Tuesday, June 30, 2015

Cysteine and NAC

Cysteine is a sulfur-containing amino acid and an important structural and functional component of proteins and enzymes. 

The antioxidant activity of Glutathione (GSH) is attributed specifically to the presence and availability of this amino acid.
”For our bodies to sustain healthy glutathione levels, the limiting factor in our daily intake of food is usually the amino acid cysteine. It must be in a form that can survive the trip from our mouths to our cells. Unfortunately, merely eating either glutathione or the free amino acid cysteine does not give the cell what it needs to manufacture glutathione.”

Dr. Jimmy Gutman “Glutathione. Your Key To Health”
Oral glutathione cannot be effectively used to build glutathione in cells (details are on our page Oral Glutathione). The body requires three amino acids - glutamate, glycine and cysteine – in order to manufacture glutathione on its own inside the cell.
WHY IS CYSTEINE IMPORTANT?


The “SH” in the glutathione abbreviation “GSH” stands for the critically active sulfur sulfhydryl group. Cysteine is a sulfur-containing amino acid that contributes to the sulfhydryl group in the glutathione molecule. This makes cysteine the most crucial of the three building blocks for glutathione.
This means that the level of cysteine in your system is the limiting factor in how fast you can produce glutathione and how much of it you can make.
When cells have cysteine they are able to manufacture glutathione. Low levels of this all-important amino acid may reduce your ability to prevent free radical damage and may result in impaired function of the immune system.
Unfortunately, cysteine is deficient in many diets. In addition to low amounts of cysteine being present in our diets, only the cysteine of a specific form can actually enter the cell.
In order to determine the best source of cysteine for building intracellular glutathione, let’s take a closer look at the sources of this crucial amino acid and how the body uses them.

CYSTEINE PRODUCED BY THE BODY


Your body can and does produce some cysteine on its own from another amino acid – methionine, which is also a sulfur-containing amino acid. Methionine is an essential amino acid, meaning it is not produced by the body but comes from diet only.
Food sources of methionine are: all meats and poultry, fish, eggs, dairy, quinoa, buckwheat, sesame seeds, Brazil nuts, and to a lesser degree dry spirulina. While methionine can be found in other foods as well, such as beans and legumes, the amount of methionine is too low to be of any benefit for significant cysteine production and ultimately glutathione production for your immune health.
The process of transformation of methionine into cysteine is a multi-step process, very complex and requires the presence of certain enzymes and B-vitamins. Any small deficiency in this long complicated chain of events, from consumption to enough glutathione to boost the immune system, and you are left with a compromised immune system that lacks sufficient glutathione for multiple “T” cell cloning to occur.
The process of transforming methionine into cysteine can be interrupted by a number of things. Liver diseases and impaired metabolism are the most disruptive to this process, and this process is completely non-existent in newborn babies. Fortunately for babies, mothers’ milk is loaded with sulfur-containing bonded cysteine (more details in the next paragraph).
Some of the cysteine that does get produced from methionine can be used for manufacturing glutathione inside the cells. Unfortunately, methionine also converts into homocysteine in the body. Homocysteine has been identified as a high risk factor for hardening of arteries (atherosclerosis). For this reason methionine cannot be considered the main source of cysteine for building glutathione, and supplemental methionine (L-methionine) should be avoided.

CYSTEINE FROM FOOD SOURCES


milk, cheese, farm Cysteine is present in all high-protein foods: all meats and poultry, dairy and eggs, quinoa, buckwheat.
Small amounts of cysteine can be found in other plant sources: broccoli, Brussels sprouts, red and yellow bell peppers, onions, garlic.
In food cysteine is bound into protein molecules by amide (peptide) bonds. High temperatures during cooking break down these bonds and destroy bioactivity of cysteine.
If plant sources of cysteine are consumed raw, then harsh stomach acids break down these bonds. Free cysteine either gets snatched up by stomach and intestinal bacteria (they need it, too!), or if free cysteine survives the trip into the bloodstream, it cannot enter the cells.
For cysteine to bypass the stomach acids, one will have to eat some 50 lbs. of raw veggies a day, or – 4-5 lbs. of raw meat, which is out of the question.
Study “Immunoenhancing property of dietary whey protein in mice: role of glutathione” led by Dr. Bounous and Dr. Batist and published in Clinical and Investigavive Medicine demonstrated that mice fed dietary (free) cysteine showed no positive immunological response.
”Cysteine has trouble surviving the trip from your mouth to your cells unless it’s part of a larger molecule or protein.”
Dr. Jimmy Gutman “Glutathione. Your Key To Health”

And there is one food source out there with very interesting qualities where cysteine molecule remains intact during digestion.
Raw cow’s milk (or rather, milk whey) contains three highly bioactive proteins: lactoferrin, serum albumin and alpha lactalbumin. These proteins contain exceptional amounts of cysteine. And most importantly, in the form that can enter cells: each cysteine molecule is bonded with another cysteine molecule by a disulfide bond or bridge:
bonded cysteine molecule, disufide bonds

