Nutritional Profile Energy value (calories per serving): Low Protein: Moderate Fat: None Saturated fat: None Cholesterol: None Carbohydrates: High Fiber: None Sodium: Low Major vitamin contribution: B vitamins Major mineral contribution: Phosphorus
About the Nutrients in This Food Beer and ale are fermented beverages created by yeasts that convert the sugars in malted barley and grain to ethyl alcohol (a.k.a. “alcohol,” “drink- ing alcohol”).* The USDA /Health and Human Services Dietary Guidelines for Americans defines one drink as 12 ounces of beer, five ounces of wine, or 1.25 ounces of distilled spirits. One 12-ounce glass of beer has 140 calo- ries, 86 of them (61 percent) from alcohol. But the beverage—sometimes nicknamed “liquid bread”—is more than empty calories. Like wine, beer retains small amounts of some nutrients present in the food from which it was made. * Because yeasts cannot digest t he starches in grains, t he grains to be used in mak ing beer and ale are allowed to germinate ( “malt” ). When it is t ime to make t he beer or ale, t he malted grain is soaked in water, forming a mash in which t he starches are split into simple sugars t hat can be digested (fermented) by t he yeasts. If undisturbed, t he fermentat ion will cont inue unt il all t he sugars have been digested, but it can be halted at any t ime simply by raising or lowering t he temperature of t he liquid. Beer sold in bott les or cans is pasteurized to k ill t he yeasts and stop t he fermentat ion. Draft beer is not pasteurized and must be refrigerated unt il tapped so t hat it will not cont inue to ferment in t he container. The longer t he shipping t ime, t he more likely it is t hat draft beer will be exposed to temperature variat ions t hat may affect its qualit y—which is why draft beer almost always tastes best when consumed near t he place where it was brewed. The Nutrients in Beer (12-ounce glass)
| Nutrients | Beer | %R DA |
| Calcium | 17 mg | 1.7 |
| Magnesium | 28.51 mg | 7–9* |
| Phosphorus | 41.1 mg | 6 |
| Potassium | 85.7 mg | (na) |
| Zinc | 0.06 mg | 0.5– 0.8* |
| Thiamin | 0.02 mg | 1.6 –1.8* |
| R iboflavin | 0.09 mg | 7– 8* |
| Niacin | 1.55 mg | 10 |
| Vitamin B6 | 0.17 mg | 13 |
| Folate | 20.57 mcg | 5 |
Diets That May Restrict or Exclude This Food Bland diet Gluten-free diet Low-purine (antigout) diet
Buying This Food Look for: A popular brand that sells steadily and will be fresh when you buy it. Avoid: Dusty or warm bottles and cans.
Storing This Food Store beer in a cool place. Beer tastes best when consumed within two months of the day it is made. Since you cannot be certain how long it took to ship the beer to the store or how long it has been sitting on the grocery shelves, buy only as much beer as you plan to use within a week or two. Protect bottled beer and open bottles or cans of beer from direct sunlight, which can change sulfur compounds in beer into isopentyl mercaptan, the smelly chemical that gives stale beer its characteristic unpleasant odor.
When You Are Ready to Serve This Food Serve beer only in absolutely clean glasses or mugs. Even the slightest bit of grease on the side of the glass will kill the foam immediately. Wash beer glasses with detergent, not soap, and let them drain dry rather than drying them with a towel that might carry grease from your hands to the glass. If you like a long-lasting head on your beer, serve the brew in tall, tapering glasses to let the foam spread out and stabilize. For full flavor, serve beer and ales cool but not ice-cold. Very low temperatures immo- bilize the molecules that give beer and ale their flavor and aroma.
What Happens When You Cook This Food When beer is heated (in a stew or as a basting liquid), the alcohol evaporates but the flavor- ing agents remain intact. Alcohol, an acid, reacts with metal ions from an aluminum or iron pot to form dark compounds that discolor the pot or the dish you are cooking in. To prevent this, prepare dishes made with beer in glass or enameled pots.
