Antioxidant and Free Radicals

Noni is a powerful antioxidant.
An antioxidant is a substance that reduces the oxidative damage caused by free radicals.

Antioxidants

Antioxidants are phytochemicals, vitamins and other nutrients that protect our cells from damage caused by free radicals. In vitro en in vivo studies have shown that antioxidants help prevent the free radical damage that is associated with cancer and heart disease. Antioxidants can be found in most fruits and vegetables but also culinary herbs and medicinal herbs can contain high levels of antioxidants. Dragland S and colleagues showed in their study entitled "Several Culinary and Medicinal Herbs are Important Sources of Dietary Antioxidants", and published in the Journal of Nutrition (2003 May) that the antioxidant level of herbs can be as high as 465 mmol per 100 g.A study in 2006 by Thompson HJ showed that a botanical diversity of fruits and vegetables plays a role in the biological effect of antioxidant phytochemicals. The consumption of smaller quantities of many phytochemicals may result in more health benefits than the consumption of larger quantities of fewer phytochemicals.

What are free radicals?
Free radicals are formed as part of our natural metabolism but also by environmental factors, including smoking, pesticides, pollution and radiation. Free radicals are unstable molecules which react easily with essential molecules of our body, including DNA, fat and proteins. All organic and inorganic materials consist of atoms, which can be bound together to form molecules. Each atom has a specific number of protons (positively charged) and electrons (negatively charged). Most single atoms are not stable because they have to few or to may electrons. Atoms try to reach a state of maximum stability by giving away or receiving electrons from other atoms, thereby forming molecules. Free radicals are molecules with have one electron too much or to less in order to be stable. Free radicals try to steal or give electrons to other molecules, thereby changing their chemical structure.

When a free radical attacks a molecule, it will then become a free radical itself, causing a chain reaction which can result in the destruction of a cell. Antioxidants have the property to neutralize free radicals without becoming a free radicals themselves. When antioxidants neutralize free radicals by receiving or donating an electron they do not become antioxidants themselves because they are stable in both forms. In other words, antioxidants are chemicals that offer up their own electrons to the free radicals, thus preventing cellular damage. However, when the antioxidant neutralizes a free radical it becomes inactive. Therefore we need to continuously supply our body with antioxidants. The action of free radicals could increase the risk of diseases such as cancer and hearth problems and could accelerate ageing. Antioxidants have the property to neutralize the free radicals and prevent damage. Well known examples of antioxidants are the vitamin C, E and beta-carotene. These three vitamins are often added to the so called ACE drinks. But there are numerous other rather unknown antioxidants such as lycopene, and lutein.

Benefits of antioxidants
Numerous studies with plant phytochemicals show that phytochemicals with antioxidant activity may reduce risk of cancer and improve heart health.

Antioxidants reduce the risk of cancer

Not all results are conclusive but many studies show that antioxidants may reduce the risk of cancer. A large randomized trial on antioxidants and cancer risk was the Chinese Cancer Prevention Study (1993). This study showed that a combination of the antioxidants beta-carotene, vitamin E and selenium significantly reduced incidence of cancer. However, the Alpha-Tocopherol / Beta-Carotene Cancer Prevention Study (1994) showed that intake of beta-carotene increased lung cancer rates of male smokers.

Antioxidants protect the heart

Everyone knows that cholesterol causes heart diseases and tries to limit cholesterol intake. But a more important cause of fatty buildups in the arteries is the oxidation of low-density lipoprotein cholesterol. The use of dietary supplements of antioxidants could reduce the risk of cardiovascular disease, but there is no hard evidence. At this stage, studies only show that the intake of foods, naturally rich in antioxidants reduces this risk.

Antioxidant claims on foods

Antioxidants can be found in most foods, especially in fruits and vegetables, but we see more and more food products on the shelves with antioxidant claims. These antioxidant claims crop up everywhere: from beverages to chocolates. Food producers do this because of the very high consumer awareness of the term antioxidants. Consumers believe that a high intake of antioxidants will protect them from ageing, cancer, heart disease and other diseases. This awareness already started in the 1990s when mainly beverage producers launched so called ACE drinks, which contained the three antioxidant vitamins vitamin A, C and E. Now food producers are adding supper fruits such as red berries, pomegranate and acai. When the food producer claims antioxidants, they are mainly looking at the total content of antioxidants and not at their biological activity. The antioxidant activity of foods is mainly expressed as FRAP, ORAC or TEAC values, all of which are measured in a test tube. In future the antioxidant activity should be measured in humans, by determining the quantities absorbed in the blood and tissues.

