Lecture 10 nutrients involved in antioxidant function
wajihahwafa
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Nov 21, 2016
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About This Presentation
At the end of this lecture, the student should be able to:
Describe how antioxidants protect cells from the oxidative damage caused by free radicals.
Describe the relationship between antioxidant nutrients and the risk for cancer
Discuss how consuming nutrients with antioxidant properties can reduce...
Slide Content
Lecture 10: Nutrients Involved in Antioxidant Function DR. SHARIFAH WAJIHAH WAFA [email protected]
Topic Learning Outcomes At the end of this lecture, the student should be able to: Describe how antioxidants protect cells from the oxidative damage caused by free radicals. Describe the relationship between antioxidant nutrients and the risk for cancer Discuss how consuming nutrients with antioxidant properties can reduce the risk for cardiovascular disease, Compare and contrast macular degeneration and cataracts, and discuss how antioxidants may affect these two disorders .
Course Outline What are Antioxidants? A Profile of Nutrients That Function as Antioxidants What Disorders are Related to Oxidation?
What Are Antioxidants? Compounds that protect cells from the damage caused by oxidation Nutrients with antioxidant properties: Vitamin E Vitamin C Vitamin A (precursor beta-carotene) Selenium
Structure of Atoms Atom: the smallest unit of matter. Atoms are composed of Nucleus —positively charged center portion of the atom Electrons —negatively charged particles surrounding the nucleus
Structure of Atoms Figure 8.1
Oxidation Molecules are composed of atoms. During metabolic reactions, electrons can be transferred. From the atoms of one molecule To the atoms of another molecule
Oxidation Figure 8.2
Oxidation Oxidation : the loss of electrons from a molecule. Reduction : the gain of electrons by a molecule. Oxidation and reduction usually occur together as an exchange reaction .
Oxidation Stable atoms contain an even number of paired electrons. Free radical : an atom that has lost an electron and is left with an unpaired electron. Free radicals are highly reactive and can cause damage to molecules in the cell
Free Radicals Stable atoms have an even number of electrons ( pairs ) orbiting Electron loss during oxidation leaves an odd number or unpaired electron Unstable atoms are called free radicals Reactive oxygen species (ROS): oxygen molecule that becomes a free radical Free Radical Formation
Formation of Free Radicals Figure 8.4
What Causes Free Radicals? Metabolic processes Immune system fighting infections Environmental factors Pollution Excess sunlight Toxic substances Radiation Tobacco smoke Asbestos
Formation of Free Radicals Free radicals cause damage to Cell membranes Low-density lipoproteins (LDLs) Proteins in the cell Genetic material (DNA)
Diseases Linked to Free Radicals Cancer Heart disease Diabetes Arthritis Cataracts Kidney Disease Alzheimer’s disease Parkinson’s disease
Quick Review Free radicals are formed during oxidation when a stable atom loses or gains an electron and this electron remains unpaired. Free radicals can be produced during the formation of ATP, immune system fights infections, and exposed to pollution, toxic substances, radiation, the Sun, and tobacco smoke. Free radicals are highly unstable entities that cause the production of more free radicals. They can damage our cell membranes, low density lipoproteins (LDLs), cell proteins, and DNA and are associated with many diseases including heart disease, cancer, and diabetes.
Antioxidants Antioxidants can function in different ways. Some vitamins donate their electrons to free radicals to stabilize them Some minerals act with complex enzyme systems to destroy free radicals Superoxide dismutase Catalase Glutathione peroxidase
Antioxidant Enzymes Antioxidant enzyme systems Break down oxidized fatty acids Make more vitamin antioxidants available to fight other free radicals
Antioxidant Enzymes Antioxidant enzymes: Superoxide dismutase converts free radicals to less damaging substances, such as hydrogen peroxide Catalase removes hydrogen peroxide from the body Glutathione peroxidase removes hydrogen peroxide
Antioxidants Other compounds stabilize free radicals and prevent damage to cells and tissues Nutrients with antioxidant properties: Vitamin E Vitamin C Vitamin A Beta-carotene (precursor to vitamin A) Selenium
Quick Review Antioxidant vitamins donate electrons or hydrogen atoms to free radicals to stabilize them and reduce oxidative damage. Antioxidant minerals are part of antioxidant enzyme systems that convert free radicals to less damaging substances , which the body then excretes. Other compounds stabilize free radicals , which prevents them from damaging cells and tissues. Selenium , copper, iron , zinc, and manganese act as cofactors for the antioxidant enzyme systems, which include superoxide dismutase, catalase, and glutathione peroxidase.
