Vitamin C is generally considered to be an important "nutrient," but its perceived value usually ends there. Only rarely does the public (and the medical profession) glimpse its true potential in the prevention and treatment of disease -- and this because, by legal definition (in the US), only FDA-approved drugs can prevent, treat and cure disease.
This does not mean, however, that essential nutrients like Vitamin C cannot in fact prevent and treat disease, i.e. only because it is illegal to speak truthfully about something, doesn't mean that that something isn't true. The National Library of Medicine, in fact, contains thousands of studies demonstrating vitamin C's ability to significantly improve health.
The best thing 'we the people' can do, despite our lack of medical degrees and licensure, and without the FDA's iron-fisted legal and regulatory apparatus on our side, is to use the peer-reviewed research at our disposal to inform and protect our treatment decisions.
Perhaps we must revisit an important moment in history to regain a sense of how profoundly vitamin C deficiency and vitamin C therapy can affect health. James Lind (1716-1794), pioneer of naval hygiene in the British Royal Navy, conducted the first ever clinical trial proving that citrus fruits cured scurvy. Lind’s discovery saved tens of thousands of seamen from the ravages of scurvy, spurring England’s naval supremacy, putatively changing the course of world history.
If significant historical events like these don’t provide enough evidence to vindicate the efficacy of nutrients like Vitamin C, molecular biology and the science of genetics can help to fill in the gaps.
It is a little known and under-appreciated fact that all humans are born with a serious, life-threatening genetic defect: namely, the inability to manufacture Vitamin C.
This defect occurred approximately 63 million years ago, when our haplorrhini (“simple nosed”) primate predecessors lost the gene (Gulnolactone oxidase pseudogene – GULOP), responsible for the manufacture of Vitamin C from glucose.
The ability to synthesize Vitamin C, in fact, has been lost several times in vertebrates, e.g. in guinea pigs, some bats, some fishes, passeriform birds and in primates of the suborder Haplorrhini, which includes monkes, apes and humans.
It was Linus Pauling, two time Nobel Laurette, and the world’s foremost vitamin C proponent, who first brought this inborn error of metabolism to popular light. Pauling advocated taking large doses of Vitamin C (up to 10-12 grams a day) in order to offset the deficiencies of our modern diet. He believed that it was our movement away from a vitamin C rich fruit-and-vegetable based diet that explained the modern epidemic of heart disease.
According to this perspective, without adequate Vitamin C we are unable to produce the collagen necessary to heal our arteries. The Vitamin C starved body compensates for this by increasing the production of a very small and sticky type of cholesterol known as lipoprotein A, which leads to the formation of atheromatous plaque (clogged arteries). Linus Pauling advocated taking large amounts of vitamin C in combination with the amino acid lysine to reverse the damage done to the arteries, and to prevent recurrence.*
Indeed, a study published in 2008 showed that higher plasma vitamin C levels are associated with a significantly reduced risk of stroke. Scientists from the clinical gerontology unit at Addnbrooke’s University Hospital in Cambridge, UK, tracked 20,649 men and women aged 40 to 79 years, between 1993 and 1997. The group was followed through March 2005. Individuals who had the highest vitamin C levels showed a 42% reduction in stroke risk! If you compare this with Plavix’s 8.7 – 9.4% risk reduction, and the profound side effects drugs like these generate, one begins to understand why the media projection of “vitamins are toxic” propaganda serves only the interests of the drug companies.
Before one goes out and buys a bargain bottle of Vitamin C tablets, one should be advised that ascorbic acid is not exactly the same thing as Vitamin C. Ascorbic acid is found within the Vitamin C complex as it exists in food, but is only one of a number of inseparable cofactors, such as rutin, bioflavonoids (vitamin p), factor k, factor j, factor p, ascorbinogen, protein chaperones, and various enzymes like tyrosinase, which together in their entirety constitute the whole food complex.
Ascorbic acid is also 10 times more acidic than the naturally buffered Vitamin C found in raw food, and will on occasions lead to stomach upset, calcium loss from the bones, and kidney stones, in susceptible individuals. Traditionally ascorbic acid is produced semi-synthetically from corn or rice starch through a heavily chemical dependent process. Ascorbic acid can be considered no more natural than white flour, and yet despite this fact, has very little toxicity relative to pharmaceuticals, and can be used in much higher doses than the FDA’s Recommended Daily Allowance without adverse side effects.