This paired unit is now called cystine (note the difference in spelling). It is pronounced /sis-‘ta-yn/. Cystine can easily enter the cell where it breaks down back into two cysteine molecules and participates in the formation of glutathione.
These disulfide bonds are very fragile and easily denatured by heat and mechanical stress. Pasteurization of milk multiple times at high temperatures before it reaches your table, as well as mechanical stress during centrifuging, destroy these bonds.
It makes cysteine from supermarket milk (and all mainstream dairy for that matter) absolutely useless for building glutathione. Humans outsmarted themselves by ruining the only viable food source of cysteine. For generations unprocessed milk, cheeses and yogurts used to be our ancestors’ sources of this critical glutathione precursor.
”So I have come down to rescue them from the hand of the Egyptians and to bring them up out of that land into a good and spacious land, a land flowing with milk and honey…”
Exodus 3:8, NIV

Retail sale of raw milk is currently legal only in 10 US states, with another 4 states allowing it for pet consumption only. Detailed map can be viewed here (the page will open in a new window).
To find a raw dairy farm near your residence visit this raw milk farm locator (the page will open in a new window).
If you live in Pennsylvania, New Jersey, New York City tri-state area, eastern Ohio, northern Maryland, north-eastern West Virginia, check out
Your Family Cow – PA raw dairy and grass-fed meat farm that delivers delicious quality food to many drop point locations in PA along the borders with above mentioned states (they are prohibited to cross borders with raw milk). My husband and I drive for 3 hours round trip from New Jersey to the nearest drop point in Stroudsburg, PA almost every month and buy raw milk, cheeses and fresh meat from this farm. It is an effort that is so well worth it!
Raw milk will supply your body with cysteine. However, 1-2 glasses a day is not enough to raise glutathione levels noticeably. To do that one will have to drink a minimum of 1-2 gallons a day, or more in case of a serious illness. Still, it is a great way to provide your body with additional cysteine in this natural form that can easily enter cells and be used as a building block for glutathione. None other food is able to do that!
Human breast milk contains large amounts of lactoferrin, serum albumin and alpha lactalbumin, as well as other immunoglobulins - so it is loaded with bonded cysteine. This is one of the reasons why mother's milk is such a strong immune system builder for a baby, and why it is very important to breastfeed your child. No baby formula will supply bonded cysteine for building glutathione.

CYSTEINE AS A SUPPLEMENT L-CYSTEINE


Cysteine is available as a supplement from health food stores and pharmacies. It is usually labeled “L-cysteine”, and the most common dosage is 500 mg in pill, tablet or capsule form.
Science has proven that supplemental cysteine may in fact raise intracellular glutathione to a small degree, especially in cases of severe glutathione depletion.
However, cysteine as a dietary supplement can promote hypercysteinemia and can be potentially toxic. Its absorption into bloodstream is limited because it is easily oxidized in the digestive tract. Further oxidation in the bloodstream leads to formation of potentially toxic byproducts, some of which may contain a highly reactive oxidant – hydroxyl radical.
Cysteine toxicity leads to a number of disorders in the body, from heart disease to renal (kidney) disease. Due to the potential for cysteine toxicity, excessive homocysteine levels and potential hypercysteinemia, it is not recommended to take L-cysteine supplements without strict supervision from your physician, especially if there are underlying health conditions.
In addition to being a dietary supplement, L-cysteine is also used in baking as a dough conditioner – you might find it on the ingredient lists of some commercial breads and other baked goods. It is also used as a flavor enhancer in both human and pet food (it contributes to meat flavor). A derivative of L-cysteine called N-acethyl-cysteine or NAC is widely used as a drug – we will discuss NAC in the next paragraph.
L-cysteine can be of synthetic and natural origin. Synthetic L-cysteine is made either using industrial chemicals that undergo biochemical transformation with the help of enzymes, or from chemicals using a microbial fermentation process.
Because synthetic L-cysteine is very expensive to manufacture, natural L-cysteine is more widely used. How is it made? The process is actually quite gross. Since cysteine is naturally abundant as a structural component of keratin (a protein that hair is made of), L-cysteine is made from human hair, duck and chick feathers and pigs’ bristles. Most of L-cysteine supply comes from Asia, mostly China, where hair is collected from the floors of barber and hairdresser shops. Then hair or feathers are either boiled in concentrated hydrochloric acid and other chemicals, or in a different process, they sit in a broth of mutated harmless E. coli bacteria, sugars and minerals. The end product of hair breakdown is L-cysteine.
In recent years, because of the growing concern from vegans, vegetarians and various religious groups, feathers have been used more often than human hair. However, almost free cost of hair will not allow it to completely disappear from the market.
According to the FDA guidelines, when L-cysteine is used as a flavor it does not have to be listed on food labels. When it has to be labeled, the source is not required to be mentioned. To find out whether synthetic or natural L-cysteine was used in your food you should call the manufacturer.
CYSTEINE AS A DRUG NAC


