Boron
neutron capture therapy (BNCT) is a binary therapeutic approach.
Nonradioactive boron-10 atoms accumulated in tumor cells combining
with the neutron beams produce two highly energetic particles that
could eradicate the cell that takes it and the neighboring cells.
Small molecules that carry boron atom, e.g. 5- and 6-boronated and
2,7-diboronated tryptophans, were assessed for their boron accumulation
in U87-MG, LN229, and 3T3 for BNCT. TriBoc tryptophan, TB-6-BT, shows
boron-10 at 300 ppm in both types of tumor cells with a tumor to normal
ratio (T/N) of 5.19–5.25 (4 h). TB-5-BT and DBA-5-BT show boron-10
at 300 ppm (2 h) in U87-MG cells. TB-5-BT exerts a T/N of >9.66
(1
h) in LN229 compared with the current clinical boronophenyl alanine
with a highest T/N of 2.3 (1 h) and accumulation concentration of
<50 ppm. TB-5-BT and TB-6-BT warrant further animal study.
A small fenbufen library comprising 18 compounds was prepared via Suzuki Miyara coupling. The five-step preparations deliver 9–17% biphenyl compounds in total yield. These fenbufen analogs exert insignificant activity against the IL-1 release as well as inhibiting cyclooxygenase 2 considerably. Both the para-amino and para-hydroxy mono substituents display the most substantial COX-2 inhibition, particularly the latter one showing a comparable activity as celecoxib. The most COX-2 selective and bioactive disubstituted compound encompasses one electron-withdrawing methyl and one electron-donating fluoro groups in one arene. COX-2 is selective but not COX-2 to bioactive compounds that contain both two electron-withdrawing groups; disubstituted analogs with both resonance-formable electron-donating dihydroxy groups display high COX-2 activity but inferior COX-2 selectivity. In silico simulation and modeling for three COX-2 active—p-fluoro, p-hydroxy and p-amino—fenbufens show a preferable docking to COX-2 than COX-1. The most stabilization by the p-hydroxy fenbufen with COX-2 predicted by theoretical simulation is consistent with its prominent COX-2 inhibition resulting from experiments.
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