Medical Uses and/or Benefits Reduced risk of heart attack. Data from the American Cancer Society’s Cancer Prevention Study 1, a 12-year survey of more than 1 million Americans in 25 states, shows that men who take one drink a day have a 21 percent lower risk of heart attack and a 22 percent lower risk of stroke than men who do not drink at all. Women who have up to one drink a day also reduce their risk of heart attack. Numerous later studies have confirmed these findings. Lower risk of stroke. In January 1999, the results of a 677-person study published by researchers at New York Presbyterian Hospital-Columbia University showed that moder- ate alcohol consumption reduces the risk of stroke due to a blood clot in the brain among older people (average age: 70). How the alcohol prevents stroke is still unknown, but it is clear that moderate use of alcohol is a key. Heavy drinkers (those who consume more than seven drinks a day) have a higher risk of stroke. People who once drank heavily, but cut their consumption to moderate levels, can also reduce their risk of stroke. Numerous later studies have confirmed these findings. Lower cholesterol levels. Beverage alcohol decreases the body’s production and storage of low-density lipoproteins (LDLs), the protein and fat particles that carr y cholesterol into your arteries. As a result, people who drink moderately tend to have lower cholesterol levels and higher levels of high density lipoproteins (HDLs), the fat and protein particles that carr y cholesterol out of the body. The USDA /Health and Human Services Dietar y Guidelines for Americans defines moderation as two drinks a day for a man, one drink a day for a woman. Stimulating the appetite. Alcoholic beverages stimulate the production of saliva and the gastric acids that cause the stomach contractions we call hunger pangs. Moderate amounts of alcoholic beverages, which may help stimulate appetite, are often prescribed for geriatric patients, convalescents, and people who do not have ulcers or other chronic gastric problems that might be exacerbated by the alcohol. Dilation of blood vessels. Alcohol dilates the capillaries (the tiny blood vessels just under the skin), and moderate amounts of alcoholic beverages produce a pleasant flush that temporar- ily warms the drinker. But drinking is not an effective way to warm up in cold weather since the warm blood that flows up to the capillaries will cool down on the surface of your skin and make you even colder when it circulates back into the center of your body. Then an alco- hol flush will make you perspire, so that you lose more heat. Excessive amounts of beverage alcohol may depress the mechanism that regulates body temperature.
Adverse Effects Associated with This Food Increased risk of breast cancer. In 2008, scientists at the National Cancer Institute released data from a seven-year survey of more than 100,000 postmenopausal women showing that even moderate drinking (one to two drinks a day) may increase by 32 percent a woman’s risk of developing estrogen-receptor positive (ER+) and progesterone-receptor positive (PR+) breast cancer, tumors whose growth is stimulated by hormones. No such link was found between consuming alcohol and the risk of developing ER-/PR- tumors (not fueled by hor- mones). The finding applies to all types of alcohol: beer, wine, and spirits. Increased risk of oral cancer (cancer of the mouth and throat). Numerous studies confirm the American Cancer Society’s warning that men and women who consume more than two drinks a day are at higher risk of oral cancer than are nondrinkers or people who drink less. Note: The Dietary Guidelines for Americans describes one drink as 12 ounces of beer, five ounces of wine, or 1.5 ounces of distilled spirits. Increased risk of cancer of the colon and rectum. In the mid-1990s, studies at the University of Oklahoma suggested that men who drink more than five beers a day are at increased risk of rectal cancer. Later studies suggested that men and women who are heavy beer or spirits drinkers (but not those who are heavy wine drinkers) have a higher risk of colorectal cancers. Further studies are required to confirm these findings. Fetal alcohol syndrome. Fetal alcohol syndrome is a specific pattern of birth defects—low birth weight, heart defects, facial malformations, and mental retardation—first recognized in a study of babies born to alcoholic women who consumed more than six drinks a day while pregnant. Subsequent research has found a consistent pattern of milder defects in babies born to women who consume three to four drinks a day or five drinks on any one occasion while pregnant. To date, there is no evidence of a consistent pattern of birth defects in babies born to women who consume less than one drink a day while pregnant, but two studies at Columbia University have suggested that as few as two drinks a week while preg- nant may raise a woman’s risk of miscarriage. (“One drink” means 12 ounces of beer, five ounces of wine, or 1.25 ounces of distilled spirits.) Alcoholism. Alcoholism is an addiction disease, the inability to control one’s alcohol consumption. It is a potentially life-threatening condition, with a