NAC stands for N-acetyl-cysteine (also known as n-acetyl-l-cysteine). It is a variant of L-cysteine with an acetyl molecule attached to it. This variation in molecular structure enables cysteine to survive the digestive tract and get into cells, thus increasing cysteine’s bioavailability, in other words – usefulness for building glutathione.
For several decades NAC has been used as an effective drug for breaking up mucus in lungs of patients with asthma, emphysema, chronic bronchitis and cystic fibrosis. This drug is an active component in inhalers.
Another application of NAC, usually intravenously, is at hospital emergency rooms to treat cases of acetaminophen (Tylenol) overdose. It is used to rapidly spike glutathione levels in patients with overdoses to save their lives.
Also, NAC has been used in research on HIV patients when it became known in the early 1990s that such patients are severely glutathione deficient. Since then NAC has been used with positive results in many animal and human trials in a wide range of diseases characterized by oxidative stress and low glutathione levels.
Non-prescription NAC is sold as a dietary supplement in pill, tablet or powder form. It can also be an ingredient in various supplements advertised as immune system boosters.
Either in clinical use or as a supplement, NAC therapy has two common problems: it is a pharmaceutical drug which has certain toxicity, and glutathione levels induced by NAC reach a rapid peak and decline within hours.
These rapids spikes in GSH levels are usually followed by a drop, often below normal levels. To maintain elevated glutathione levels NAC must be taken or injected several times a day which is very hard on human body.
According to the information from WebMD, possible side effects of oral NAC are:
  • Severe - obstructive pulmonary disease, coughing up blood;

  • Less severe – throat pain, irritation of the larger air passages of the lungs, increase of secretion of the lungs, painful, red or swollen mouth, fever, vomiting or feeling like it, runny nose, clammy skin;

  • Rare side effects - severe contact dermatitis and hives.
In his bestseller “Glutathione. Your Key To Health” Dr. Jimmy Gutman states: “Although rare, death has been reported in association with NAC”.
According to drugs.com, there are 6 drugs known to interact with NAC. See the list here (will open in a new window).
Some people have a hard time tolerating the taste and smell of NAC – it resembles that of rotten eggs due to sulfur content.
NAC as a cysteine delivery system should not be used without professional medical advice.
In addition, a recent randomized and placebo-controlled study (2013) linked NAC supplements with hindered muscle performance and increased recovery time for several days after athletic exercise (Thiol-based antioxidant supplementation alters human skeletal muscle signaling and attenuates its inflammatory response and recovery after intense eccentric exercise. Michailidis Y. et al. Am. J Clin Nutr. 2013 Jul;98(1):233-45. doi: 10.3945/ajcn.112.049163. Epub 2013 May 29.).

Watch Dr. Jimmy Gutman explain where L-cysteine and NAC come from:



CYSTEINE IN UNDENATURED WHEY PROTEIN


Raw cow’s milk contains 5-10% protein, out of which 80% is casein and 20% whey. And as I mentioned above in paragraph Cysteine From Food Sources, this whey contains potent GSH precursors - lactoferrin, serum albumin and alpha lactalbumin, rich in bonded cysteine that is able to survive digestion, enter the bloodstream and cross the cell walls.
As an interesting comparison, proteins in human breast milk contain only 40% casein and 60% whey - this makes mother’s milk an exceptional source of bonded cysteine.
For whey protein to be effective in raising glutathione it must be kept undenatured – unheated and unaltered – at all times during the manufacturing process.
The unique quality of undenatured whey proteins as a source of highly bioactive cysteine was discovered in the late 1970s by Dr. Gustavo Bounous, a renowned researcher in the field of nutrition at McGill University in Montreal, Canada.
One day a cheese manufacturer from Switzerland sent whey protein powder, a byproduct of cheese production, to Dr. Bounous requesting him to investigate its possible application. Preliminary study revealed that mice fed this whey protein exhibited a much better immune response than mice fed a regular diet. Subsequent studies confirmed these exiting results.
Dr. Bounous’s research with undenatured whey protein can be viewed
here.
As a result of extensive research done by Dr. Bounous in the 1980s, undenatured whey protein Immunocal was developed. Immunocal is made from raw milk through a process which produces 90% pure whey protein that is kept undenatured and preserves its full bioactivity. It is patented for its immuno-enhancing and glutathione building qualities.
Since then, Immunocal has been successfully used in studies on humans including research into HIV/AIDS, hepatitis, Lyme disease, bacterial infections, cancer therapy, lung diseases, chronic fatigue syndrome and other conditions characterized by low glutathione levels and high oxidative stress. A new 2-year study that started in July 2011 and currently underway is set to determine the effect of Immunocal on improving behaviors of children with autism.
Immunocal is the first dietary supplement listed in the US Physicians’ Desk Reference (PDR), US Pharmacist’s Red Book and Canadian Compendium of Pharmaceuticals and Specialties (CPS) which means it can be prescribed by doctors.
It is the first natural supplement to have received such scientific recognition.
I feel confident to state that undenatured whey protein Immunocal is the best, safest, most effective natural source of bioactive bonded cysteine necessary for glutathione production in cells.

Source: http://www.immunehealthscience.com/cysteine.html

Sunday, June 28, 2015

15 Plants and Herbs That Can Boost Lung Health, Heal Respiratory Infections And Even Repair Pulmonary Damage


A wave of viral and bacterial infections is sweeping across the Northern Hemisphere and people are taking longer to heal from an array of symptoms within the respiratory system. If you are resorting to conventional medicine to address these infections with antibiotics, you are not only adding to the problems associated with antibiotic resistance, but you're also doing little to address the healing mechanisms within your body to address the cause. 