The difference between ascorbic acid and Vitamin C in whole food form was perfectly clear to Szent-Gyorgi who received a Nobel Prize in 1937 for discovering Vitamin C. Even though Szent-Gyorgi received international recognition for identifying ascorbic acid as Vitamin C, his later research lead him to conclude that ascorbic acid had very little anti-scurvy activity in and of itself. Szent-Gyorgi found that the vitamin C found in organ meats and food sources like paprika, where the aforementioned cofactors are intact, were far superior in combating scurvy. We would be well served to acknowledge that all raw fruits and vegetables contain a “life force” that can not be fully decomposed or reduced to the chemical skeleton within which the life force of “vitamin activity” works, no more than our life/soul can be reduced to the $10 or so worth of chemical building blocks that our body is composed of. Fortunately there are vitamin manufacturers out there who acknowledge this fact, and produce raw whole food concentrates rich in vitamin activity. When eating raw, organic fruits and vegetables is not an option, or when higher levels are needed, these supplements offer authentic therapeutic activity.
The history of vitamin C illustrates just how profoundly important it is for us to get these vital nutrients known as “vitamins,” and that they are best derived from food. If we choose to overlook the importance of vitamins in maintaining health, and yes, even preventing and reversing disease, we will be forced to accept a pharmaceutically driven medical perspective that believes that health is the absence of symptoms, and that symptoms are to be combated or driven back deep into our bodies with sublethal dosages of toxic chemicals, i.e. drugs. Such as perspective on disease is itself so diseased that there is no escaping the ill health that results from it. We must remember that there has never been a disease that has been caused by a lack of a drug…..therefore, why would it ever be considered sound medical practice to treat disease with drugs, as a first line of treatment?
*If Linus Pauling and other Vitamin C researchers are correct and a deficiency of Vitamin C causes the breakdown of collagen in the artery, aspirin therapy, which causes Vitamin C deficiency, would not be considered a safe way to reduce cardiac mortality. To the contrary, it would further destabilize the strength and elasticity of the artery leading to hemorrhage, which is the primary deadly side effect of aspirin therapy.
Oxidative Stress
Endothelial Dysfunction
DNA damage
Cortisol: High
Hepatitis C
Autism
C-Reactive Protein
Coronary Artery Disease
Endometriosis
Hepatitis A
Inflammation
Macular Degeneration
Peripheral Vascular Diseases
Pre-Eclampsia
Tuberculosis
Cataract
Asthma
Gastric Cancer
Helicobacter Pylori Infection
Aging Skin
Atherosclerosis
Aortic Aneurysm
Cardiovascular Diseases
Chronic Obstructive Pulmonary Disease
Common Cold
Ehlers-Danlos Syndrome
Esophageal Cancer
Hypertension
Obesity
Peripheral Arterial Disease
Smoking
Upper Respiratory Infections
Radiation Induced Illness
Bone Fractures
Cancers: All
Cholesterol: Oxidation
Hyperlipidemia
Aging
Arteriosclerosis
Lipid Peroxidation
Neuralgia: Post Herpetic
Alcohol Toxicity
Gastric Ulcer
Hyperthyroidism
Infertility: Female
Stress
Acute Myeloid Leukemia
Barrett Esophagus
Cystic Fibrosis
Non-Hodgkin Lymphoma
Pancreatic Cancer
Surgery: All
Adiponectin: Low Levels
Anemia: Hemolytic
Anemia: Iron Deficiency
Aortic Stenosis
Aspirin-Induced Toxicity