Vitamin E Vitamin E is a fat-soluble vitamin made of Tocotrienol —biologically inactive form Tocopherol —biologically active form Functions of Vitamin E Primary role is as an antioxidant Protects polyunsaturated fatty acids (PUFAs) Protects low-density lipoproteins (LDLs)
Vitamin E Recommended intake 5–15 mg alpha- tocopherol per day Upper limit (UL) is 1,000 mg per day Sources of Vitamin E Vegetable oils, nuts, seeds, wheat germ, soybeans Animal and dairy products are poor sources
Vitamin E What if you consume too much vitamin E? Vitamin E toxicity is uncommon Vitamin E can interfere with anticoagulant medications What if you don’t consume enough vitamin E? Vitamin E deficiencies are uncommon Can result in fragile red blood cells (erythrocyte hemolysis)
Vitamin C Vitamin C is a water-soluble vitamin that must be consumed in the human diet. Functions of Vitamin C Antioxidant Synthesis of collagen Prevents the disease scurvy Enhances the immune system Enhances the absorption of iron
Vitamin C Recommended intake 90 mg/day for men; 75 mg/day for women Smokers need an extra 35 mg/day Sources of vitamin C Fresh fruits and vegetables Heat destroys vitamin C Cooking foods lowers their vitamin C content
Vitamin C What if you consume too much vitamin C? Megadoses (10 times or more of the recommended intake) of vitamin C can cause nausea, diarrhea, nosebleeds Can cause iron toxicity in people with hemochromatosis Can lead to kidney stone formation in people with kidney disease
Vitamin C What if you don’t consume enough vitamin C? Scurvy: the most common vitamin C deficiency disease Bleeding gums, loose teeth, weakness Can occur after one month on a vitamin C-deficient diet
Beta-carotene Beta-carotene is In the class of chemicals called carotenoids A provitamin : inactive precursors that must be converted to the active form of a vitamin in the body The precursor of retinol
Beta-carotene Functions of beta-carotene A weak antioxidant Effective against oxidation in cell membranes and LDLs Carotenoids in general are known to Enhance the immune system Protect skin from damage by UV light Protect eyes from damage
Beta-carotene Recommended intake Beta-carotene is not considered an essential nutrient No DRI or RDA has been established Sources of beta-carotene Fruits and vegetables that are red, orange, yellow, and deep green
Beta-carotene What if you consume too much beta-carotene? Large quantities do not appear to be toxic Skin may turn yellow or orange at high intakes; harmless and reversible What if you don’t consume enough beta-carotene? There are no known deficiency symptoms
Vitamin A Vitamin A is a fat-soluble vitamin. Excess vitamin A is stored in the liver, adipose tissue, kidneys, and lungs There are three active forms of Vitamin A Retinol Retinal Retinoic acid
Vitamin A Figure 8.10
Vitamin A Figure 8.11 (1 of 2)
Vitamin A Figure 8.11 (2 of 2)
Vitamin A Functions of vitamin A Essential to proper vision Antioxidant, protecting LDL cholesterol Cell differentiation: the process by which cells mature and specialize Sperm production and fertilization Bone growth
Vitamin A Recommended intake RDA is 900 m g/day for men; 700 m g/day for women Sources of vitamin A Animal sources: liver, eggs Plant sources such as the provitamin carotenoids (dark green, orange, and deep yellow fruits and vegetables)
Vitamin A What if you consume too much vitamin A? Vitamin A is highly toxic, especially from supplements Birth defects and permanent damage to the liver and eyes can result What if you don’t consume enough vitamin A? Night blindness is the most common disease of vitamin A deficiency Irreversible blindness ( xerophthalmia )
Selenium Selenium is a trace mineral found in a few amino acids in the body. Functions of selenium Antioxidant; part of the glutathione peroxidase enzyme system Production of thyroxine —a thyroid hormone
Selenium Recommended intake 55 m g/day for men and women UL is 400 m g/day Sources of selenium Rich sources include organ meats, pork, seafood, nuts, wheat, rice
