Development of a lozenge for oral transmucosal delivery of trans-resveratrol in humans: proof of concept.

Resveratrol provides multiple physiologic benefits which promote healthspan in various model species and clinical trials support continued exploration of resveratrol treatment in humans. However, there remains concern regarding low bioavailability and wide inter-individual differences in absorption and metabolism in humans, which suggests a great need to develop novel methods for resveratrol delivery. We hypothesized that oral transmucosal delivery, using a lozenge composed of a resveratrol-excipient matrix, would allow resveratrol to be absorbed rapidly into the bloodstream. We pursued proof of concept through two experiments. In the first experiment, the solubility of trans-resveratrol (tRES) in water and 2.0 M solutions of dextrose, fructose, ribose, sucrose, and xylitol was determined using HPLC. Independent t-tests with a Bonferroni correction were used to compare the solubility of tRES in each of the solutions to that in water. tRES was significantly more soluble in the ribose solution (p = 0.0013) than in the other four solutions. Given the enhanced solubility of tRES in a ribose solution, a resveratrol-ribose matrix was developed into a lozenge suitable for human consumption. Lozenges were prepared, each containing 146±5.5 mg tRES per 2000 mg of lozenge mass. Two healthy human participants consumed one of the prepared lozenges following an overnight fast. Venipuncture was performed immediately before and 15, 30, 45, and 60 minutes following lozenge administration. Maximal plasma concentrations (Cmax) for tRES alone (i.e., resveratrol metabolites not included) were 325 and 332 ng⋅mL(-1) for the two participants at 15 minute post-administration for both individuals. These results suggest a resveratrol-ribose matrix lozenge can achieve greater Cmax and enter the bloodstream faster than previously reported dosage forms for gastrointestinal absorption. While this study is limited by small sample size and only one method of resveratrol delivery, it does provide proof of concept to support further exploration of novel delivery methods for resveratrol administration

Peak plasma concentration (<i>C</i>_max) of <i>t</i>RES following administration of a lozenge in reference to previously reported data.

<p>Note that the maximal plasma concentration (<i>C</i>_max) is that for trans-resveratrol (<i>t</i>RES) alone and therefore does not include any resveratrol metabolites.</p

Trans-resveratrol content of four individual lozenges created.

<p>Trans-resveratrol content of four individual lozenges created.</p

Data from human participants (both male).

<p>Note that the maximal plasma concentration (<i>C</i>_max) is that for trans-resveratrol (<i>t</i>RES) alone and therefore does not include any resveratrol metabolites.</p

Targeted cytosine methylation for in vivo detection of protein–DNA interactions

We report a technique, named targeted gene methylation (TAGM), for identifying in vivo protein-binding sites in chromatin. M.CviPI, a cytosine-5 DNA methyltransferase recognizing GC sites, is fused to a DNA-binding factor enabling simultaneous detection of targeted methylation, factor footprints, and chromatin structural changes by bisulfite genomic sequencing. Using TAGM with the yeast transactivator Pho4, methylation enrichments of up to 34- fold occur proximal to native Pho4-binding sites. Additionally, significant selective targeting of methylation is observed several hundred nucleotides away, suggesting the detection of long-range interactions due to higher-order chromatin structure. In contrast, at an extragenic locus lacking Pho4-binding sites, methylation levels are at the detection limit at early times after Pho4 transactivation. Notably, substantial amounts of methylation are targeted by Pho4-M.CviPI under repressive conditions when most of the transactivator is excluded from the nucleus. Thus, TAGM enables rapid detection of DNA–protein interactions even at low occupancies and has potential for identifying factor targets at the genome-wide level. Extension of TAGM from yeast to vertebrates, which use methylation to initiate and propagate repressed chromatin, could also provide a valuable strategy for heritable inactivation of gene expression