Unraveling the benzocaine-receptor interaction at molecular level using mass-resolved spectroscopy.

The benzocaine-toluene cluster has been used as a model system to mimic the interaction between the local anesthetic benzocaine and the phenylalanine residue in Na(+) channels. The cluster was generated in a supersonic expansion of benzocaine and toluene in helium. Using a combination of mass-resolved laser-based experimental techniques and computational methods, the complex was fully characterized, finding four conformational isomers in which the molecules are bound through N-H···π and π···π weak hydrogen bonds. The structures of the detected isomers closely resemble those predicted for benzocaine in the inner pore of the ion channels, giving experimental support to previously reported molecular chemistry models.

Molecular recognition in the gas phase: benzocaine-phenol as a model of anaesthetic-receptor interaction.

The benzocaine-phenol complex is proposed as a model system of the interaction between the local anaesthetic benzocaine and the tyrosine residue. The complex has been generated by supersonic expansion of benzocaine and phenol in helium and probed by 1- and 2-color mass-resolved laser spectroscopies. The electronic excitation spectrum of the 1 : 1 complex spans some approximately 700 cm(-1) and includes well resolved bands from at least two isomers, as demonstrated using UV-UV hole burning spectroscopy. The combination of ion dip infrared spectroscopy (IDIRS) and ab initio calculations shows that both isomers are stabilized by an OH...N hydrogen bond between the phenol hydroxyl group and the benzocaine amino moiety, differing only in the conformation adopted by the benzocaine monomer (trans and gauche). The application of the fragmentation threshold method to benzocaine-phenol suggests the existence of chemical reactions in the electronic excited state of the complex and/or in the ion. Such hypothesis is also supported by the calculated potential energy curves along the hydrogen bond coordinate.

Combined experimental and theoretical study of the benzocaine/Ar van der Waals system in supersonic expansions.

The electronic spectra of Benzocaine x Ar(n), n = 0-4 were obtained using two-color resonance enhanced multiphoton ionization; the 1:1 and 1:2 clusters were investigated by ultraviolet/ultraviolet hole burning, stimulated emission pumping, and other laser spectroscopies. A single isomer was found for the 1:1 cluster, while two isomers of the 1:2 cluster were found: one with the two Ar atoms on the same side of the chromophore, and the other with the two Ar atoms sitting on opposite sides of the chromophore. The observed shifts point to the existence of a single isomer for the 1:3 and 1:4 species. Dissociation energies for the neutral ground and first excited electronic state and the ion ground electronic state of the complexes have been determined by the fragmentation threshold method and by ab initio calculations conducted at the MP2 level with 6-31++g(2d, p), 6-311++g(2d, p) and AUG-cc-pVTZ basis sets. The results are compared with those obtained for other similar systems.

ZEKE-PFI spectroscopy of benzocaine.

The adiabatic ionization threshold (AIT) of trans- and gauche-benzocaine has been measured by zero electron kinetic energy-pulsed field ionization (ZEKE-PFI) spectroscopy to be 7.8412+/-0.0008 eV (lasers at 34,134.4 and 29,109.3 cm(-1)) and 7.8421+/-0.0004 eV (34,144.8+29105.7 cm(-1)), respectively. AITs computed at the B3LYP/AUG-cc-p-VDZ level for the two conformers are some approximately 2,500 cm(-1) lower than the experimental; in contrast their energy difference is very close. The trans-benzocaine cation ZEKE spectra has been recorded taking a number of S(1) intermediate vibronic states. The spectra provide an energy threshold for the appearance of intramolecular vibrational redistribution (IVR) around approximately 540 cm(-1) in the S(1) state.