higher risk of death by accident, suicide, malnutrition, or acute alcohol poisoning, a toxic reaction that kills by para- lyzing body organs, including the heart. Malnutrition. While moderate alcohol consumption stimulates appetite, alcohol abuse depresses it. In addition, an alcoholic may drink instead of eating. When an alcoholic does eat, excess alcohol in his/her body prevents absorption of nutrients and reduces the ability to synthesize new tissue. Hangover. Alcohol is absorbed from the stomach and small intestine and carried by the bloodstream to the liver, where it is oxidized to acetaldehyde by alcohol dehydrogenase (ADH), the enzyme our bodies use to metabolize the alcohol we produce when we digest carbohydrates. The acetaldehyde is converted to acetyl coenzyme A and either eliminated from the body or used in the synthesis of cholesterol, fatty acids, and body tissues. Although individuals vary widely in their capacity to metabolize alcohol, on average, normal healthy adults can metabolize the alcohol in one quart of beer in approximately five to six hours. If they drink more than that, they will have more alcohol than the body’s natural supply of ADH can handle. The unmetabolized alcohol will pile up in the bloodstream, interfering with the liver’s metabolic functions. Since alcohol decreases the reabsorption of water from the kidneys and may inhibit the secretion of an antidiuretic hormone, they will begin to urinate copiously, losing magnesium, calcium, and zinc but retaining more irritating uric acid. The level of lactic acid in the body will increase, making them feel tired and out of sorts; their acid-base balance will be out of kilter; the blood vessels in their heads will swell and throb; and their stomachs, with linings irritated by the alcohol, will ache. The ultimate result is a “hangover” whose symptoms will disappear only when enough time has passed to allow their bodies to marshal the ADH needed to metabolize the extra alcohol in their blood. Changes in body temperature. Alcohol dilates capillaries, tiny blood vessels just under the skin, producing a “flush” that temporarily warms the drinker. But drinking is not an effective way to stay warm in cold weather. Warm blood flowing up from the body core to the surface capillaries is quickly chilled, making you even colder when it circulates back into your organs. In addition, an alcohol flush triggers perspiration, further cooling your skin. Finally, very large amounts of alcohol may actually depress the mechanism that regulates body temperature. Impotence. Excessive drinking decreases libido (sexual desire) and interferes with the ability to achieve or sustain an erection. “Beer belly.” Data from a 1995, 12,000 person study at the University of North Carolina in Chapel Hill show that people who consume at least six beers a week have more rounded abdomens than people who do not drink beer. The question left to be answered is which came first: the tummy or the drinking.
Food/Drug Interactions Acetaminophen (Tylenol, etc.). The FDA recommends that people who regularly have three or more drinks a day consult a doctor before using acetaminophen. The alcohol/acetamino- phen combination may cause liver failure. Disulfiram (Antabuse). Taken with alcohol, disulfiram causes flushing, nausea, low blood pressure, faintness, respiratory problems, and confusion. The severity of the reaction gener- ally depends on how much alcohol you drink, how much disulfiram is in your body, and how long ago you took it. Disulfiram is used to help recovering alcoholics avoid alcohol. (If taken with alcohol, metronidazole [Flagyl], procarbazine [Matulane], quinacrine [Atabrine], chlorpropamide (Diabinase), and some species of mushrooms may produce a mild disulfi- ramlike reaction.) Anticoagulants. Alcohol slows the body’s metabolism of anticoagulants (blood thinners) such as warfarin (Coumadin), intensif ying the effect of the drugs and increasing the risk of side effects such as spontaneous nosebleeds. Antidepressants. Alcohol may increase the sedative effects of antidepressants. Drinking alcohol while you are taking a monoamine oxidase (M AO) inhibitor is especially hazard- ous. M AO inhibitors inactivate naturally occurring enzymes in your body that metabolize tyramine, a substance found in many fermented or aged foods. Tyramine constricts blood vessels and increases blood pressure. If you eat a food containing tyramine while you are taking an M AO inhibitor, you cannot effectively eliminate the tyramine from your body. The result may be a hypertensive crisis. Ordinarily, fermentation of beer and ale does not produce tyramine, but some patients have reported tyramine reactions after drinking some imported beers. Beer and ale are usually prohibited to those using M AO inhibitors. Aspirin, ibuprofen, ketoprofen, naproxen, and nonsteroidal anti-inflammatory drugs. Like alcohol, these analgesics irritate the lining of the stomach and may cause gastric bleeding. Combining the two intensifies the effect. Insulin and oral hypoglycemics. Alcohol lowers blood sugar and interferes with the metabo- lism of oral antidiabetics; the combination may cause severe hypoglycemia. Sedatives and other central nervous system depressants (tranquilizers, sleeping pills, antidepres- sants, sinus and cold remedies, analgesics, and medication for motion sickness). Alcohol inten- sifies sedation and, depending on the dose, may cause drowsiness, respiratory depression, coma, or death.... beer