What are free radicals?

Free radicals are atomic or molecular species with unpaired electrons in the outermost bonding orbital and are likely to take part in chemical reactions. Electrons prefer to be in pairs and when an electron is alone in its orbital in will try to take an electron from another atom to become more stable. When the other atom loses its electron it tries on its turn to steal an electron from another atom, often resulting in a dangerous chain reaction. Free radicals can cause damage to our cells but they also play an important role in a number of biological processes, such as the intracellular killing of bacteria by white blood cells and some cell signalling processes.

Types of free radicals

Most free radicals are coming from oxygen atoms and are called Reactive Oxygen Species (ROS), such as superoxide ion, hydroxyl radical, hydrogen peroxide and singlet oxygen.

Superoxide ion (or reactive oxygen species) is an oxygen molecule with an extra electron. This free radical can cause damage to mitochondria, DNA and other molecules. Our body can neutralize superoxide ions by producing superoxide dismutase.

Hydroxyl radical is formed by the reduction of an oxygen molecule in the electron transport chain. It is a neutral (not charged) form of the hydroxide ion. Hydroxyl radicals are highly reactive and form an important part of radical biochemistry. Unlike superoxide the hydroxyl radical cannot be eliminated by an enzymatic reaction. Is has a very short half-life and will only react with molecules its vicinity. Because of its high reactivity it will damage most organic molecules such as carbohydrates, DNA, lipids and proteins.

Singlet oxygen is formed by our immune system. Singlet oxygen causes oxidation of LDL cholesterol.

Hydrogen peroxide is not a free radical but it is involved in the production of many reactive oxygen species. Hydrogen peroxide is a byproduct of oxygen metabolism and is neutralized by peroxidases.

Sometimes reactive nitrogen atoms are involved and these free radicals grouped under Reactive Nitrogen Species (RNS). Nitric acid is the most important RNS. Some transitional metals, such as iron and copper, have many numbers of unpaired electrons and can also act as free radicals. These metals do not have that strong electron affinity but can easily accept and donate electrons.

Oxidative damage

Free radicals can damage DNA in different ways. They can disrupt the duplication and maintenance of DNA, brake open the DNA molecule or they can alter the structure by reacting with the DNA bases. Lipids in cell membranes are very prone to oxidative damage because some free radicals tend to concentrate in the membrane and cause oxidative damage, known as lipid peroxidation. Many forms of cancer are thought to be the result of reactions between free radicals and DNA, resulting in mutations that can lead to malignancy. Other diseases such as atherosclerosis, Parkinson's disease and Alzheimer's are also attributed to free radicals.