Selenium What if you consume too much selenium? Selenium toxicity (brittle hair, nails, skin rashes) can result from supplements What if you don’t consume enough selenium? Keshan disease: a form of heart disease Kashin -Beck disease: an arthritis
Additional Antioxidants Copper, zinc, and manganese are part of the superoxide dismutase enzyme antioxidant complex Iron is part of the catalase structure Copper, iron, and zinc for blood health Manganese : important cofactor in carbohydrate metabolism
Quick Review
Cancer Cancer: a group of related diseases characterized by cells growing out of control. Composed of three steps Initiation —a cell’s DNA is mutated Promotion —altered cell repeatedly divides Progression —cells grow out of control
Cancer Figure 8.15 (1 of 3)
Cancer Figure 8.15 (2 of 3)
Cancer Figure 8.15 (3 of 3)
Cancer Factors that increase cancer risk include Tobacco use Sun exposure Nutrition Environmental/occupational exposure Low level of physical activity
Tobacco Use
Tobacco Use
Cancer Antioxidants may contribute to reducing the risk of cancer. Antioxidants may work by Enhancing the immune system Inhibiting growth of cancer cells Preventing oxidation damage to cells
Quick review Cancer is a group of diseases in which genetically mutated cells grow out of control . Tobacco use, Sun exposure, nutritional factors, radiation and chemical exposures , and low physical activity levels are related to a higher risk for some cancers . Eating foods high in antioxidants is associated with lower rates of cancer, but studies of antioxidant supplements and cancer are equivocal.
Cardiovascular Disease (CVD) Leading cause of death in adults Diseases of the heart and blood vessels Coronary heart disease Hypertension (high blood pressure) Atherosclerosis (hardening of the arteries) Primary manifestations of CVD Heart attack Stroke
Major Risk Factors for CVD Smoking Hypertension High blood levels of LDL cholesterol Obesity Sedentary lifestyle
Other Risk Factors for CVD Low blood levels of HDL cholesterol Diabetes Family history of CVD Males before age 55 Females before age 65 Being male older than 45 years Being postmenopausal woman
Low-Grade Inflammation More important than elevated cholesterol? Weakens plaque in blood vessels (more fragile) Likely to burst, break away, lodge in blood vessels of heart or brain, and close off blood supply, resulting in a heart attack or stroke
Low-Grade Inflammation C-reactive protein (CRP) Marker for inflammation (blood test) Associated with high risk for heart attack in the presence of normal cholesterol levels High CRP and high cholesterol can increase the risk for heart attack
Antioxidants and CVD Antioxidants (vitamins E and lycopene) reduce damage to blood vessels: Scavenge free radicals Reduce low-grade inflammation Reduce blood coagulation and clot formation In fruits, vegetables, and whole grains Dietary fiber (soluble):oatmeal and oat bran Folate (reduce homocysteine-CVD risk factor) Others (flavonoids): tea
Quick review Risk factors for CVD include smoking, hypertension, high LDL-cholesterol, obesity , and a sedentary lifestyle. Antioxidants may help reduce the risk for heart disease by preventing oxidative damage to LDL-cholesterol, reducing inflammation in the vessels and reducing the formation of blood clots.
Age-Related Vision Impairment Macular degeneration Leading cause of blindness Deterioration of center portion of retina Loss of the ability to see details Cataract Damaged portion of eye’s lens (cloudy vision) Impaired adjustment from dark to bright light
Macular degeneration Cataract
Age-Related Vision Impairment Possible role of antioxidants Supplements may reduce progression of macular degeneration Mixed results from cataract research Current research does not support the use of antioxidant supplements to prevent these two diseases of aging
Quick Review There is no evidence that antioxidants can reverse or prevent aging or significantly prolong our lives . Macular degeneration and cataracts are two diseases of vision that are associated with aging. Antioxidant nutrients have been found to reduce the risk of these diseases in some studies.
Putting It All Together
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