Nutritional Profile Energy value (calories per serving): Moderate to high Protein: None Fat: None Saturated fat: None Cholesterol: None Carbohydrates: None (except for cordials which contain added sugar) Fiber: None Sodium: Low Major vitamin contribution: None Major mineral contribution: Phosphorus
About the Nutrients in This Food Spirits are the clear liquids produced by distilling the fermented sugars of grains, fruit, or vegetables. The yeasts that metabolize these sugars and convert them into alcohol stop growing when the concentration of alcohol rises above 12–15 percent. In the United States, the proof of an alcoholic beverage is defined as twice its alcohol content by volume: a beverage with 20 percent alcohol by volume is 40 proof. This is high enough for most wines, but not high enough for most whiskies, gins, vodkas, rums, brandies, and tequilas. To reach the concentra- tion of alcohol required in these beverages, the fermented sugars are heated and distilled. Ethyl alcohol (the alcohol in beer, wine, and spirits) boils at a lower temperature than water. When the fermented sugars are heated, the ethyl alcohol escapes from the distillation vat and condenses in tubes leading from the vat to a collection vessel. The clear liquid that collects in this vessel is called distilled spirits or, more technically, grain neutral spirits. Gins, whiskies, cordials, and many vodkas are made with spirits American whiskeys (which include bourbon, rye, and distilled from grains. blended whiskeys) and Canadian, Irish, and Scotch whiskies are all made from spirits aged in wood barrels. They get their flavor from the grains and their color from the barrels. (Some whiskies are also colored with caramel.) Vodka is made from spirits distilled and filtered to remove all flavor. By law, vodkas made in America must be made with spirits distilled from grains. Imported vodkas may be made with spirits distilled either from grains or potatoes and may contain additional flavoring agents such as citric acid or pepper. Aquavit, for example, is essentially vodka flavored with caraway seeds. Gin is a clear spirit flavored with an infusion of juniper berries and other herbs (botanicals). Cordials (also called liqueurs) and schnapps are flavored spirits; most are sweetened with added sugar. Some cordials contain cream. Rum is made with spirits distilled from sugar cane (molasses). Tequila is made with spirits distilled from the blue agave plant. Brandies are made with spirits distilled from fruit. (Arma- gnac and cognac are distilled from fermented grapes, calvados and applejack from fermented apples, kirsch from fermented cherries, slivovitz from fermented plums.) Unless they contain added sugar or cream, spirits have no nutrients other than alcohol. Unlike food, which has to be metabolized before your body can use it for energy, alcohol can be absorbed into the blood-stream directly from the gastrointestinal tract. Ethyl alcohol provides 7 calories per gram.
The Most Nutritious Way to Serve This Food The USDA /Health and Human Services Dietary Guidelines for Americans defines one drink as 12 ounces of beer, five ounces of wine, or 1.25 ounces of distilled spirits, and “moderate drinking” as two drinks a day for a man, one drink a day for a woman.
Diets That May Restrict or Exclude This Food Bland diet Lactose-free diet (cream cordials made with cream or milk) Low-purine (antigout) diet
Buying This Food Look for: Tightly sealed bottles stored out of direct sunlight, whose energy might disrupt the structure of molecules in the beverage and alter its flavor. Choose spirits sold only by licensed dealers. Products sold in these stores are manufac- tured under the strict supervision of the federal government.
Storing This Food Store sealed or opened bottles of spirits in a cool, dark cabinet.
Preparing This Food All spirits except unflavored vodkas contain volatile molecules that give the beverage its characteristic taste and smell. Warming the liquid excites these molecules and intensifies the flavor and aroma, which is the reason we serve brandy in a round glass with a narrower top that captures the aromatic molecules as they rise toward the air when we warm the glass by holding it in our hands. Whiskies, too, though traditionally served with ice in America, will have a more intense flavor and aroma if served at room temperature.
What Happens When You Cook This Food The heat of cooking evaporates the alcohol in spirits but leaves the flavoring intact. Like other alcoholic beverages, spirits should be added to a recipe near the end of the cooking time to preserve the flavor while cooking away any alcohol bite. Alcohol is an acid. If you cook it in an aluminum or iron pot, it will combine with metal ions to form dark compounds that discolor the pot and the food you are cooking. Any recipe made with spirits should be prepared in an enameled, glass, or stainless-steel pot.