Noni's Phytochemicals Profile

1. ethylthomethyl) benzene

2. 1-hexanol

3. hydroxyanthraquinone

4. 2-heptanone

5. 2-methyl-2-butenyl hexanoate

6. 6-§-primeveroside

7. 2-methylbutanoic acid

8. 24-methylcycloartanol

9. 24-methylenecycloartanyl linoleate

10. 3-hydroxymorindone

11. 3-methyl-2-buten-1-ol

12. 3-methylthiopropanoic acid

13. 5,6-dihydroxylucidin-3-§-primeverosid

14. glucopyranoside

15. D(+)=galactopyranoside

16. 1,-O-§-rhamnosyl

17. 6-dodeceno-y-lactone

18. methylanthraquinone

19. acetic acid

20. alkaloids

21. anthraquinones

22. asperuloside

23. benzyl alcohol

24. methyl octanoate

25. methyl palmitate

26. morenone-2

27. morindanigrine

28. morindone

29. mucilaginous matter

30. it-butyric acid

31. nonanoic acid

32. octadecenoic acid

33. oleic acid 34. paraffin

35. pentose

36. phosphate

37. physcion-8-O

38. 1-butanol

39. 1-methoxy-2-formyl-3-

40. 2,5-undecadien-1-ol

41. 2-methyl-2-butenyl decanoate

42. 2-methyl-3,5,6-trihydroxyanthraquinone-

43. 2-methyl-3,5,-6-trihydroxyanthraquinones

44. 2-methylpropanoic acid

45. 24-methylenecholesterol

46. 3-hydroxyl-2-butanone

47. 3-hydroxymorindone-6-§-primeveroside

48. 3-methyl-3-buten-1-ol

49. 5,6-dihydroxylucidin

50. 5,7-acacetin 7-O-§-D(+)-

51. 5,7-dimethylapigenin-4O-O-§-D-

52. 6,8-dimethoxy-3-methyl anthraquinone-

53. glucopyranoside

54. 7-hydroxy-8methoxy-2-

55. 8,11,14-eicostrienoic acid

56. alizarin

57. anthragallol 1,2-dimethyl ehter

58. antrhagallol 2,3-dimethyl ehter

59. benzoic acid

60. butanoic acid

61. methyl oleate

62. morenone-1

63. morindadiol64. morindin

65. morindone-6-§-primeveroside

66. myristic acid

67. it-valeric acid

68. nordamnacanthal

69. octanoic acid

70. palmitic acid

71. pectins

72. phenolic body

73. physcoin

74. [{L-arabinopyranosyl} (1-3)

75. {§-D-g-D-galactopyranosyl (1-6)

76. potassium

77. calcium

78. campesteryl linoleyl glucoside

79. campesteryl palmityl glycoside

80. carbonate ions

81. cycloartenol

82. cycloartenol palmitate

83. decanoic acid

84. ethyl decanoate

85. ethyl octanoate

86. eugenol

87. gampesteryl linoleate

88. glycosides

89. hexadecane

90. hexanedioic acid

91. hexose

92. iron

93. isocaproic acid

94. isofucosteryl linoleate

95. lauric acid

96. linoleic acid

97. lucidin-3-§-primeveroside

98. methyl 3-methylthio-propanoate

99. methyl elaidate

100. proxeronine

101. resins

102. ricinoleic acid

103. rubiadin-1-methyl ether

104. sitosterol

105. sitosteryl linoleate

106. sitosteryl palmitate

107. sodium

108. §-sitosterol

109. sterols

110. stigmasteryl glycoside

111. stigmasteryl linoleyl glycoside

112. stigmasteryl palmityl glycoside

113. trioxymethylanthraquinone

114. ursolic acid

115. {§-D-galactopyranoside}

116. protein

117. campesteryl glycoside

118. campesteryl palmitate

119. campestrol

120. carotene

121. cycloartenol linoleate

122. damnacanthal

123. elaidic acid

124. ethyl hexanoate

125. ethyl palmitate

126. ferric iron

127. glucose

128. heptanoic acid

129. hexanamide

130. hexanoic acid

131. hexyl hexanoate

132. isobutyric acid

133. isofucosterol

134. isolaveric acid

135. limonene

136. lucidin

137. magnesium

138. methyl decanoate

139. methyl hexanoate

140. proxeronease

141. rhamnose

142. rubiadin

143. scopoletin

144. sitosteryl glycoside

145. sitosteryl linoleyl glycoside

146. sitosteryl palmityl glycoside

147. sorandjidiol

148. stearic acid

149. stigmasterol

150. stimasteryl linoleate

151. stigmasteryl palmitate

152. terpenoids

153. undecanoic acid

What are phytochemicals?

Phytochemicals are non-nutritive plant chemicals that have protective or disease preventive properties. There are more than thousand known phytochemicals. It is well-known that plant produce these chemicals to protect itself but recent research demonstrate that they can protect humans against diseases. Some of the well-known phytochemicals are lycopene in tomatoes, isoflavones in soy and flavanoids in fruits. They are not essential nutrients and are not required by the human body for sustaining life.

How do phytochemicals work

There are many phytochemicals and each works differently. These are some possible actions:

Antioxidant - Most phytochemicals have antioxidant activity and protect our cells against oxidative damage and reduce the risk of developing certain types of cancer.

Hormonal action -Imitate human estrogens and help to reduce menopausal symptoms and osteoporosis.

Stimulation of enzymes - Stimulate enzymes that make the estrogen less effective and could reduce the risk for breast cancer.

Interference with DNA replication - Interfere with the replication of cell DNA, thereby preventing the multiplication of cancer cells.Anti-bacterial effect - The phytochemical allicin from garlic has anti-bacterial properties.

Physical action - Some phytochemicals bind physically to cell walls thereby preventing the adhesion of pathogens to human cell walls.

How do we get enough phytochemicals?

