Oleic acid is an unsaturated fatty acid that is the most widely distributed and abundant fatty acid in nature. It is used commercially in the preparation of oleates and lotions, and as a pharmaceutical solvent. Oleic acid occurs naturally in various animal and vegetable fats and oils. It is a component of the normal human diet as a part of animal fats and vegetable oils. Oleic acid may be responsible for the hypotensive (blood pressure reducing) effects of olive oil. Oleic acid has being shown to have a potential anticancer activity.

Linoleic acid is a naturally occurring omega-6 essential fatty acid, present in a variety of foods, including the oils. Linoleic acid is a precursor for arachidonic acid biosynthesis; on the first enzymatic step of the pathway involves delta-6-desaturase, which converts linoleic acid to gamma-lenolenic acid. Linoleic acid has beneficial effects on human skin and hair. Replacement of saturated fat with linoleic acid is advocated to improve serum lipoprotein profiles and reduce the risk of coronary artery disease. Linoleic acid was tested in clinical trilas as a possible remedy against multiple sclerosis.

Glycyrrhizic Acid is specific compound isolated from licorice plants. Ammonium Glycyrrhizate (also known as GLYCYRRHIZIN, AMMONIATED) is a salt, was investigated to be a safe and is used as ingredient in the formulation of makeup, fragrance, hair care, skin care, shaving, personal hygiene and suntan products.

dl-α-tocopheryl phosphate has a growth acceleration effect on domestic fowl. Also was confirmed, that in all investigated animals dl-α-tocopheryl phosphate has an ability to being converted into vitamin E.

Glycyrrhizic Acid is specific compound isolated from licorice plants. Ammonium Glycyrrhizate (also known as GLYCYRRHIZIN, AMMONIATED) is a salt, was investigated to be a safe and is used as ingredient in the formulation of makeup, fragrance, hair care, skin care, shaving, personal hygiene and suntan products.

Strontium ranelate is composed of an organic moiety (ranelic acid) and of two atoms of stable nonradioactive strontium. In vitro, strontium ranelate increases collagen and noncollagenic proteins synthesis by mature osteoblast enriched cells. The effects of strontium ranelate on bone formation were confirmed as strontium ranelate enhanced pre-osteoblastic cell replication. The stimulation by strontium ranelate of the replication of osteoprogenitor cell and collagen, as well as noncollagenic protein synthesis in osteoblasts, provides substantial evidence to categorize strontium ranelate as a bone-forming agent. In the isolated rat osteoclast assay, a pre-incubation of bone slices with strontium ranelate induced a dose- dependent inhibition of the bone resorbing activity of treated rat osteoclast. Strontium ranelate also dose-dependently inhibited, in a chicken bone marrow culture, the expression of both carbonic anhydrase II and the alpha-subunit of the vitronectin receptor. These effects showing that strontium ranelate significantly affects bone resorption due to a direct and/or matrix-mediated inhibition of osteoclast activity and also inhibits osteoclasts differentiation, are compatible with the profile of an anti-resorptive drug. Pharmacological and clinical studies suggest that strontium ranelate optimizes bone resorption and bone formation, resulting in increased bone mass, which may be of great value in the treatment of osteoporosis. Strontium ranelate is approved by EMA for the treatment of severe osteoporosis in postmenopausal women and in adult men.

Aconitine is an alkaloid found in the Aconitum species. Aconitine is a highly toxic cardiotoxin and neurotoxin. In China and other countries, the herbal extract containing aconitine was used for the treatment of pain in musculoskeletal disorders, however the safety margin between therapeutic analgesic effect of aconitine and its known cardiotoxic effect is so narrow that the treatment may cause poisoning and death. The mechanism of aconitine action is explained by its ability to activate voltage-dependent sodium-ion channels.

Cevadine, veratridine, and related lipophilic ceveratrum alkaloids cause activation of the voltage-sensitive Na+ channels of nerve, heart, and skeletal muscle cell membranes similar to pyrethrins. Both veratridine and cevadine alter the ion selectivity of Na+ channels and cause persistent activation. The receptor for these alkaloids has not been isolated, but experiments indicate it is distinct from that of pyrethrin. Structurally, veratridine and cevadine differ only in their acyl group. Cevadine has been used as an insecticide, acting as a paralytic agent with higher toxicity to insects than to mammals. It has been used to study Na+ channel blockers such as vincamine and vincanol by inducing Na+ channels in the presence and absence of the drugs being tested.

Cevadine, veratridine, and related lipophilic ceveratrum alkaloids cause activation of the voltage-sensitive Na+ channels of nerve, heart, and skeletal muscle cell membranes similar to pyrethrins. Both veratridine and cevadine alter the ion selectivity of Na+ channels and cause persistent activation. The receptor for these alkaloids has not been isolated, but experiments indicate it is distinct from that of pyrethrin. Structurally, veratridine and cevadine differ only in their acyl group. Cevadine has been used as an insecticide, acting as a paralytic agent with higher toxicity to insects than to mammals. It has been used to study Na+ channel blockers such as vincamine and vincanol by inducing Na+ channels in the presence and absence of the drugs being tested.

Cevadine, veratridine, and related lipophilic ceveratrum alkaloids cause activation of the voltage-sensitive Na+ channels of nerve, heart, and skeletal muscle cell membranes similar to pyrethrins. Both veratridine and cevadine alter the ion selectivity of Na+ channels and cause persistent activation. The receptor for these alkaloids has not been isolated, but experiments indicate it is distinct from that of pyrethrin. Structurally, veratridine and cevadine differ only in their acyl group. Cevadine has been used as an insecticide, acting as a paralytic agent with higher toxicity to insects than to mammals. It has been used to study Na+ channel blockers such as vincamine and vincanol by inducing Na+ channels in the presence and absence of the drugs being tested.