Medical Uses and/or Benefits Reduced risk of heart attack. Data from the American Cancer Society’s Cancer Prevention Study 1, a 12-year survey of more than 1 million Americans in 25 states, shows that men who take one drink a day have a 21 percent lower risk of heart attack and a 22 percent lower risk of stroke than men who do not drink at all. Women who have up to one drink a day also reduce their risk of heart attack. Numerous later studies have confirmed these findings. Lower cholesterol levels. Beverage alcohol decreases the body’s production and storage of low density lipoproteins (LDLs), the protein and fat particles that carry cholesterol into your arteries. As a result, people who drink moderately tend to have lower cholesterol levels and higher levels of high density lipoproteins (HDLs), the fat and protein particles that carry cholesterol out of the body. Numerous later studies have confirmed these findings. Lower risk of stroke. In January 1999, the results of a 677-person study published by researchers at New York Presbyterian Hospital-Columbia University showed that moderate alcohol consumption reduces the risk of stroke due to a blood clot in the brain among older people (average age: 70). How alcohol prevents stroke is still unknown, but it is clear that moderate use is a key. Heavy drinkers (those who consume more than seven drinks a day) have a higher risk of stroke. People who once drank heavily, but cut their consumption to moderate levels, reduce their risk of stroke. Stimulating the appetite. Alcoholic beverages stimulate the production of saliva and the gastric acids that cause the stomach contractions we call hunger pangs. Moderate amounts of alcoholic beverages, which may help stimulate appetite, are often prescribed for geriatric patients, convalescents, and people who do not have ulcers or other chronic gastric problems that might be exacerbated by the alcohol. Dilation of blood vessels. Alcoholic beverages dilate the tiny blood vessels just under the skin, bringing blood up to the surface. That’s why moderate amounts of alcoholic beverages (0.2–1 gram per kilogram of body weight, or two ounces of whiskey for a 150-pound adult) temporarily warm the drinker. But the warm blood that flows up to the surface of the skin will cool down there, making you even colder when it circulates back into the center of your body. Then an alcohol flush will make you perspire, so you lose more heat. Excessive amounts of beverage alcohol may depress the mechanism that regulates body temperature.
Adverse Effects Associated with This Food Alcoholism. Alcoholism is an addiction disease, the inability to control one’s alcohol consumption. It is a potentially life-threatening condition, with a higher risk of death by accident, suicide, malnutrition, or acute alcohol poisoning, a toxic reaction that kills by para- lyzing body organs, including the heart. Fetal alcohol syndrome. Fetal alcohol syndrome is a specific pattern of birth defects—low birth weight, heart defects, facial malformations, learning disabilities, and mental retarda- tion—first recognized in a study of babies born to alcoholic women who consumed more than six drinks a day while pregnant. Subsequent research has found a consistent pattern of milder defects in babies born to women who drink three to four drinks a day or five drinks on any one occasion while pregnant. To date there is no evidence of a consistent pattern of birth defects in babies born to women who consume less than one drink a day while preg- nant, but two studies at Columbia University have suggested that as few as two drinks a week while pregnant may raise a woman’s risk of miscarriage. (One drink is 12 ounces of beer, five ounces of wine, or 1.25 ounces of distilled spirits.) Increased risk of breast cancer. In 2008, scientists at the National Cancer Institute released data from a seven-year survey of more than 100,000 postmenopausal women showing that even moderate drinking (one to two drinks a day) may increase by 32 percent a woman’s risk of developing estrogen-receptor positive (ER+) and progesterone-receptor positive (PR+) breast cancer, tumors whose growth is stimulated by hormones. No such link was found between consuming alcohol and the risk of developing ER-/PR- tumors (not fueled by hor- mones). The finding applies to all types of alcohol: beer, wine, and distilled spirits. Increased risk of oral cancer (cancer of the mouth and throat). Numerous studies confirm the A merican Cancer Societ y’s warn ing that men and women who consume more than t wo drinks a day are at higher risk of oral cancer than are nondrinkers or people who drink less. Increased risk of cancer of the colon and rectum. In the mid-1990s, studies at the University of Oklahoma suggested that men who drink more than five beers a day are at increased risk of rectal cancer. Later studies suggested that men and women who are heavy beer or spirits drinkers (but not those who are heavy wine drinkers) have a higher risk of colorectal cancers. Further studies are required to confirm these findings. Malnutrition. While moderate alcohol consumption stimulates appetite, alcohol abuses depresses it. In addition, an alcoholic may drink instead of eating. When an alcoholic does eat, excess alcohol in his/her body prevents absorption of nutrients and reduces the ability to synthesize new tissue. Hangover. Alcohol is absorbed from the stomach and small intestine and carried by the bloodstream to the liver, where it is oxidized to acetaldehyde by alcohol dehydrogenase (ADH), the enzyme our bodies use every day to metabolize the alcohol we produce when we digest carbohydrates. The acetaldehyde is converted to acetyl coenzyme A and either eliminated from the body or used in the synthesis of cholesterol, fatty acids, and body tis- sues. Although individuals vary widely in their capacity to metabolize alcohol, an adult of average size can metabolize the alcohol in four ounces (120 ml) whiskey in approximately five to six hours. If he or she drinks more than that, the amount of alcohol in the body will exceed the available supply of ADH. The surplus, unmetabolized alcohol will pile up in the bloodstream, interfering with the liver’s metabolic functions. Since alcohol decreases the reabsorption of water from the kidneys and may inhibit the secretion of an antidiuretic hormone, the drinker will begin to urinate copiously, losing magnesium, calcium, and zinc but retaining uric acid, which is irritating. The level of lactic acid in the body will increase, making him or her feel tired and out of sorts; the acid-base balance will be out of kilter; the blood vessels in the head will swell and throb; and the stomach, its lining irritated by the alcohol, will ache. The ultimate result is a hangover whose symptoms will disappear only when enough time has passed to allow the body to marshal the ADH needed to metabolize the extra alcohol in the person’s blood. Changes in body temperature. Alcohol dilates capillaries, tiny blood vessels just under the skin, producing a “flush” that temporarily warms the drinker. But drinking is not an effective way to stay warm in cold weather. Warm blood flowing up from the body core to the surface capillaries is quickly chilled, making you even colder when it circulates back into your organs. In addition, an alcohol flush triggers perspiration, further cooling your skin. Finally, very large amounts of alcohol may actually depress the mechanism that regulates body temperature. Impotence. Excessive drinking decreases libido (sexual desire) and interferes with the ability to achieve or sustain an erection. Migraine headache. Some alcoholic beverages contain chemicals that inhibit PST, an enzyme that breaks down certain alcohols in spirits so that they can be eliminated from the body. If they are not broken down by PST, these alcohols will build up in the bloodstream and may trigger a migraine headache. Gin and vodka appear to be the distilled spirits least likely to trigger headaches, brandy the most likely.
