Unprecedented diterpenoid dimers with soluble epoxide hydrolase inhibitory effect from Euphorbia fischeriana.

Biseuphoids A (1) and B (2), two unprecedented ent-abietane-type diterpenoid dimers linked by monomeric blocks through C-17-C-12' and C-17-C-11', respectively, were isolated from Euphorbia fischeriana, along with their biogenesis related diterpenoid monomers, 17-hydroxyjolkinolide B (3), caudicifolin (4), and fischeriabietane C (5). Their structures were elucidated by extensive spectroscopy assisted by quantum chemical NMR and ECD calculations. The unusual dimeric skeletons are possibly derived from the adduct of diterpenoid monomers through Michael-like reactions. The novel dimers 1 and 2 exhibited inhibitory activities on soluble epoxide hydrolase (sEH) with IC50 values of 8.17 and 5.61 µM, respectively. Molecular dynamics studies illustrated that both 1 and 2 can occupy the catalytic pocket of sEH by forming stable hydrogen bonds with the key amino acid residues including Gln384, Asn378, Pro361, Ala365, Asn366, and Asn472.

Cytotoxic diterpenoid dimer containing an intricately caged core from Euphorbia fischeriana.

Bislangduoids A and B, a novel class of dimeric diterpenoids based on ent-abietanes tethered by C-17-C-15' bridge, were identified as trace components from a traditional Chinese medicine Euphorbia fischeriana (Langdu). Bislangduoid A features a highly oxidized scaffold incorporating a cage-like pentacyclic core. Their structures were elucidated by extensive spectroscopic techniques, electronic circular dichroism, and NMR calculations. The biosynthetic pathway for the dimeric skeleton and the unique caged moiety via Michael and acetal-formation reactions was proposed. Bislangduoid A showed pronounced cytotoxicity against HepG2 cells through the mitochondria-dependent apoptosis pathway.

In vitro effects of polyethylene glycol in University of Wisconsin preservation solution on human red blood cell aggregation and hemorheology.

Addition of hydroxyethyl starch (HES) to UW (University of Wisconsin) solution increases viscosity of the solution and red blood cell (RBC) aggregation. Recently, it was suggested that HES could be replaced by a new colloid, polyethylene glycol (PEG), in UW solution. The aim of this study was to see whether and how PEG affected RBC aggregation, and whether RBC aggregation parameters had any correlation with the molecular weight and concentration of PEG. After giving informed consent and signing consent documents, 12 healthy volunteers were enrolled in the study. Blood samples obtained from these volunteers were mixed with the test solutions with blood/solutions ratios of 5:1 and 1:1. Human RBC aggregation was investigated with an automatic hemorheological analyzer. Blood viscosity was measured with a cone-plate viscometer. Morphological characters of RBC aggregates were evaluated by light microscopy. It was found that viscosity was not affected by the Colloid-free UW solution. PEG20kDa (1 and 10 g/L) and PEG35kDa (1 g/L) had little effect on RBC aggregation, while PEG20kDa (30 g/L) and PEG35kDa (10 and 30 g/L) had a significant hyperaggregating effect on RBC. In conclusion, PEGs had a potential hyperaggregating effect on human RBC. This effect is correlated with PEG molecular weight and concentration. The use of large molecular weight and high concentration PEG in UW solution accounts for extended and accelerated aggregation of erythrocytes. The use of low concentration PEG35kDa (1 g/L) would be the optimal choice.