Asthma: Bronchial
Athletic Performance
Athletic Performance: Recovery
Attention Deficit Disorder with Hyperactivity
Attention Deficit Hyperactivity Disorder
Autism Spectrum Disorders
Breast Cancer: Prevention
COPD
Catecholamines: Elevated
Childhood Cognitive Disorders
Childhood Deficiencies
Childhood Infections
Connective Tissue Diseases
Diabetes Mellitus: Type 2
Diabetic Neuropathies
Duodenal Ulcer
Epidermolysis Bullosa
Exercise-Induced Tissue Damage
Fibromyalgia
Genital Warts
Gestational Diabetes
Graves Disease
Heart Failure
Hemodialysis
High Cortisol
High Homocysteine
Immunotherapy: Adoptive
Kidney Cancer
Kidney Stones
Knee Replacement Surgery: Adverse Effects
Larsen Syndrome
Lead Poisoning
Leukoplakia
Lichen Planus
Lymphoma: Mantle Cell
Marfan Syndrome
Migraine Disorders
Mortality: All-Cause
Myelodysplastic Syndrome
NSAID-induced toxicity
Peripheral Neuropathies
Postmenopausal Disorders
Postpartum Depression
Precancerous Conditions
Pregnancy: Prevention of Problems
Pregnancy: Urinary Tract Infections
Purpura: Thrombocytopenic
Raynaud Disease
Rhinosinusitis
Sclerosis: Systemic
Skin Diseases
Sleep Apnea: Central
Stroke: Prevention
Thalassemia
Thyroid Cancer
Trauma Patients
Urinary Tract Infections
Vision Loss
Pyrethroid Insecticide Induced Toxicity
Breast Cancer
Pesticide Toxicity
Aflatoxicosis
Alzheimer's Disease
Tumors
Aluminum Toxicity
Cadmium Poisoning
Charcot-Marie-Tooth Disease
Dyslipidemias
Fluoride Toxicity
Hypothyroidism
Influenza A
Lymphoma
Nickel Poisoning
Sperm Quality: Low
Chemical Exposure: Nitrobenzene
Gallstones
High Cholesterol
Nicotine/Tobacco Toxicity
Triglycerides: Elevated
Allergic Airway Diseases
Alloxan toxicity
Amebiasis
Ascites
Azo compound toxicity
Benzene Toxicity
Cancer Metastasis
Cartilage Diseases
Cervical Cancer
Chemotherapy-Induced Toxicity: Cisplatin
Cholestasis
Cytomegalovirus Infections
Emphysema: Pulmonary
Eosinophilia
Gingival melanin pigmentation
Hearing Loss
Hearing Loss: Noise-Induced
Hepatoma
Human Influenza
Hypercholesterolemia
Hyperglycemia
Hypertension: Pulmonary
Infertility: Male
Leukemia
Liver Cancer
Memory Disorders
Ovarian Cancer
Parainfluenza Virus Infections
Paramyxoviridae Infections
Pesticide-Induced Toxicity: Organochlorines
Pesticide-Induced Toxicity: Organophosphates
Polychlorinated biphenyl toxicity
Prenatal Chemical Exposures
Promyelocytic leukemia
Prophyrias
Prostatic Hyperplasia: Benign
Radiation Induced Illness: Bone Marrow
Radiation-Induced Illness: Americium
Radiation-Induced Illness: Plutonium
Radiation-Induced Illness: Radioiodine (Iodine-131)
Smoking: Pulmonary
Tin Poisoning
Arterial Plaque
Benzo[a]pyrene-induced Toxicity
Burkitt Lymphoma
Cancers: Multi-Drug Resistant
Candida Infection
Congestive Heart Failure
Corneal Neovascularization
Corticosteroid-Induced Toxicity
Degenerative Disk Disease
Endothelial Damage
Eye Diseases: Vitreous Disorders
Gout
HSV-1
Hormone Imbalances
Human Papillomavirus (HPV)
Human T-Cell Lymphotrophic Virus type 1 associated disease
Hyperuricemia
Infection: Antibiotic Resistant
Iron Overload
Iron Poisoning
Lung Cancer
Lyhmphoma: T-cell
Mesothelioma
Mitochondrial Diseases
Myocardial Infarction
Nutritional Deficiencies
Organ Transplantation: Cornea
Osteoporosis
Para-phenylenediamine Induced Toxicity
Parkinson Disease
Petroleum Exposure & Toxicity
Polio
Polycyclic aromatic hydrocarbon (PAH) toxicity
Prostate Cancer
Pseudomonas Infections
Pseudomonas aeruginosa
Rosacea
Scurvy
Stem Cell Transplant
Wound Healing
Wound Healing: Delayed
No comments:
Write comments