Food/Drug Interactions Acetaminophen (Tylenol, etc.). FDA recommends that people who regularly have three or more drinks a day consult a doctor before using acetaminophen. The alcohol/acetaminophen combination may cause liver failure. Anti-alcohol abuse drugs (disulfiram [Antabuse]). Taken concurrently with alcohol, the anti- alcoholism drug disulfiram can cause flushing, nausea, a drop in blood pressure, breathing difficulty, and confusion. The severity of the symptoms, which may var y among individu- als, generally depends on the amount of alcohol consumed and the amount of disulfiram in the body. Anticoagulants. Alcohol slows the body’s metabolism of anticoagulants (blood thinners), intensif ying the effect of the drugs and increasing the risk of side effects such as spontane- ous nosebleeds. Antidepressants. Alcohol may strengthen the sedative effects of antidepressants. Aspirin, ibuprofen, ketoprofen, naproxen and nonsteroidal anti-inflammatory drugs. Like alco- hol, these analgesics irritate the lining of the stomach and may cause gastric bleeding. Com- bining the two intensifies the effect. Insulin and oral hypoglycemics. Alcohol lowers blood sugar and interferes with the metabo- lism of oral antidiabetics; the combination may cause severe hypoglycemia. Sedatives and other central nervous system depressants (tranquilizers, sleeping pills, antide- pressants, sinus and cold remedies, analgesics, and medication for motion sickness). Alcohol intensifies the sedative effects of these medications and, depending on the dose, may cause drowsiness, sedation, respiratory depression, coma, or death. MAO inhibitors. Monoamine oxidase (M AO) inhibitors are drugs used as antidepressants or antihypertensives. They inhibit the action of natural enzymes that break down tyramine, a substance formed naturally when proteins are metabolized. Tyramine is a pressor amine, a chemical that constricts blood vessel and raises blood pressure. If you eat a food that contains tyramine while you are taking an M AO inhibitor, the pressor amine cannot be eliminated from your body and the result may be a hypertensive crisis (sustained elevated blood pressure). Brandy, a distilled spirit made from wine (which is fermented) contains tyramine. All other distilled spirits may be excluded from your diet when you are taking an M AO inhibitor because the spirits and the drug, which are both sedatives, may be hazard- ous in combination.... distilled spirits
In order to prevent NEURAL TUBE defects and cleft lip or palate (see CLEFT PALATE), all women planning to become pregnant should be advised to have a diet rich in folic acid in the months before conception until 13 weeks’ gestation, or to take folic acid tablets.
Recent research has suggested that adequate levels of folic acid can prevent the build-up of homocysteine, a compound in the blood closely associated with heart attacks and strokes. It has been suggested that the o?cial recommendation of 200 micrograms a day in the diet should be doubled. (See APPENDIX 5: VITAMINS.)... folic acid
Diagnosis and treatment Any person with isolated, itching, dry and scaling lesions of the skin with no obvious cause – for example, no history of eczema (see DERMATITIS) – should be suspected of having a fungal infection. Such lesions are usually asymmetrical. Skin scrapings or nail clippings should be sent for laboratory analysis. If the lesions have been treated with topical steroids they may appear untypical. Ultraviolet light ?ltered through glass (Wood’s light) will show up microsporum infections, which produce a green-blue ?uorescence.