Herbal remedies not only boost lung health, but they can heal infections and even repair lung damage. Here are 15 of the best herbs to boost lung health.  

1. LICORICE ROOT

Licorice is one of the more widely consumed herbs in the world. In Traditional Chinese Medicine it occurs in more formulas than any other single herb because it is thought to harmonize the action of all other herbs. Licorice is very soothing and softens the mucous membranes of the throat and especially the lungs and stomach and at the same time cleanses any inflamed mucous membrane that needs immune system support. . It reduces the irritation in the throat and yet has an expectorant action. It is the saponins (detergent-like action) that loosen the phlegm in the respiratory tract, so that the body can expel the mucus. Compounds within this root help relieve bronchial spasms and block the free radical cells that produce the inflammation and tightening of the air ways. The compounds also have antibacterial and antiviral effects to them as well which helps fight off viral and bacterial strains in the body that can cause lung infections. Glycrrhizins and flavonoids can even help prevent lung cancer cells from forming which means they can even prevent lung cancer.


2. COLTSFOOT


Coltsfoot has been traditionally by Native Americans for thousands of years to strengthen the lungs. It clears out excess mucus from the lungs and bronchial tubes. It soothes the mucus membranes in the lungs, and has been shown in research to assist with asthma, coughs, bronchitis, and other lung ailments. Coltsfoot is available in dried form for tea or as an alcohol extract known as a tincture.

3. CANNABIS
The toxic breakdown of therapeutic compounds in cannabis from burning the plant are totally avoided with vaporization. Extraction and inhaling cannabinoid essential oils of the unprocessed plant affords significant mitigation of irritation to the oral cavity that comes from smoking. Cannabis is perhaps one of the most effective anti-cancer plants in the world shown in study after study to stimulate cannabinoid receptor activation in specific genes and mediate the anti-invasive effect of cannabinoids. Vaporizing cannabis allows the active ingredients to stimulate the body's natural immune response and significantly reduces the ability of infections to spread. Vaporizing cannabis (especially with very high amounts of cannabinoids) opens up airways and sinuses, acting as a bronchodilator. It is even a proven method to treat and reverse asthma.

4. OSHA ROOT


Osha is an herb native to the Rocky Mountain area and has historically been used by the Native Americans for respiratory support. The roots of the plant contain camphor and other compounds which make it one of the best lung-support herbs in America. One of the main benefits of osha root is that it helps increase circulation to the lungs, which makes it easier to take deep breaths. Also, when seasonal sensitivities flare up your sinuses, osha root which is not an actual antihistamine, does produce a similar effect and may be help calm respiratory irritation.


5. THYME
Thyme is very powerful in the fight against chest congestion. It produces powerful antiseptic essential oils which are classified as naturally antibiotic and anti-fungal. Thyme is a well known to zap acne than expensive prescription creams, gels and lotions. Thyme tea has the power to chase away and eliminate bacteria and viruses so whether your infection is based on either, it will work. Thyme has been used as a lung remedy consumed since antiquity and is used extensively to day to prevent and treat respiratory tract infections and bacterial infection pneumonia.


6. OREGANO


Although oregano contains the vitamins and nutrients required by the immune system, its primary benefits are owed to its carvacrol and rosmarinic acid content. Both compounds are natural decongestants and histamine reducers that have direct, positive benefits on the respiratory tract and nasal passage airflow. Oil of oregano fights off the dangerous bacteria Staphylococcus aureus, better than the most common antibiotic treatments. Oregano has so many health benefits that a bottle of organic oregano oil should be in everyone's medicine cabinet.


7. LOBELIA


Did you know that horses given lobelia are able to breath more deeply? Its benefits are not limited to equestrians. It has been used as "asthmador" in Appalachian folk medicine. Lobelia, by some accounts, is thought to be one of the most valuable herbal remedies in existence. Extracts of Lobelia inflata contain lobeline, which showed positive effects in the treatment of multidrug-resistant tumor cells. Lobelia contains an alkaloid known as lobeline, which thins mucus, breaks up congestion. Additionally, lobelia stimulates the adrenal glands to release epinephrine, in effect, this relaxes the airways and allows for easier breathing. Also, because lobelia helps to relax smooth muscles, it is included in many cough and cold remedies. Lobelia should be part of everyone's respiratory support protocol!

8. ELECAMPANE
Elecampane has been used by Native Americans for many years to clear out excess mucus that impairs lung function. It is known as a natural antibacterial agent for the lungs, helping to lessen infection particularly for people who are prone to lung infections like bronchitis. Herbal practitioners often recommend one teaspoon of the herb per cup of boiling water, drunk three times daily for two to three weeks but elecampane is also available in tincture format for ease.

