Vitamin B12 is an essential vitamin that’s crucial for many vital metabolic and hormonal functions — including the production of digestive enzymes and carrying important nutrients into and out of cells. Due to how it helps convert and synthesize many other compounds within the body, it’s needed for well over 100 daily functions. Some of the roles that are attributed to vitamin B12 include: red blood cell production, DNA/RNA synthesis, methylation and producing the coating of the nerves.

Biotin, also known as vitamin B7, is one of the B vitamins, a group of chemically distinct, water-soluble vitamins that also includes thiamine, riboflavin, niacin, pantothenic acid, pyridoxine, folic acid, and others.

Protein synthesis - Glutathione maintains our proteins in their proper form. Its sulfur atom reacts with unnatural sulfur-sulfur bonds in proteins, breaking them and allowing the proper pairings to form.Amino acid transport (transport - movement into, out of, within a cell, or between cells, by means of some agent such as a transporter) - Glutathione is predominately located in the cell, whereas a major fraction of the cellular y-glutamyl transpeptidase (glutathione enzyme) is on the external surface of cell membranes. This means intracellular glutathione is translocated out of many cells – glutathione moves substances, such as amino acids, in and out of the cell.

Biotin is important in a number of essential metabolic reactions in humans, including catalyzing the synthesis of fatty acids, metabolism of the amino acid leucine, and gluconeogenesis (generation of glucose from non-sugar carbon substrates like pyruvate, glycerol, and amino acids). Biotin is important in cell growth; plays a role in the Krebs cycle, which is the biochemical pathway in which energy is released from food (glucose, amino acids, and fat); helps with the transfer of carbon dioxide; and is useful in maintaining a steady blood sugar level.

Initial symptoms of biotin deficiency include:

1. Dry skin

2. Seborrheic dermatitis

3. Fungal infections

4. Rashes including erythematous peri-orofacial macular rash

5. Fine and brittle hair

6. Hair loss or total alopecia

GSH is a small protein molecule composed of 3 amino acids: cysteine, glutamate, and glycine called GSH precursors or building blocks. GSH is produced out of these three precursors in every cell of the human body and performs many important roles, such as:

Enhancement of systemic immune function - The immune system works best if the lymphoid cells have properly balanced glutathione. The cloning of T-cells consumes large quantities of cysteine. Macrophages (type of white blood cells), which are only present in sufficient quintiles when there is sufficient glutathione, provide the cysteine for the T-cell cloning. Glutathione regulates the binding, internalization, degradation and T-cell proliferation by increasing, as much as two times, the number of binding cellular receptors. More receptors equates to more T-cells being produced simultaneously (multiple T-cell cloning). Cellular GSH also affects the growth and replication of T-cells through growth stimulating cytokines.

Enhancement of humoral immune function - The role of glutathione in the humoral response is that it protects the cells taking part in the humoral response all along this complex process.

A quick synapses of the humoral immune response: “humoral” means circulating in the bloodstream. This is an immune response (chiefly against bacterial invasion) that is mediated by B cells and involves the transformation of B cells into plasma cells that produce and secrete antibodies to a specific antigen.

The process in a nutshell: macrophages engulf and digest the invading pathogen. The digested pieces activate helper T cells which in turn activate the proliferation of B cells that are programed for the specific invading pathogen.

Recycling of other antioxidants (master antioxidant role) - Glutathione recycles oxidized lipoic acid, vitamin C and E by restoring them to an active state, mostly by donating the electrons that they used in metabolizing (neutralizing) free radicals. So, instead of having this army of antioxidants flushed out, they are recycled by glutathione and sent back out to work.

Vitamin C is a potent reducing agent, meaning that it readily donates electrons to recipient molecules. Related to this oxidation-reduction (redox) potential, two major functions of vitamin C are as an antioxidant and as an enzyme cofactor.

Vitamin C is the primary water-soluble, non-enzymatic antioxidant in plasma and tissues. Even in small amounts vitamin C can protect indispensable molecules in the body, such as proteins, lipids (fats), carbohydrates, and nucleic acids (DNA and RNA), from damage by free radicals and reactive oxygen species (ROS) that are generated during normal metabolism, by active immune cells, and through exposure to toxins and pollutants (e.g., certain chemotherapy drugs and cigarette smoke). Vitamin C also participates in redox recycling of other important antioxidants; for example, vitamin C is known to regenerate vitamin E from its oxidized form.


Vitamin C’s role as a cofactor is also related to its redox potential. By maintaining enzyme-bound metals in their reduced forms, vitamin C assists mixed-function oxidases in the synthesis of several critical biomolecules. Symptoms of vitamin C deficiency, such as poor wound healing and lethargy, result from impairment of these enzymatic reactions and insufficient collagen, carnitine, and catecholamine synthesis.

Vitamin C affects several components of the human immune system; for example, vitamin C has been shown to stimulate both the production and function of leukocytes (white blood cells), especially neutrophils, lymphocytes, and phagocytes. Specific measures of functions stimulated by vitamin C include cellular motility, chemotaxis, and phagocytosis. Neutrophils, mononuclear phagocytes, and lymphocytes accumulate vitamin C to high concentrations, which can protect these cell types from oxidative damage. In response to invading microorganisms, phagocytic leukocytes release non-specific toxins, such as superoxide radicals, hypochlorous acid ("bleach"), and peroxynitrite; these reactive oxygen species kill pathogens and, in the process, can damage the leukocytes themselves. Vitamin C, through its antioxidant functions, has been shown to protect leukocytes from self-inflicted oxidative damage. Phagocytic leukocytes also produce and release cytokines, including interferons, which have antiviral activity. Vitamin C has been shown to increase interferon levels in vitro.


Collagen is the protein that forms connective fibers in tissues such as skin, ligaments, cartilage, bones, and teeth. Collagen also acts as a kind of intracellular “glue” that gives support, shape, and bulk to blood vessels, bones, and organs such as the heart, kidneys, and liver. Collagen fibers keep bones and blood vessels strong and help to anchor our teeth to our gums. As the most abundant protein in the body, collagen accounts for more mass than all the other proteins put together.