Fungal infections used to be treated quite e?ectively with benzoic-acid compound ointment; it has now been superseded by new IMIDAZOLES preparations, such as CLOTRIMAZOLE, MICONAZOLE and terbina?ne creams. The POLYENES, NYSTATIN and AMPHOTERICIN B, are e?ective against yeast infections. If the skin is macerated it can be treated with magenta (Castellani’s) paint or dusting powder to dry it out.
Refractory fungal infection can be treated systematically provided that the diagnosis of the infection has been con?rmed. Terbina?ne, imidazoles and GRISEOFULVIN can all be taken by mouth and are e?ective for yeast infections. (Griseofulvin should not be taken in pregnancy or by people with liver failure or porphyria.) (See also FUNGUS; MICROBIOLOGY.)... fungal and yeast infections
Among the smallest and simplest microorganisms are the viruses. First described as ?lterable agents, and ranging in size from 20–30 nm to 300 nm, they may be directly visualised only by electron microscopy. They consist of a core of deoxyribonucleic or ribonucleic acid (DNA or RNA) within a protective protein coat, or capsid, whose subunits confer a geometric symmetry. Thus viruses are usually cubical (icosahedral) or helical; the larger viruses (pox-, herpes-, myxo-viruses) may also have an outer envelope. Their minimal structure dictates that viruses are all obligate parasites, relying on living cells to provide essential components for their replication. Apart from animal and plant cells, viruses may infect and replicate in bacteria (bacteriophages) or fungi (mycophages), which are damaged in the process.
Bacteria are larger (0·01–5,000 µm) and more complex. They have a subcellular organisation which generally includes DNA and RNA, a cell membrane, organelles such as ribosomes, and a complex and chemically variable cell envelope – but, unlike EUKARYOTES, no nucleus. Rickettsiae, chlamydia, and mycoplasmas, once thought of as viruses because of their small size and absence of a cell wall (mycoplasma) or major wall component (chlamydia), are now acknowledged as bacteria; rickettsiae and chlamydia are intracellular parasites of medical importance. Bacteria may also possess additional surface structures, such as capsules and organs of locomotion (?agella) and attachment (?mbriae and stalks). Individual bacterial cells may be spheres (cocci); straight (bacilli), curved (vibrio), or ?exuous (spirilla) rods; or oval cells (coccobacilli). On examination by light microscopy, bacteria may be visible in characteristic con?gurations (as pairs of cocci [diplococci], or chains [streptococci], or clusters); actinomycete bacteria grow as ?laments with externally produced spores. Bacteria grow essentially by increasing in cell size and dividing by ?ssion, a process which in ideal laboratory conditions some bacteria may achieve about once every 20 minutes. Under natural conditions, growth is usually much slower.
Eukaryotic micro-organisms comprise fungi, algae, and protozoa. These organisms are larger, and they have in common a well-developed internal compartmentation into subcellular organelles; they also have a nucleus. Algae additionally have chloroplasts, which contain photosynthetic pigments; fungi lack chloroplasts; and protozoa lack both a cell wall and chloroplasts but may have a contractile vacuole to regulate water uptake and, in some, structures for capturing and ingesting food. Fungi grow either as discrete cells (yeasts), multiplying by budding, ?ssion, or conjugation, or as thin ?laments (hyphae) which bear spores, although some may show both morphological forms during their life-cycle. Algae and protozoa generally grow as individual cells or colonies of individuals and multiply by ?ssion.
Micro-organisms of medical importance include representatives of the ?ve major microbial groups that obtain their essential nutrients at the expense of their hosts. Many bacteria and most fungi, however, are saprophytes (see SAPROPHYTE), being major contributors to the natural cycling of carbon in the environment and to biodeterioration; others are of ecological and economic importance because of the diseases they cause in agricultural or horticultural crops or because of their bene?cial relationships with higher organisms. Additionally, they may be of industrial or biotechnological importance. Fungal diseases of humans tend to be most important in tropical environments and in immuno-compromised subjects.
Pathogenic (that is, disease-causing) microorganisms have special characteristics, or virulence factors, that enable them to colonise their hosts and overcome or evade physical, biochemical, and immunological host defences. For example, the presence of capsules, as in the bacteria that cause anthrax (Bacillus anthracis), one form of pneumonia (Streptococcus pneumoniae), scarlet fever (S. pyogenes), bacterial meningitis (Neisseria meningitidis, Haemophilus in?uenzae) is directly related to the ability to cause disease because of their antiphagocytic properties. Fimbriae are related to virulence, enabling tissue attachment – for example, in gonorrhoea (N. gonorrhoeae) and cholera (Vibrio cholerae). Many bacteria excrete extracellular virulence factors; these include enzymes and other agents that impair the host’s physiological and immunological functions. Some bacteria produce powerful toxins (excreted exotoxins or endogenous endotoxins), which may cause local tissue destruction and allow colonisation by the pathogen or whose speci?c action may explain the disease mechanism. In Staphylococcus aureus, exfoliative toxin produces the staphylococcal scalded-skin syndrome, TSS toxin-1 toxic-shock syndrome, and enterotoxin food poisoning. The pertussis exotoxin of Bordetella pertussis, the cause of whooping cough, blocks immunological defences and mediates attachment to tracheal cells, and the exotoxin produced by Corynebacterium diphtheriae causes local damage resulting in a pronounced exudate in the trachea.
