Density functional theory (B3LYP//6-311+G*) calculations including Poisson-Boltzmann implicit solvent were applied to study the formation of the trimethylboroxine.amine adduct with respect to methylboronic acid monomers and free amine in solution. Potential intermediates and transition states between intermediates were calculated to assess the thermodynamic and kinetic factors controlling this transformation. Our calculations suggest that the rate-determining steps are condensation reactions to form dimers and trimers, and closure of the boroxine ring. Fast amine exchange is expected throughout the transformation, and the most-stable intermediate is a dimer.amine adduct. Using our calculated barriers for the methyl system as a template, we assess the conversion of phenylboronic acid to the triphenylboroxine.amine adduct and find that the pathway is most likely similar, except that the transformation is thermodynamically and kinetically more favored for the phenyl system in the presence of pyridine.