These chemical substances deactivate potentially dangerous free radicals before they can injure a cell's machinery. Worldwide, researchers are discovering just how effective nature's antioxidants can be as our body's free radical “bouncers”. Among the most recognized and dedicated defenders are Vitamin A, C, and E. Vitamin C being the most powerful.
Every living cell produces its own antioxidants, but this ability decreases with age. That is why our diet should supply phytochemicals (which include antioxidants), vitamins, and minerals.
Powerful antioxidants of the flavonoid family which constitute numerous differently colored compounds and occur in most plants. These pigments give the intense color to many fruits and vegetables, such as blueberries, red raspberries, red cabbages and purple sweet potatoes.
Represent a sugar or acid form of anthocyanidins. Next to chlorophyll, anthocyanins are the most important group of plant pigments visible to the human eye. They are a class of flavonoids that contribute to the antioxidant capacity of fruits. Anthocyanins have been shown to be powerful natural antioxidants and beneficial to our health. Of the antioxidants, they show the most ability to penetrate cell membranes and provide protection. Research has linked anthocyanin activity to an increase in peripheral circulation, improved vision, enhanced immune systems, and wound healing.
A phenolic compound naturally found in plants in the form of ellagitannin. Plants produce ellagic acid and glucose that combine to form ellagitannins, water-soluble compounds that are absorbed easily. Consequently, small amounts of ellagitannins derived from natural sources may be more effective in the human diet than large doses of purified ellagic acid. Ellagic acid has been shown to be in the 'free form' in red raspberries at approximately 1.6 mg/gram (dry weight). Marion Blackberries have been found to have double (3.3 mg/g) that level of free ellagic acid. This phenolic substance has been shown to inactivate cancer-causing chemicals, and block carcinogens from attacking DNA.
Natural polyphenolic molecules common to most flowering plants. These pigment compounds make up the largest group of antioxidant compounds in the polyphenol family. Anthocyanidins, proanthocyanins, and phenolics are types of flavonoids. One characteristic of nearly all flavonoids is that they enhance the functionality of the powerful antioxidant vitamin C.
An atom, or group of atoms, with at least one unpaired electron. Unpaired electrons are highly reactive and can damage living cells.
A process that removes ONLY the water from the fruit by using low temperatures and pressure. This process concentrates the full nutritional value of fresh berries into a small volume that does not require refrigeration, while preserving nature's premium flavor without additives.
A group of chemicals present in food that provide energy, cell building and structural materials, and life essential chemistry regulating agents. Nutrients are classified into: proteins, fats, carbohydrates (includes energy rich sugars), vitamins, minerals, and water.
Oxygen Radical Absorption (or Absorbance) Capacity is a measurement system to quantify the antioxidant activity of a substance. ORAC quantifies the degree and length of time it takes to inhibit the action of an oxidizing agent - specifically oxygen radicals - known to cause damage to the delicate machinery of living cells. Substances measured can include natural products such as fruits and vegetables, beverages, supplements, plasma, serum, and urine. Antioxidants 'sponge up' or remove free radicals.
Nutri-Fruit™ labels provide specific information as to the level of antioxidants typically present in each serving of fruit powder. Why is this important? The United States Department of Agriculture has determined that consuming fruits and vegetables with a high ORAC value may be the key to capitalizing on their healthful qualities.
Oxygen radicals and other free radicals - are formed in the biological process of oxidation. Think of an apple slice turning brown, or a nail rusting. These are easily recognized examples of oxidation. Highly unstable free radical molecules inside our cells try to stabilize themselves, causing oxidative “rusting” which can damage vitalcell structures, membranes, and enzyme systems. Such attacks make our body less able to fight against the development of cancer cells, hardening of the arteries, premature aging, bacterial infections, etc.
Because of the oxygen we breathe every moment, each of our cells takes about 10,000 free oxygen radical “hits” per day. Oxygen is required for a complicated chemical process that takes place in living cells to convert sugar, fats, and phosphate into a usable form of energy that we need to live. Oxygen radicals are an unfortunate by-product of this process. In addition, free radicals can form from environmental pollution, radiation, and cigarette smoke.
Phenolics / Polyphenols
The structural 'backbone' for most of the antioxidants found in plants. These are molecules composed of at least two six-carbon rings (benzene rings) connected by a chain of three carbons. Various chemically active functional groups (oxygen, sulfur, nitrogen, alcohols, etc) are attached to the carbons located along the chain or rings. Plants construct complex phenolic compounds, many called flavonoids, which may function to protect them from insects, diseases, and environmental stress. The phenols are a varied group of plant constituents that range from sugar-containing phenolic glycosides (such as Cyanidin-3-O-Glucoside) to salicylic acid. Phenols exhibit anti-inflammatory and antiseptic effects, as well as antiviral properties.
Another group of naturally occurring chemicals found in plants that we consume as food, but these are not nutrients, vitamins, minerals or complex carbohydrates. Phytochemicals exhibit diversified physiologic and pharmacologic effects. They have been found to inactivate cancer-causing substances, stimulate the immune system, protect against heart disease, and help prevent cataracts. These chemicals function best when obtained from the whole plant - be it fruits, vegetables, seeds, legumes, and grains - rather than being extracted and taken individually in supplement form.
The major classes of phytochemicals are based on their protective functions and individual physical and chemical characteristics as follows: terpenes, which include the familiar carotenoids and lycopene; phenols which include flavonoids and isoflavones; and the sulfur-containing thiols common in cruciferous vegetables and onions.
A major feature of phytochemicals is their powerful role as antioxidants.
A group of flavonoids, also called “condensed tannins,” are polyphenolic compounds that give flowers and fruit a blue, purple, or red hue. Proanthocyanins are powerful free radical scavengers and antioxidants.
A type of flavonoid pigment that is a building block for other members of the flavonoid family of phytochemicals. This compound may be effective in reducing Low Density Lipoprotein peroxiation, thereby lowering the risk for heart disease. Quercetin may also be helpful against asthma and allergies because of its ability to reduce the inflammation in the airways and the release of histamine, respectively.
Sorghum bicolor is a species of grass, traditionally cultivated for its nutritious grain. Sorghum is grown in many tropical and subtropical regions of the world, and is gaining increased popularity as a non-gluten grain. Historical uses of Sorghum include food, hot teas, beers, and traditional medicinal extracts.
Used on Nutri-Fruit™ antioxidant fact panels. Our measurements are conducted by the leading laboratory for ORAC analysis. Trolox, a water-soluble Vitamin E analog, is used as the calibration standard and the ORAC result is expressed as micromole (µmole) Trolox equivalent (TE) per gram. This assay provides a measure of the scavenging capacity of antioxidants against the peroxyl radical, which is one of the most common reactive oxygen species found in the body.