Hyperforin has only been found in significant amounts in Hypericum perforatum with other related species such as Hypericum calycinum containing lower levels of the phytochemical. It accumulates in oil glands, pistils, and fruits, probably as a plant defensive compound. The first natural extractions were done with ethanol and afforded a 7:1 yield of crude extract to phytochemical however, this technique produced a mixture of hyperforin and adhyperforin. The extraction technique has since been modernized using lipophilic liquid CO2 extraction to afford a 3:1 crude to phytochemical extraction which is then further purified away from adhyperforin. This CO2 extraction is rather tricky still because typical 'supercritical' conditions extract less material whereas anything over 40 °C will degrade hyperforin. Other Hypericum species contain low amounts of hyperforin.
Chemistry
Hyperforin is a prenylatedphloroglucinol derivative and is a member of the Polycyclic polyprenylated acylphloroglucinol family, also known as the PPAP family. Hyperforin is a unique PPAP because it consists of a C8 quaternary stereocenter which was a synthetic challenge unlike other PPAP synthetic targets. The structure of hyperforin was elucidated by a research group from the Shemyakin Institute of Bio-organic Chemistry and published in 1975. A total synthesis of the non-natural hyperforin enantiomer was reported in 2010 which required approximately 50 synthetic transformations and relied heavily on basic organic reactivity. In 2010, an enantioselective total synthesis of the correct enantiomer was disclosed. The retrosynthetic analysis was inspired by hyperforin's structural symmetry and biosynthetic pathway. The synthetic route undertaken generated a prostereogenic intermediate which then established the synthetically challenging C8 stereocenter and facilitated the stereochemical outcomes for the remainder of the synthesis. Hyperforin is unstable in the presence of light and oxygen. Frequent oxidized forms contain a C3 to C9 hemiketal/heterocyclic bridge or will form furan/pyran derivatives.
Pharmacokinetics
Some pharmacokinetic data on hyperforin is available for an extract containing 5% hyperforin. Maximal plasma levels in human volunteers were reached 3.5 hours after administration of an extract containing 14.8 mg hyperforin. Biological half-life and mean residence time were 9 hours and 12 hours, respectively, with an estimated steady stateplasma concentration of 100 ng/mL for 3 doses per day. Linear plasma concentrations were observed within a normal dosage range and no accumulation occurred. In healthy male volunteers, 612 mg dry extract of St. John's wort produced hyperforin pharmacokinetics characterised by a half life of 19.64 hours.
Two meta-analyses of preliminary clinical trials evaluating the efficacy of St. John's wort for treating mild-to-moderate depression indicated a response similar to selective serotonin reuptake inhibitors and with better tolerance, although the long-term generalization of study results was limited by the short duration of reviewed studies.