9. EUCALYPTUS


Native to Australia, eucalyptus isn't just for Koala bears! Aborigines, Germans, and Americans have all used the refreshing aroma of eucalyptus to promote respiratory health and soothe throat irritation. Eucalyptus is a common ingredient in cough lozenges and syrups and its effectiveness is due to a compound called cineole. Cineole has numerous benefits -- it's an expectorant, can ease a cough, fights congestion, and soothes irritated sinus passages. As an added bonus, because eucalyptus contains antioxidants, it supports the immune system during a cold or other illness.

10. MULLEIN


Both the flowers and the leaves of the mullein plant are used to make an herbal extract that helps strengthen the lungs. Mullein is used by herbal practitioners to clear excess mucus from the lungs, cleanse the bronchial tubes, and reduce inflammation that is present in the respiratory tract. A tea can be made from one teaspoon of the dried herb to one cup of boiled water. Alternatively, you can take a tincture form of this herb.


11. LUNGWORT


Lungwort is a tree-growing lichen that actually resembles lung tissue in appearance. However, this natural remedy doesn't just look the part. As early as the 1600s, lungwort has been used to promote lung and respiratory health and clear congestion. Pulmonaria selections come in all kinds so seek an herbologist for direction. Lungwort also contains compounds that are powerfully effective against harmful organisms that affect respiratory health.


12. CHAPARRAL


Chaparral, a plant native to the southwest, has been appreciated by the Native Americans for lung detoxification and respiratory support. Chaparral contains powerful antioxidants that resist irritation and NDGA which is known to fight histamine response. NDGA inhibits aerobic and anaerobic glycolysis (the energy-producing ability) of cancer cells. Chaparral is also an herb that fights harmful organisms. The benefits of chaparral are most available in a tincture extraction but chaparral tea may support respiratory problems by encouraging an expectorant action to clear airways of mucus.

13. SAGE
Sage's textured leaves give off a heady aroma, which arises from sage's essential oils. These oils are the source of the many benefits of sage tea for lung problems and common respiratory ailments. Sage tea is a traditional treatment for sore throats and coughs. The rich aromatic properties arising from sage's volatile oils of thujone, camphor, terpene and salvene can be put to use by inhaling sage tea's vapors to dispel lung disorders and sinusitis. Alternatively, brew a strong pot of sage tea and place it into a bowl or a vaporizer.


14. PEPPERMINT



Peppermint, and peppermint oil, contains menthol -- a soothing ingredient known to relax the smooth muscles of the respiratory tract and promote free breathing. Dried peppermint typically contains menthol, menthone, menthyl acetate, menthofuran and cineol. Peppermint oil also contains small amounts of many additional compounds including limonene, pulegone, caryophyllene and pinene. Paired with the antihistamine effect of peppermint, menthol is a fantastic decongestant. Many people use therapeutic chest balms and other inhalants that contain menthol to help break up congestion. Additionally, peppermint is an antioxidant and fights harmful organisms.


15. PLANTAIN LEAF


Plantain leaf has been used for hundreds of years to ease cough and soothe irritated mucous membranes. Many of its active constituents show antibacterial and antimicrobial properties, as well as being anti-inflammatory and antitoxic. Clinical trials have found it favorable against cough, cold, and lung irritation. Plantain leaf has an added bonus in that it may help relieve a dry cough by spawning mucus production in the lungs.
Seek the advice of an herbologist or Naturopathic Doctor on the preparation, appropriate dosages and frequency according to your condition. Many of the herbs above may also be combined for cumulative effects. All of the above are available in various forms, as nutritional supplements, tea blends and prepared oils. You can always grow your own as well to ensure your herbs are organic and ethically harvested.

Source: www.preventdisease.com

Wednesday, June 17, 2015

Key Elements in the Theory of Atherosclerosis

Expect some surprises:
- Cholesterol does NOT cause heart disease.
- The first detectable signs of occluding arteries are NOT fatty streaks.
- Bypass surgery does NOT extend lives
- Polyunsaturated oils may actually do MORE harm than good (eg: Canola, Sunflower, Soybean, Corn). The main difference between polyunsaturated fat and monounsaturated fat (like olive oil) is the structure which is unstable and wreaks havoc on the cells in your body; it contributes to oxidation and free radical damage in the body, which is linked to heart disease, cancer, Alzheimer's disease, autoimmune diseases and premature aging. The instability of polyunsaturated fats is especially volatile during any kind of processing. Even small amounts of light, moisture, air or heat damage polyunsaturated fat. Plus too much omega-6 fatty acids can also interfere with the use of the very important omega-3 fatty acids in the body.
- Yes, BUTTER is good for you. In the past few decades, butter has been blamed for everything from obesity to heart disease. But recently, it has been making a comeback as a “health food.” (More: http://authoritynutrition.com/7-reasons-why-butter-is-good-for-you/)



About Cholesterol :
High blood cholesterol levels (hypercholesterolemia) usually have little or nothing to do with the amount of cholesterol eaten. Cholesterol is a VITAL bodily substance. It is a constituent of bile; it helps to convert sunlight into vitamin D; it is used to produce sex hormones; and it is needed by every cell in the body to keep membranes waterproof and to assist in the transmission of nerve impulses. The brain requires large amounts of cholesterol ! Cholesterol is so important that the less of it we eat, the more of it our bodies produce. On an omnivorous diet, from 70 to 80% of the cholesterol in the body is endogenous (made within the body) and does not come from diet. Since cholesterol is found only in foods of animal origin, on a vegan (total vegetarian) diet, 100% of the cholesterol in the body is endogenous.

