Polymeric proanthocyanidins are common constituents of many foods and beverages. Their fate in the human body remains largely unknown. Their metabolism by human colonic microflora incubated in vitro in anoxic conditions has been investigated using nonlabeled and (14)C-labeled purified proanthocyanidin polymers. Polymers were almost totally degraded after 48 h of incubation. Phenylacetic, phenylpropionic and phenylvaleric acids, monohydroxylated mainly in the meta or para position, were identified as metabolites by gas chromatography coupled to mass spectrometry (GC-MS). Yields were similar to those previously reported for flavonoid monomers. These results provide the first evidence of degradation of dietary phenolic polymers into low-molecular-weight aromatic compounds. To understand the nutritional properties of proanthocyanidins, it is therefore essential to consider the biological properties of these metabolites.
The gut absorption of proanthocyanidins (PAs) and of the related (+)-catechin monomer was investigated with colonic carcinoma (Caco-2) cells of a human origin, grown in monolayers on permeable filters. Permeability of various radiolabeled PAs differing in their molecular weight was compared with that of the radiolabeled (+)-catechin. No toxicity was observed at PA concentrations up to the physiological concentration of 1 mM. (+)-Catechin and PA dimer and trimer had similar permeability coefficients (P(app) = 0.9-2.0 x 10(-6) cm s(-1)) close to that of mannitol, a marker of paracellular transport. Paracellular transport was also indicated by the increase of absorption after reduction of the transepithelial electric resistance through calcium ion removal. In contrast, permeability of a PA polymer with an average polymerization degree of 6 (molecular weight 1,740) was approximately 10 times lower (P(app) = 0.10 +/- 0.04 x 10(-6) cm s(-1)). PAs, particularly the most astringent PA polymer, were also adsorbed on the epithelial cells. These results suggest that PA dimers and trimers could be absorbed in vivo and that polymer bioavailability is limited to the gut lumen.
Proanthocyanidins share common properties with other polyphenols, in particular their reducing capacity and ability to chelate metal ions. However, their polymeric nature clearly makes them different. They have a high affinity for proteins and their absorption through the gut barrier is likely limited to the molecules of low polymerization degree and to the metabolites formed by the colonic microflora, as suggested by in vitro experiments. The nutritional significance of proanthocyanidins is discussed in relation to their physico-chemical properties and bioavailability.
Proanthocyanidin polymers, oligomers, and the structurally related monomer (+)-catechin were labeled by incorporation of radioactive precursors in shoots of willow tree (Salix caprea L.). [1-(14)C]-Acetate and [U-(14)C]-phenylalanine precursors were fed through the cut stems or petioles of leaves. Optimization of several parameters such as the nature and origin of the plant material, leaf maturity, nature, and quantity of radioactive precursor applied and the duration of metabolism led to incorporation yields of 3.2% and to specific activities of 500 microCi/g. Detailed characterization of the products (polymerization degree, procyanidin/prodelphinidin ratio, specific activities) and purification by chromatography are reported. Some sugars bound to radiolabeled proanthocyanidin polymers were removed by enzymic treatment with a mixture of glycosidases. A radioactive purity close to 100% and specific activities suitable for bioavailability studies were obtained.
Nasal administration to rats of small molecules (tritiated water, tyrosine, and propanol) results in a higher concentration in the brain arterial blood than in other arteries. The preferential distribution is based on a counter current transfer, which takes place between nasal vein blood and brain arterial blood in the cavernous sinus-carotid artery complex. This model was used to investigate whether the antimigraine 5HT(1B/1D) receptor agonists sumatriptan and naratriptan may also be transferred by the system. The ratio of 'head':'heart' plasma concentrations obtained from two carotid catheters after intranasal administration was not different from 1.00 for either compound, and thus, there was no experimental evidence of a preferential local transfer of drug from the nose to the carotid artery circulation. However, plasma concentrations increased from the first minute after intranasal dosing suggesting that sumatriptan and naratriptan are absorbed into the general systemic circulation from the nasal cavity in rats in a first-order fashion with no lag time. This is consistent with the clinical onset of efficacy of sumatriptan after an intranasal dose which occurs as early as 15 min post dose.
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