Hoodia gordonii: an up-to-date review of a commercially important anti-obesity plant.

Hoodia gordonii is a spiny succulent plant popularly consumed for its purported anti-obesity effect. Traditionally used by the Khoi-San of South Africa and Namibia as a hunger and thirst suppressant while on long hunting trips, the commercialisation of this plant has been highly controversial due to intellectual property rights and benefit sharing issues, as well as the fact that several prominent pharmaceutical companies involved in its development have withdrawn their interest. Quality control has been the main focus of scientific studies as the supply of H. gordonii plant material is limited due to its sparse geographical distribution, slow maturation rate, need for a permit to cultivate or export material as well as high public demand, contributing to adulteration of a large amount of products. Despite the isolation of numerous steroidal glycosides from H. gordonii, the main focus has been on the pregnane glycoside P57, considered to be the active ingredient and marker molecule to determine quality of raw material and products. Publications based on scientific studies of key aspects such as in vivo biopharmaceutics, the biological activity of all chemical constituents, clinical efficacy, and especially safety are insufficient or completely absent causing great concern as H. gordonii is one of the most widely consumed anti-obesity products of natural origin. This review offers an up-to-date overview of all the current available knowledge pertaining to H. gordonii achieved by systematic analysis of the available literature.

Characterization of in vitro pharmacokinetic properties of hoodigogenin A from Hoodia gordonii.

This study was aimed to predict the pharmacokinetic properties of hoodigogenin A, which is the aglycone of the oxypregnane steroidal glycoside P57AS3 (P57) isolated from Hoodia gordonii. A series of in vitro assays was used to predict its gastric, intestinal and metabolic stability, intestinal and blood brain barrier (BBB) transport, protein binding and interaction with major drug metabolising enzymes. In the simulated gastric fluid, hoodigogenin A was stable (2 % degradation in 60 minutes) whereas P57 was unstable (45 % degradation in 30 minutes). In simulated intestinal fluid, P57 was degraded to an extent of 8 % in 180 minutes, while hoodigogenin A was stable. Hoodigogenin A was efficiently transported by passive diffusion across Caco-2 and MDR1-MDCK monolayers with P(app) values in the range of 32 x 10(-6) cm/sec and 22 x 10(-6) cm/sec, respectively. The compound was metabolically unstable in human liver microsomes and S9 fractions with a CL' (int) of 71 and 120 mL/min/kg, respectively and was bound to the plasma proteins to an extent of 92 %. The compound strongly inhibited CYP3A4 activity (IC(50) 3 microM), indicating a possibility of drug-herb/botanical interactions when products containing H. gordonii are used simultaneously with other botanicals/herbs/drugs.

Effect of pregnandiol on caffeine metabolism in female rats.

Three groups of six 5-week-old Sprague Dawley female rats received i.p. injections of pregnandiol, 1.25, 2.50 or 5 mg/kg, respectively, in triolein daily for 7 days. Caffeine metabolism was studied in liver slices on day 8 by HPLC. Only primary metabolites were formed. N-1 demethylation was the most important pathway (theobromine represented 51% of total dimethylxanthines). Unlike in human in vitro or in vivo, 1,3,7-DAU (6-amino-5-(N-formylmethylamino)-1,3-dimethyluracil) was an important metabolite (9.7% of total caffeine metabolites). Pregnandiol inhibited N-1, N-3 and N-7 demethylation in vitro (-33%, -33% and -28%, respectively, at 5 mg/kg/day), but it had no effect on N-1 demethylation at 1.25 or 2.50 mg/kg/day. Pregnandiol at all doses had no effect on 1,3,7-trimethyluric acid and 1,3,7-DAU formation. These results are consistent with the hypothesis that C-8 hydroxylation and demethylation of caffeine are mediated by different isoenzymes. They indicate that pregnandiol is a potent inhibitor of microsomal drug metabolism, specifically of cytochrome P450 IA, which could explain the immaturity of some metabolic pathways of caffeine in neonates.

Stable isotope studies on steroid metabolism and kinetics: sulfates of 3 alpha-hydroxy-5 alpha-pregnane derivatives in human pregnancy.

The metabolism and production rates of 3 alpha-hydroxy-5 alpha-pregnan-20-one sulfate and the 3-sulfate and 3,20-disulfate of 5 alpha-pregnane-3 alpha,20 alpha-diol in pregnant women were studied. The steroid sulfates were labeled with deuterium in the 3 beta,11,11- or 3 beta,11,11,20 beta-positions and were injected intravenously. The deuterium content of steroids in the monosulfate and disulfate fraction of plasma collected at different times after the injection was determined by capillary column gas chromatography/mass spectrometry. The injected steroid sulfates underwent oxidoreduction at C-20 and 16 alpha-hydroxylation. In addition, the 3-sulfate of 5 alpha-pregnane-3 alpha,20 alpha-diol became hydroxylated at C-21. The pregnanediol and pregnanetriol monosulfates were also converted to disulfates. No evidence was obtained for a metabolic sequence involving hydrolysis, oxidoreduction, and resulfation at the C-3 position. Production rates and rates of metabolic transformations were determined using different one- and two-pool models. The production rate of the pregnanolone/pregnanediol monosulfate couple was 0.08 to 0.5 mmol/24 h, the variability probably depending both on individual factors and stage of pregnancy. The half-life time for oxidation and reduction at C-20 was 0.1 to 0.4 hours, reduction being the faster process. The half-life time for the turnover of the steroid skeleton was 1.3 to 3.3 hours. The injected steroid monosulfates were 16 alpha-hydroxylated at a rate of 1 to 8 mumol/24 h. A significant fraction of these 16 alpha-hydroxylated steroid sulfates, 0.5 to 25 mumol/24 h, was formed from other, probably unconjugated, precursors. The 16 alpha-hydroxylated steroid monosulfates underwent rapid oxidoreduction at C-20. The 3-sulfate of 5 alpha-pregnane-3 alpha,20 alpha-diol was hydroxylated at C-21. The production rate of 5 alpha-pregnane-3 alpha,20 alpha,21-triol 3-sulfate was 8 to 36 mumol/24 h in four women and 180 mumol/24 h in one woman, and this steroid was not formed from other precursors to a significant extent. 5 alpha-Pregnane-3 alpha,20 alpha-diol disulfate was a metabolic end product accounting for a major part of the elimination of the steroids injected. Its half-life time was 1.4 to 2.8 hours. The results show that the formation of sulfated steroids with a 3 alpha-hydroxy-5 alpha configuration may account for 50% of the metabolism of progesterone in late pregnancy.