Cholesterol also serves as an antioxidant of last resort – when the body lacks sufficient dietary antioxidants (e.g. vitamin C, vitamin E, selenium) to counter the free radicals that damage arterial walls. In this role, cholesterol covers over patches of arterial damage and gives up electrons (i.e. becomes oxidized) in order to neutralize free radicals and prevent further damage to the arteries. In the process, this cholesterol becomes oxidized.


The other dietary/lifestyle factors that contribute to elevated cholesterol levels include: (a) not drinking enough water, (b) excess sugar intake, (c) insufficient dietary fiber, and (d) lack of exercise. High cholesterol readings can also be an overlooked symptom of low thyroid function.

Cholesterol-lowering prescription drugs are potentially lethal. They reduce cholesterol everywhere in the body, including in the brain - where cholesterol acts as an insulator to prevent water from entering nerve cells and shorting out electrical circuits.

Key Elements in the Theory of Atherosclerosis

- Free Radicals and Homocysteine* create tiny tears in the lining of artery walls
- Excess blood sugar accelerates this arterial damage
- the body patches arterial tears with fibrin (a clotting protein) and scarring
- Dead macrophages (immune cells) become trapped in the patches and scar tissue
- The macrophages swell up to become foam cells
- Through time, more and more substances become attracted to and trapped in the arterial patches - including collagen, fats, minerals (especially calcium), foreign proteins, heavy metals, phospholipids, mucopolysaccharides, muscle tissue, cellular debris, triglycerides, and cholesterol.
- The parts of the arterial tree most vulnerable to the accumulation of plaque are the coronary arteries, the carotid arteries, and the femoral arteries
- Plaque that is allowed to proliferate out of control will eventually cause a heart attack, a stroke, or gangrene.
-Antioxidants protect the arteries from damaging effects of oxygen free radicals. (an atioxidant is a molecule that can absorb a renegade electron without becoming a free radical itself). Dietary antioxidants include: vitamin C, vitamin E, and selenium.
- Vitamin C and B-vitamins encourage the body to make coenzyme Q10, an internally generated antioxidant
- Selenium, zinc and manganese facilitate the body's production of the free radical scavengers
- Vitamins B6, B12 and folic acid eliminate the homocysteine* hazard
- Vitamin C in large amounts encourages the arteries to produce LPL (Lipoprotein lipase), an enzyme that emulsifies and disposes of fats that have accumulated in artery walls
- Certain high potency nutrients act as chelating agents to remove minerals and heavy metals from arterial plaque - including vitamin C, L-cysteine, DL-methionine, and thiamine
 - Magnesium dissolves calcium deposits in arterial plaque
- Magnesium also prevents arterial spasms, some of which can be fatal
- Large amounts of vitamin E encourage the body to develop collateral circulation, in effect creating self-generated bypasses
- Choline emulsifies fats, keeping them from sticking together and thereby improving the flow characteristics of the blood 
- Vitamin E prevents blood platelets (also called "thrombocytes", are a component of blood whose function (along with the coagulation factors) is to stop bleeding by clumping and clogging blood vessel injuries) from sticking together, thus reducing their tendency to contribute to excessive coagulation in arterial patches
- Monounsaturated oils (e.g. olive, avocado, almond) have protective effect on arterial cell membranes


* Homocysteine is an amino acid and breakdown product of protein metabolism that, when present in high concentrations, has been linked to an increased risk of heart attacks and strokes. Elevated homocysteine levels are thought to contribute to plaque formation by damaging arterial walls. High levels may also act on blood platelets and increase the risks of clot formation; however, whether high levels of homocysteine actually cause cardiovascular disease has yet to be agreed upon. In addition, some evidence suggests that people with elevated homocysteine levels have twice the normal risk of developing Alzheimer's disease.

FACTS:

- The true cause of atherosclerosis is whatever damages the arterial wall. The most likely suspects are free radicals, homocysteine, and diabetes.
- The first visual evidence we have of developing atherosclerosis is what mistakenly appear to be fatty streaks in the inner liner of arteries.
- Cholesterol is a slippery, waxy substance that cannot possibly adhere to a smooth, healthy arterial lining. (similarly, fats cannot stick to a healthy arterial lining). 
- blood cholesterol levels are less influenced by cholesterol content of food than by stress factors. Such stress-causing factors can apparently consist of foods which contain virtually no cholesterol - like the microwaved vegetables.
- Reducing Stress Is extremely Important: (

-  countries like France have both a high consumption of fat and low incidence of heart disease ! (the French paradox)
- There is just as much cholesterol circulating in your veins as in our arteries, but plaque is found only in arteries and NEVER in veins.