Viruses cause disease by cellular destruction arising from their intracellular parasitic existence. Attachment to particular cells is often mediated by speci?c viral surface proteins; mechanisms for evading immunological defences include latency, change in viral antigenic structure, or incapacitation of the immune system – for example, destruction of CD 4 lymphocytes by the human immunode?ciency virus.... microbiology
Causes: Impaired immunity as in AIDS. High sugar diets (yeasts thrive in the presence of sugar), alcohol, broad spectrum antibiotics, iron deficiency anaemia, diabetes, steroid therapy. A common cause frequently overlooked is the reaction between yeasts and mercury from amalgam dental fillings when methyl mercury is created in the intestine. For treatments to be effective silver fillings should be removed. A favourite breeding ground for the fungus is the low bowel.
Alternatives. Teas. Balm, Chamomile, Gotu Kola, La Pacho (Pau d’arco), Rosemary, Thyme. Tablets/capsules. Aloe Vera, Caprycin, Echinacea, Garlic, Goldenseal, Poke root, Thuja. Candidiasis of stomach and intestines. Caprylic acid derived from coconut inhibits growth of Candida in the intestines and colon without upsetting the balance of the intestinal flora.
Horseradish. Success reported: (Rudat K.D. 1957. Journal Hyg. Epidem. Microbiol. Immol. Prague 1:123)
Garlic. Inhibits growth of Candida. (Tynecke Z, and Gos Z)
Formula. While a practitioner’s treatment will be prescribed according to the specific requirements of the individual, the following combination may be used for the average case:–
Tinctures: Echinacea 50ml, Poke root 15ml, Vervain 15ml, Galangal 15ml, Calendula 15ml, Clivers 20ml. Mix. Dose: one 5ml teaspoon thrice daily. (Brenda Cooke MNIMH, Mansfield, Notts)
Diet. High fibre food essential for efficient daily clearance. Low fat, low salt, gluten-free, little milk only. 2 teaspoons Olive oil thrice daily. Reject: refined foods, yeasts (no bread), mushrooms, mouldy cheese, sugar, artificial sweeteners, alcohol.
Supplements. Vitamin A, C, E, biotin, Calcium ascorbate, Zinc, Lacto-bacillus.
Chelation therapy. Anti-fungals. ... candidiasis
Preservatives, such as sodium nitrate, are added to food to control the growth of bacteria, moulds, and yeasts. Other additives, such as antioxidants, improve the keeping quality of food by preventing undesirable changes (they stop rancidity in foods containing fat, for example). Additives that improve texture include emulsifiers, stabilizers, thickeners, and gelling agents. Appearance and taste are improved by the use of colourings, flavourings, sweeteners, and flavour enhancers. Artificial sweeteners, such as saccharin, may be used instead of sugar, especially in products for diabetics or slimmers.
Certain additives may produce an allergic reaction in some people, and some are thought to be a factor in behavioural problems in children.... food additives
Most fungi are either harmless or beneficial to human health, but some can cause illness and disease. The fruiting bodies of some fungi contain toxins that can cause poisoning if eaten (see mushroom poisoning). Certain fungi infect food crops and produce toxins that can cause food poisoning. The best known of these is a fungus that infects cereals and produces ergot, a toxin that constricts blood vessels; and another that grows on peanuts and produces aflatoxin, a poison and carcinogen. The inhaled spores of some fungi can cause allergic alveolitis, a persistent allergic reaction in the lungs. Fungal spores are sometimes responsible for other allergic disorders such as allergic rhinitis and asthma. Some fungi are able to invade and form colonies in the lungs, in the skin, or sometimes in various different tissues throughout the body, leading to conditions that range from mild irritation to severe, even fatal, widespread infection (see fungal infections) and illness. (See also candidiasis.)... fungi
Treatment of eczema is with regular emollients and topical corticosteroids. Other treatments include topical *calcineurin inhibitors, phototherapy, and systemic immunosuppressants. There is emerging evidence that effective treatment of eczema helps to reduce the risk of subsequently developing asthma and hay fever. —eczematous adj.... eczema
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