Foods containing phytochemicals are already part of our daily diet. In fact, most foods contain phytochemicals except for some refined foods such as sugar or alcohol. Some foods, such as whole grains, vegetables, beans, fruits and herbs, contain many phytochemicals. The easiest way to get more phytochemicals is to eat more fruit and vegetables. It is recommended take daily at least 5 to 9 servings of fruits or vegetable. Fruits and vegetables are also rich in minerals, vitamins and fibre and low in saturated fat.

Future of phytochemicals

Phytochemicals are naturally present in many foods but it is expected that through bioengineering new plants will be developed, which will contain higher levels. This would make it easier to incorporate enough phytochemicals with our food.

History of Phytochemicals

Phytochemicals exists as long as plants exist but we only know about hundred years about their existence. Medicinal plants are widely used by traditional cultures all over the world. It is likely that the knowledge of traditional medicine developed through trial and error over many centuries. The Chinese have the oldest medicine system. More than 5000 years ago, the Chinese based their medicine on the influence of yin and yang, and on the five elements. The earliest records about herbal medicine dates back to 2800 BC when the Chinese emperor Shen Nong wrote the text The Great Native Herbal.

Hippocrates (460-377 BC) and Aristotle (384-322 BC) introduced the herbal medicine from India and Egypt to Europe.

The Greek physician Dioscorides wrote the book De Materia Medica in the first century AD. During the 19th and 20th century, the main strategy of the scientists was to discover the active ingredients, which had medicinal or pesticidal properties. Examples of these discoveries are salicylic avid, morphine and pyrethroids (pesticides). During the 1980s many laboratories started to identify phytochemicals in plants that might be used as medicines. Many of these discovered phytochemicals seems to fight diseases such as cancer, heart attack and stroke. At the same time other scientist conducting epidemiological studies to determine the relationship between the consumption of phytochemicals and human health. Most studies showed that diets rich in plants gave lower rates of cancer and heart disease.

Today, most new pharmaceuticals are not discovered in plants but are new synthetic creations. Recently there is a renewed interest in the discovery of phytochemicals. This renewed interest is our awareness has already developed many chemicals, which still have to be discovered. New modern laboratory techniques have made it easer to discover and identify new phytochemicals.

Noni (Morinda citrifolia)

Other names: Indian mulberry, nono, nonu, cheese fruit, Ba Ji Tian

Description:
The noni plant is a small evergreen shrub or tree that grows from three to six metres. The noni plant has a straight trunk, large elliptical leaves, white tubular flowers and ovoid yellow fruits of up to 12 cm in diameter. The ripe noni fruit has a not so pleasant taste and odour.

Parts used:
All parts of the noni plant can be used: roots, stems, bark, leaves, and flowers and of course the fruits.

Some of the over 150 Phytochemicals include:
Octoanoic acid, Scopoletin, Damnacanthal, Terpenoids, Anthraquinones, Caproic acid, Ursolic Acid, Rutin, etc

Medicinal properties:
Noni has been reported to have a range of health benefits for colds, cancer, diabetes, asthma, hypertension, pain, skin infection, high blood pressure, mental depression, atherosclerosis and arthritis.

The noni contain the antibacterial compounds in the fruits (acubin, L-asperuloside and alizarin) and roots (anthrauinones). Noni conatins scopoletin which inhibits the growth of Escherichia coli, which is responsible for intestinal infections, and Heliobacter pylori, which causes ulcers

Damnacanthal, which is found in the noni roots, inhibits the tyrosine kinase and gives noni antitumor activity.

Other facts:
The medicinal properties of Noni were discovered, more than 2000 years ago, by the Polynesians, who imported the fruit from Southeast Asia. Today the noni fruits is eaten in many parts of the world, mainly in the Pacific Islands, Southeast Asia and Australia.

Those who recovered from illness after eating the noni fruit called it "the fruit of God". In 2003, noni juice was approved by the European Commission as a novel food and was allowed to be commercialized in the EU. A novel food is food or a food ingredient that was not used to a significant degree in the EU before May 15, 1997. Before any new food product can be introduced on the European market it must be rigorously assessed for safety.

Noni Benefits

Induction of extracellular matrix synthesis in normal human fibroblasts by anthraquinone isolated from Morinda citrifolia (Noni) fruit.
Journal of Medicinal Food. 2005 Winter;8(4):552-5

Previous in vitro studies with cultured human dermal fibroblasts have shown that extract from noni increased production of collagen. The aim of this study was to identity the phytochemicals responsible for this action. The researchers succeeded in isolating the phytochemical 1,4-dihydroxy-2-methoxy-7-methylanthraquinone. This anthraquinone significantly increased production of procollagen and glycosaminoglycans and reduced expression of the collagenase. The study concluded that anthraquinone from Noni extract could be used as a possible anti-wrinkle agent.