Oxidized Cholesterol

Scientists observed that NOT all cholesterol in arterial deposits is the same; some of it has become OXIDIZED. They speculated that it must be the oxidized cholesterol that causes the damage; and from this assumption followed a number of dietary precautions, such as cooking eggs over low heat so as not to damage their cholesterol content. The oxidized cholesterol theory has 2 flaws:
1) the oxidized cholesterol is one of the last ingredients laid down in the arterial plaque, not the first
2) it is more likely that this cholesterol became oxidized after it accumulated in the plaque. An outer layer of cholesterol may have sacrificed itself in order to protect deeper layers and the artery itself from damaging effects of oxygen free radicals. From this perspective, cholesterol could be considered an antioxidant of last resort.

Inflammation

Inflammation is a nonspecific immune response that occurs in reaction to any type of bodily injury. C-reactive Protein (CPR) is a protein found in the blood, the levels of which rise in response to inflammation and are associated with atherosclerosis, diabetes, autoimmune disorders and sport injuries. In other words, atherosclerosis raises CPR levels, but not all elevated CPR levels are triggered by atherosclerosis.

Arterial inflammation usually increases CPR levels before any significant blockage shows up on ultra sound tests. This does not mean that inflammation causes atherosclerosis, however. Jumping to this kind of erroneous conclusion is known in logic as the post hoc proper hoc fallacy - meaning that just because one event precedes another does not prove that the former caused the latter. In scientific terms, this is the error of assuming that correlation is cause.
Inflammation is an effect, not a cause. Inflammation does not cause atherosclerosis any more than inflammation causes arthritis or sports injuries. In all cases, inflammation is a response to damage of some kind. We need to find out what is causing the damage. With respect to atherosclerosis, the most causative agents are: FREE RADICALS, HOMOCYSTEINE and ELEVATED BLOOD GLUCOSE (as in diabetes).

Vitamin C

Here is a remarkable fact: animals which produce ascorbate in the livers do NOT develop atherosclerosis. If you wish to induce atherosclerosis in animals for research purposes, you have to use monkeys or guinea pigs. The ability to produce vitamin C internally prevents an animal's arteries from plugging up. This is due to at least 3 biochemical mechanisms:
1) vitamin C is required for the production of Lipoprotein Lipase (LPL), an arterial cleansing enzyme
2) vitamin C is required for the production of coenzyme Q10, an antioxidant that protects arteries from damaging oxygen free radicals
3) vitamin C itself is a powerful antioxidant.
If the human liver were capable of producing vitamin C in the same way that animals' livers do, it would probably produce a range of 2gr to 10gr per day, when converted for equivalent body weight, the higher amounts being required during times of stress.
The implication is that by taking suitably high amounts of vitamin C throughout our entire lives, we may be able to prevent atherosclerosis. It is unlikely, however, that vitamin C supplementation alone would be capable of removing arterial plaque that has been accumulating over years.

Lipoprotein Lipase

Cholesterol, triglycerides and phospholipids are LIPOPROTEINS, the molecules of which consist of fats chemically linked to proteins. Lipoproteins are classified as very low-density (VLDL), low-density (LDL), intermediate density (IDL), and high density (HDL). It is thought that individuals with high blood levels of HDL are less predisposed to coronary heart disease than those with high blood levels of VLDL or LDL. This is because the lower density lipoproteins are puffer and tend to more easily block openings in the tiny capilaries or in the arteries that have become narrowed by pre-existing plaque. The body's natural way of reducing excess lipoproteins is to make Lipoprotein Lipase (LPL).

Lipoprotein Lipase (LPL) is a water soluble, fat splitting enzyme (an emulsifier) that hydrolyze triglycerides in lipoproteins, such as those foundin very low density lipoproteins (VLDL) in the blood, into free fatty acids and one monoacylglycerol molecule. It is also involved in promoting the cellular uptake of chylomicron remnants, cholesterol-rich lipoproteins, and free fatty acids. LPL is attached to the surface of some cells that line the capillaries and arteries, and is also distributed in adipose, heart and skeletal muscle tissue, as well as in lactating mammary glands.

Lipoprotein Lipase works like a detergent to emulsify excess cholesterol and triglyceride, breaking them down and enabling them to be carried safely away through the liver and bile. There's a catch however. The body requires an abundant supply of vitamin C in order to be able to produce LPL to do its job.
This ascorbate-LPL dependence may be one of the mechanisms by which most animals are protected from atherosclerosis and we humans are not. Without a sufficient high intake of vitamin C, the human body cannot produce enough LPL to prevent excess fats and cholesterol from accumulating in arterial plaque.

Lipoprotein(a)

Lipoprotein(a) is structurally similar to low density lipoproteins (LDL) and is often considered to be a marker for atherosclerotic diseases.
In other words, if there is a significant lipoprotein(a) reading in your blood work, you are theoretically considered to be at higher risk of developing atherosclerosis than if your other lipoprotein fractions are out of balance. But there is a missing link in this chain of reasoning.
Lipoprotein(a) may well indicate a genetic predisposition for elevated or distorted cholesterol readings. However, there is no conclusive scientific evidence that cholesterol or other lipoproteins actually cause atherosclerosis, plus a number of logical reasons why they cannot.

