
There is reason to believe that antioxidants, e. G., Vitamin E, Vitamin C, and betacarotine, selenium, lycopene, lutein, lipoic acid, and resveratrol, can significantly reduce the damage brought about by the lone electrons in the human system. This they do by inhibiting the formation of the molecules in the first place. Antioxidants are vital molecules, present in most foods, which help prevent the lone electrons form affecting healthy tissue. In other words, they neutralize the free radicals thus protecting healthy body tissues against oxidative stress.
While these antioxidants are readily available in the market in supplement form, it is worth mentioning that they can also be derived from a number of natural remedies and foods. These foods include goji berries, cocoa, black tea, chokeberry, acai, oolong tea, medicinal mushrooms, white tea, wheatgrass, and tart cherries to mention but a few. Most vegetables and fruits are also believed to be potent sources of antioxidants, and so are proteins and grains.
What are free radicals in the body and how to stabilize them can best be understand when one understands what a free radical scavenger is. Take your time to learn of this vitamin, mineral, or enzyme that you can include in your daily diet and which can help inhibit the snowball effect and destroy the lone molecules. The best way to protect your body from these molecules and ensure no further damage is done is to look for the best scavenger.
It is worth noting that they often come as an unpaired electron, and for them to be stable, they have to constantly search for another lone electron in which they will bound. Another thing worth noting is they are often responsible for a myriad of processes and complications in the human system, top among them tissue damage, aging, and a couple of diseases linked to these radicals.
The best explanation of these molecules is that they are termed as "free" because they are always in search of other molecules to make them stable. They are further termed as "radicals" because they are available in millions and can find a pair to stabilize with from so many other molecules. It is worth mentioning that the stabilization process can wreak havoc on an otherwise healthy system. This is because it starts a snowball effect once the lone molecule finds a pair, the donating molecule assumes the new title of "free radical", and the chain continues.
Some of the diseases linked to these include cancer, heart disease, glaucoma, rheumatoid arthritis, Alzheimer's disease, Parkinson's disease, and mucular degeneration often associated with aging.
The good news is that the lone molecules can be stabilized and the degenerating effect brought to a halt, all thanks to antioxidants. Note that the process of stabilization destroys so many healthy tissues, hence the need to put to an end to the degenerative process.
There is reason to believe that antioxidants, e. G., Vitamin E, Vitamin C, and betacarotine, selenium, lycopene, lutein, lipoic acid, and resveratrol, can significantly reduce the damage brought about by the lone electrons in the human system. This they do by inhibiting the formation of the molecules in the first place. Antioxidants are vital molecules, present in most foods, which help prevent the lone electrons form affecting healthy tissue. In other words, they neutralize the free radicals thus protecting healthy body tissues against oxidative stress.
While these antioxidants are readily available in the market in supplement form, it is worth mentioning that they can also be derived from a number of natural remedies and foods. These foods include goji berries, cocoa, black tea, chokeberry, acai, oolong tea, medicinal mushrooms, white tea, wheatgrass, and tart cherries to mention but a few. Most vegetables and fruits are also believed to be potent sources of antioxidants, and so are proteins and grains.
What are free radicals in the body and how to stabilize them can best be understand when one understands what a free radical scavenger is. Take your time to learn of this vitamin, mineral, or enzyme that you can include in your daily diet and which can help inhibit the snowball effect and destroy the lone molecules. The best way to protect your body from these molecules and ensure no further damage is done is to look for the best scavenger.
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