RESUMEN
Photodynamic action has been used for diverse biomedical applications, such as treating a broad range of bacterial infections. Based on the combination of light, dioxygen, and photosensitizer (PS), the photodynamic inactivation (PDI) approach led to the formation of reactive oxygen species (ROS) and represented a non-invasive, non-toxic, repeatable procedure for pathogen photoinactivation. To this end, different tetrapyrrolic macrocycles, such as porphyrin (Por) dyes, have been used as PSs for PDI against microorganisms, mainly bacteria. Still, there is significant room for improvement, especially new PS molecules. Herein, unsymmetrical new pyridinone (3−5) and thiopyridyl Pors (7) were prepared with α-, ß-, or γ-cyclodextrin (CD) units, following their quaternization to perform the corresponding free-base Pors (3a−5a and 7a), and were compared with the already-known Pors 6a and 8a, both bearing thiopyridinium and CD units. These water-soluble porphyrins were evaluated as PSs, and their photophysical and photochemical properties and photodynamic effects on E. coli were assessed. The presence of one CD unit and three positive charges on the Por structure (3a−5a and 7a) enhanced their aqueous solubility. The photoactivity of the cationic Pors 3a−5a and 6a−8a ensured their potential against the Gram-negative bacterium E. coli. Within each series of methoxypyridinium vs thiopyridinium dyes, the best PDI efficiency was achieved for 5a with a bacterial viability reduction of 3.5 log10 (50 mW cm−2, 60 min of light irradiation) and for 8a with a total bacterial viability reduction (>8 log10, 25 mW cm−2, 30 min of light irradiation). Here, the presence of the methoxypyridinium units is less effective against E. coli when compared with the thiopyridinium moieties. This study allows for the conclusion that the peripheral charge position, quaternized substituent type/CD unit, and affinity to the outer bacterial structures play an important role in the photoinactivation efficiency of E. coli, evidencing that these features should be further addressed in the pursuit for optimised PS for the antimicrobial PDI of pathogenic microorganisms.
RESUMEN
Photodynamic inactivation (PDI) of microorganisms has been used for the treatment of bacterial infection. PDI is based on the combination of three non-toxic elements: a photosensitizer (PS), light and molecular oxygen, which lead to the formation of reactive oxygen species (ROS) that cause lethal oxidative damage into the target pathogenic bacteria. For that, clinical approved tetrapyrrolic macrocycles, with particular emphasis on photoactive porphyrin (Por) dyes, have been used as PS in PDI for different biomedical applications. Two novel unsymmetrical free-base thiopyridyl Pors conjugated with α- or γ-CD units (Pors 2 and 3) were prepared and the corresponding cationic ones (Pors 2a and 3a) were assessed as water-soluble photosensitizer (PS) agents by photophysical, photochemical and E. coli photobiological studies. The presence of the CD unit and the positive charges on the Por periphery (2a and 3a) enhance their solubility in aqueous media. The photoactivity of the two cationic Pors 2a and 3a ensures their potential as PDI drugs against Gram-negative bacteria model, a bioluminescent E. coli, which the best PDI efficiency was determined for Por 3a that achieved the highest bacterial reduction of 4.0 log10 (ANOVA, p < 0.0001), reaching the detection limit of the method after 15 min.