Co-enzyme Q10
  
Co-enzyme Q10 (ubiquinone, ubiquinol) is a vitamin-like substance that is present in ALL bodily cells and generates energy in the form of adenosine triphosphate (ATP). CoQ10 is present in large amounts in those organs with highest energy requirements, namely the heart, liver and kidneys. CoQ10 also functions as an antioxidant to protect cells against the damaging effects of oxygen free radicals. There combined actions of CoQ10 help both to strengthen the heart muscle and to prevent damage to arterial walls.

Internal production of CoQ10 is ascorbate dependant, which may be another of the reasons why most animals' bodies are protected against atherosclerosis, whereas those with hypoascorbemia are not.
If the body has sufficient high intake of vitamin C and B-vitamins, it may be capable of producing all the CoQ10 it needs - without resorting to dietary CoQ10. Large amounts of vitamin C can also supplement and even replace the antioxidant activity of CoQ10.
Cholesterol lowering drugs interfere with and deplete the body's production of CoQ10, however so anyone taking these pharmaceuticals is well advised also to take supplementary CoQ10.   

Free Radicals

A free radical is an unstable, highly reactive molecular fragment that contains an odd number of electrons and an open bond or half bond. If 2 radicals meet, both are eliminated. If a radical reacts with a nonradical, another free radical is produced. This type of event may become a chain reaction and may contribute to the development of ischemic injury, such as myocardial infarction (heart attach). Cascading free radical reactions appear to be the most significant cause of arterial damage.

Blood Sugar

All of the various sugars we consume are broken down in the digestive tract into simple sugars glucose (dextrose) and fructose (levulose), then immediately absorbed through the intestinal wall directly into the bloodstream. The LIVER converts fructose into glucose, so ultimately every king of sugar ends up as glucose (blood sugar). If we consume too much sugar, our blood becomes flooded with excess level of glucose. If our PANCREAS, LIVER and ADRENAL GLANDS are in fine working order, then this spike in blood sugar is only temporary. If our endocrine system is out of balance and we push our sugar consumption, then we may develop hypoglycemia or diabetes. (some forms of diabetes are caused or aggravated by genetic weakness).

Hypoglycemia is characterized by compulsive sugar consumption which triggers multiple highs and lows in blood sugar throughout the day. In diabetes, blood sugar is constantly too high. Unfortunatelly, high glucose levels accelerate free radical damage - the degree of which damage is most probably in direct proportion to how high the glucose level and for how much of the day. In the development of arterial damage:
a) diabetes is a hugely accelerating factor
b) hypoglycemia is probably an aggravating factor
c) in otherwise healthy people, high sugar meals may cause some degree of arterial stress.
Our bodies can getall of the glucose we need for optimal functioning from gradual breakdown of complex carbohydrates (eg: whole grains, starchy vegetables), thus avoiding spikes in blood sugar.

Blood Fats

The body has a very clever way of assuring that fats in the bloodstream stay within an acceptable range. The fats that we consume are broken down by the action of bile and amylase enzymes into simpler fatty acids that are absorbed into the lymphatic system rather than the bloodstream. To absorb fats directly into the blood would be fatal. Instead, fats circulate throughout the lymphatics and are transferred into the blood on an "as needed" basis. Thus, the quantity of fats in the blood is strictly regulated and is of no consequence to atherosclerosis. The quality of fats most assuredly is, however. Unstable polyunsaturated oils, rancid fats and trans fats circulating in our lymphatic system find their way into cellular membranes, thus increasing their vulnerability to free radical damage.

Niacin (vitamin B3)

When there is a need for additional support to dietary and lifestyle practices that can lower cholesterol, it simply makes sense to use natural compounds, which are actually safer and more effective than the prescription drugs commonly used for that purpose.
Niacin, or vitamin B3, has long been used to lower cholesterol. In fact niacin is recommended by the National Cholesterol Education Program as the first "drug" to use. Unlike many cholesterol-lowering drugs, which have actually been shown to reduce life expectancy, niacin can lower cholesterol safely and extend life.  Its effects are long-lasting. (The dose of niacin usually required to lower cholesterol is 1gram/3 times per day). 

NOTE: Besides safely reducing harmful cholesterol levels, another niacin feature is its ability to greatly reduce anxiety and depression. Yet another feature is that it dilates blood vessels and creates a sensation of warmth, called a "niacin flush." (reaction that is totally harmless). This is often accompanied with a blushing of the skin. It is this "flush" or sensation of heat that indicates a temporary saturation of niacin. 
 
When you flush, you can literally see and feel that you've taken enough niacin. The idea is to initially take just enough niacin to have a slight flush.  This means a pinkness about the cheeks, ears, neck, forearms and perhaps elsewhere. A slight niacin flush should end in about fifteen minutes or so. If you take too much niacin, the flush may be more pronounced and longer lasting.  If you flush beet red for half an hour and feel weird, well, you took too much. And a large dose of niacin on an empty stomach is certain to cause profound flushing.
 
The dose required to reduce harmful cholesterol can result in flushing of the skin so you might want to buy a slow-released product. (forms of B3 that don't create flushing like inositol hexaniacinate). 

Source: www.rowlandpub.com/bypass.php