Hepatotoxicity of NONI juice: report of two cases.
World Journal of Gastroenterology. 2005 August 14;11(30):4758-60

NoniI juice (Morinda citrifolia) is becoming more popular as a health ingredient in wellness drinks. Noni has been claimed to be beneficial for many diseases. But recently there were cases of liver intoxication. Therefore the toxicity of noni juice was reassessed. One patient had to undergo a liver transplantation and another patient recovered after stopping intake of noni juice. The first patient with previous toxic hepatitis associated with paracetamol developed hepatic failure after consuming nearly two liters of noni juice. The hepatotoxicity is probably linked to anthraquinones. Following this negative publicity, most noni juice producers recommend a daily intake of max 30 ml noni juice.

Inhibition of angiogenic initiation and disruption of newly established human vascular networks by juice from Morinda citrifolia (noni).
Angiogenesis. 2003;6(2):143-9

Noni juice has been used traditionally for its medicinal properties. The aim of this study was to investigate the effect of noni juice on the development of blood vessel. The study used a fibrin clot matrix model with human placental vein and human breast tumor explants. The researchers found that noni juice at concentrations of 5 percent effectively reduced blood vessel development and reduced the growth rate of new vessels.

Phytochemicals in Noni Juice

An anthraquinone with potent quinone reductase-inducing activity and other constituents of the fruits of Morinda citrifolia (noni).
The Journal of Natural Products. 2005 December;68(12):1720-2

Noni has long been used as a medicinal plant in Polynesia. Recently noni has become popular in the United States and other Western countries. This study was the first to isolate a special anthraquinone: 2-methoxy-1,3,6-trihydroxyanthraquinone. This anthraquinone is a strong quinone reductase inducer. It is about 40 times more active than sulphoraphane.

Chemical constituents of the fruits of Morinda citrifolia (Noni) and their antioxidant activity.
The Journal of Natural Products. 2005 April;68(4):592-5

The purpose of this study was to isolate and identify phytochemicals in noni fruits. First the phytochemicals were first extracted with methanol and then separated in a N-Butyl Alcohol -soluble fraction. The researchers isolated and identified 17 known phytochemicals and two new phytochemicals: 6-alpha-hydroxyadoxoside and 6-beta,7-beta-epoxy-8-epi-splendoside. The researchers also isolated 6 know phytochemicals for the first time from noni: borreriagenin, cytidine, deacetylasperuloside, dehydromethoxygaertneroside, epi-dihydrocornin, methyl alpha-d-fructofuranoside and methyl beta-d-fructofuranoside. The phytochemicals with the highest antioxidant activity were neolignan and americanin A.

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NONI works as a ‘Healthy, Immune System Promoter’

Research has shown that if the immune system starts to turn against itself - perhaps the result of an autoimmune disorder - it may cause a complete obliteration of the pancreas’ beta cells or at least a reduction in the number of functioning beta cells. This then affects the amount and purity and effectiveness of the body’s insulin.

"Noni helps promoting a healthy immune system

by either enhancing an already functioning system

or by stimulating a sluggish one"

Current studies have revealed that Noni helps promoting a healthy immune system by either enhancing an already functioning system or by stimulating a sluggish one. In addition, as described earlier, Noni is believed to fortify and maintain cell structure. This can be accomplished by Noni acting as an adaptogen that can aid “sick” cells in repairing themselves. This could apply to diabetes by either helping malfunctioning beta cells in the pancreas or by aiding the cells that are unsuccessfully trying to receive and use the glucose in the blood.

Besides, NONI has a low glycemic index. Glycemic Index refers to a method of classification by which a number is assigned to foods based on how they affect blood sugar levels. Foods that contain the same amount of total carbohydrate may have a different glycemic index. Fried Chicken, for example, has a higher glycemic affect on the body than carrots; kidney beans increase blood sugar levels more significantly than soya beans, because of its higher glycemic value. The glycemic effect of foods can indicate, as many researchers have found, potential risks than the acute blood sugar levels. NONI has a very low glycemic index and hence it reduces the risks of chronic conditions of diabetics.