Free radicals are the highly unstable chemicals that attack, infiltrate, and injure vital cell structures. Most stable chemical compounds in the body possess a pair of electrons. Sometimes, one member of the electron pair gets stripped away. The resulting compound (less one electron) is called a free radical.

In chemistry, the term free radical means that it is now free to combine with another element to form a new stable compound. One way to think of free radical is the way our social system work. In a family there is husband and wife. They are joined together. Both are “tied up” or not available for other partners. Now, for some reason they get separated. Now both mates can look for another person to join together. The way free radicals work, one of these free spouse go and breaks up a stable marriage of another couple, by joining with one of the spouses. This result in the ouster of a person from that family creating a brand new “free radical” that goes around prowling to find another “compound” to attack. You can see that free radicals can do lot of harm by forming a chain reaction.

A similar thing happens with free radicals in the body. When a free radical is born, it goes around the body looking for another compound to steal an electron from. This breaks up this “contented” couple that result in releasing another free radical, and so on. While on the prowl, these free radicals (which are really the oxidation products from the body) can do tremendous damage to the delicate machinery of our cells, in those that produce dopamine. The most studied free radical chain reaction in living things is lipid peroxidation. (The term lipid refers to any fat-soluble substance, animal or vegetable. Peroxidation means the formation of a peroxide molecule. These are the molecules with the greatest proportion of oxygen molecules. For example, water molecule has two hydrogen atoms and one oxygen atom. Hydrogen peroxide has two Hydrogen atoms and two oxygen atoms. In other words, there is an excess oxygen atom in hydrogen peroxide.)

Ninety eight percent of the oxygen we breathe is used by tiny powerhouses within our cells called mitochondria that convert sugar, fats and inorganic phosphate (ADP), oxygen into adenosine triphosphate (ATP), the universal form of energy we need to live. This energy producing activity of the mitochondria involves a series of intricate, complex and vital biochemical processes dependent on vast numbers of enzymes (estimates vary from 500 to 10,000 sets of oxidative enzymes). These, in turn, are dependent upon dozens of nutrient factors and co-factors. In this metabolism process a very small amount of left over oxygen loses electrons, creating free radicals. These free radicals burn holes in our cellular membranes. Calcium penetrates our cells through these holes. This excess calcium results in cell death. This, in turn, weakens tissues and organs. As this damage continues, our body becomes “rusty”, less able to fight other invaders such as cancer, hardening of the arteries, premature aging, and other bodily disorders. See why the chemicals we ingest, the air we breathe and the fluids we drink are vital to our health.

In addition to the oxygen we breathe, the free radicals can also come from such things as environmental pollution, radiation, cigarette smoke, chemicals, and herbicides.

The key to having a healthy body is to repair the damages caused by the free radicals before it is too late, and to protect the body’s tissue cells from the free radicals before they cause mutations. Antioxidants are substances that have free-radical chain-reaction-breaking properties. Like a bouncer, the antioxidants deactivate potentially dangerous free radicals before they can damage cells machinery. Most of these antioxidants come from plants and are called phytochemicals. More than 60,000 such plant chemicals are identified. Among the most effective and dedicated antioxidants are Vitamin A, C, and E (known as the ACE trio against cancer.). Out of these, Vitamin C is the most powerful.

Each cell produces its own antioxidants. But the ability to produce them decreases as we age. That is why diet rich in anti-oxidant and phytochemical rich fruits and vegetables supplemented with additional vitamins and minerals is important.

The insufficient amount of dopamine disturbs the balance between dopamine and other transmitters, such as acetylcholine. Dopamine is a chemical messenger responsible for transmitting signals between the substantia nigra and the next “relay station” of the brain, the corpus striatum, to produce smooth, purposeful muscle activity.

Oxidation due to free radicals is thought to cause damage to tissues, including neurons.  Normally, free radical damage is kept under control by antioxidant chemicals that protect the cells.

Research has found that those with Parkinson’s have increased brain levels of iron, especially in the substantia nigra, and decreased levels of ferritin, which serves as a protective mechanism by chelating, or forming a ring around the iron isolating it. Conclusion, oxidative mechanisms may cause or contribute to Parkinson’s disease. Parkinson’s may occur when either an external or internal toxin selectively destroys dopaminergic neurons. Our environment is a risk factor such as exposure to pesticides or toxins in the food supply are examples that could hypothetically cause Parkinson’s disease.