Proline Enantiomers Discrimination by (L)-Prolinated Porphyrin Derivative Langmuir-Schaefer Films: Proof of Concept for Chiral Sensing Applications

A porphyrin derivative functionalized with the L-enantiomer of proline amino acid was characterized at the air-pure water interface of the Langmuir trough. The porphyrin derivative was dissolved in dichloromethane solution, spread at the air-subphase interface and investigated by acquiring the surface pressure vs. area per molecule Langmuir curves. It is worth observing that the behavior of the molecules of the porphyrin derivative floating film was substantially influenced by the presence of L-proline amino acid dissolved in the subphase (10(-5) M); on the contrary, the physical chemical features of the floating molecules were only slightly influenced by the D-proline dissolved in the subphase. Such an interesting chirality-driven selection was preserved when the floating film was transferred onto solid supports by means of the Langmuir-Schaefer method, but it did not emerge when a spin-coating technique was used for the layering of the tetrapyrrolic derivatives. The obtained results represent proof of concept for the realization of active molecular layers for chiral discrimination: porphyrin derivatives, due to their intriguing spectroscopic and supramolecular properties, can be functionalized with the chiral molecule that should be detected. Moreover, the results emphasize the crucial role of the deposition technique on the features of the sensing layers.

Automated summary

The behavior of porphyrin derivative floating film molecules was significantly influenced by the presence of L-proline amino acid dissolved in the subphase, while D-proline had only a slight influence. This chirality-driven selection was preserved through the Langmuir-Schaefer method, but not with the spin-coating technique. These results provide proof of concept for active molecular layers for chiral discrimination and emphasize the crucial role of the deposition technique on the features of the sensing layers.