Carbon dots: Types, preparation, and their boosted antibacterial activity by photoactivation. Current status and future perspectives.

Carbon dots (CDs) correspond to carbon-based materials (CBM) with sizes usually below 10 nm. These nanomaterials exhibit attractive properties such us low toxicity, good stability, and high conductivity, which have promoted their thorough study over the past two decades. The current review describes four types of CDs: carbon quantum dots (CQDs), graphene quantum dots (GQDs), carbon nanodots (CNDs), and carbonized polymers dots (CPDs), together with the state of the art of the main routes for their preparation, either by "top-down" or "bottom-up" approaches. Moreover, among the various usages of CDs within biomedicine, we have focused on their application as a novel class of broad-spectrum antibacterial agents, concretely, owing their photoactivation capability that triggers an enhanced antibacterial property. Our work presents the recent advances in this field addressing CDs, their composites and hybrids, applied as photosensitizers (PS), and photothermal agents (PA) within antibacterial strategies such as photodynamic therapy (PDT), photothermal therapy (PTT), and synchronic PDT/PTT. Furthermore, we discuss the prospects for the possible future development of large-scale preparation of CDs, and the potential for these nanomaterials to be employed in applications to combat other pathogens harmful to human health. This article is categorized under: Therapeutic Approaches and Drug Discovery > Nanomedicine for Infectious Disease.

One-Pot Microwave-Assisted Synthesis of Carbon Dots and in vivo and in vitro Antimicrobial Photodynamic Applications.

Carbon-based photosensitizers are more attractive than the other ones based on their low cost, high stability, broadband of light absorption, tunable emission spectra, high quantum yield, water solubility, high resistance to metabolic degradation, and selective delivery. These properties allow multiple applications in the field of biology and medicine. The present study evaluated in vitro and in vivo the antimicrobial photodynamic effect of a one-pot microwave produced C-DOTS based on citric acid. The in vitro assays assessed the effectiveness of illuminated C-DOTS (C-DOTS + light) against Staphylococcus aureus suspension and biofilm. The concentrations of 6.9 and 13.8 mg/mL of C-DOTS and light doses of 20 and 40 J/cm2 were able to reduce significantly the microorganisms. Based on these parameters and results, the in vivo experiments were conducted in mice, evaluating this treatment on wounds contaminated with S. aureus. The viability test showed that C-DOTS-mediated photodynamic inactivation reduced 104 log of the bacteria present on the skin lesions. These results, altogether, showed that antibacterial photodynamic therapy using C-DOTS is a promising and viable treatment for Gram-positive bacteria-infected wounds.

Microencapsulation of garlic oil by ß­cyclodextrin as a thermal protection method for antibacterial action.

The present study investigated the encapsulation process of garlic oil in ß­cyclodextrin (ßCD) and the antibacterial properties of the ßCD-garlic oil complex against Escherichia coli and Staphylococcus aureus. The encapsulation method increased the thermal stability of garlic oil with a formation constant (Kc) value of 253.78 L·mol-1 for of the ßCD-garlic oil complex, which confirmed the success of the encapsulation process. Scanning electron microscopy analysis showed that the dimensions of the structures formed by the inclusion complex of ßCD-garlic oil had values ranging from 5 to 10 µm. After thermal treatment of the ßCD-garlic oil complex at 60 °C for 1 h, the complex retained significant antibacterial action. The minimum inhibitory concentration (MIC) and agar diffusion results showed that the microcapsules containing 81.73 mmol·L-1 garlic oil exhibited excellent antibacterial action.

3D-Hydrogel Based Polymeric Nanoreactors for Silver Nano-Antimicrobial Composites Generation.

This study underscores the development of Ag hydrogel nanocomposites, as smart substrates for antibacterial uses, via innovative in situ reactive and reduction pathways. To this end, two different synthetic strategies were used. Firstly thiol-acrylate (PSA) based hydrogels were attained via thiol-ene and radical polymerization of polyethylene glycol (PEG) and polycaprolactone (PCL). As a second approach, polyurethane (PU) based hydrogels were achieved by condensation polymerization from diisocyanates and PCL and PEG diols. In fact, these syntheses rendered active three-dimensional (3D) hydrogel matrices which were used as nanoreactors for in situ reduction of AgNO3 to silver nanoparticles. A redox chemistry of stannous catalyst in PU hydrogel yielded spherical AgNPs formation, even at 4 °C in the absence of external reductant; and an appropriate thiol-functionalized polymeric network promoted spherical AgNPs well dispersed through PSA hydrogel network, after heating up the swollen hydrogel at 103 °C in the presence of citrate-reductant. Optical and swelling behaviors of both series of hydrogel nanocomposites were investigated as key factors involved in their antimicrobial efficacy over time. Lastly, in vitro antibacterial activity of Ag loaded hydrogels exposed to Pseudomona aeruginosa and Escherichia coli strains indicated a noticeable sustained inhibitory effect, especially for Ag-PU hydrogel nanocomposites with bacterial inhibition growth capabilities up to 120 h cultivation.

Microencapsulation of eugenol molecules by ß-cyclodextrine as a thermal protection method of antibacterial action.

Eugenol is natural oil that has excellent antibacterial properties but cannot be used to fabricate many products that require thermal processing. One possible alternative to the use of the eugenol molecules in high-temperature processes is the encapsulation of these molecules in a structure that is not toxic and is resistant to thermal treatment. This work investigated the encapsulation process of eugenol molecules in ß-cyclodextrine and the antibacterial properties of eugenol-ß-cyclodextrine (the eugenol-ßCD complex) against Escherichia coli and Staphylococcus aureus. The FTIR, DSC, MEV and TGA results show that the encapsulation method is an excellent alternative to increase the thermal stability of eugenol molecules. A value of 241.32L.mol-1 was determined for the formation constant (Kc) of the eugenol-ßCD complex, which confirmed the success of the encapsulation process. The MEV analysis shows the formation of approximately 12µm microcapsules. After the thermal treatment of the eugenol-ßCD complex at a temperature of 80°C for 2h, the complex retained significant antibacterial action, which confirms the thermal protection of the eugenol molecules. The minimum inhibitory concentration (MIC) and agar diffusion results show that the microcapsules containing 17.08mmol.L-1 of eugenol exhibited excellent antibacterial action against Escherichia coli and Staphylococcus aureus after thermal treatment.

Nanopartículas para materiales antibacterianos y aplicaciones del dióxido de titanio / Nanoparticles for antibacterial materials and titanium dioxide applications

La aparición constante de microorganismos multiresistentes (bacterias, virus, hongos), ha elevado el esfuerzo por la búsqueda de materiales antibacterianos, que sean efectivos para su aplicación en áreas tan diversas como la industria textil, alimentación animal, el tratamiento de aguas, industria médica, farmacéutica y cosmética. Es bien conocido que agentes antibacterianos inorgánicos tales como las nanopartículas de plata, de cobre, de óxido de zinc y de óxido de cobre, han atraído una atención especial a lo largo del tiempo, debido a su estabilidad y a que no presentan problemas de bioseguridad. Aun así, recién las nanopartículas de dióxido de titanio han venido ganando atención para aplicaciones biomédicas, dado que estas partículas se vuelven antibacteriales mediante un proceso de fotoactivación y presentan absorción de ciertas longitudes de onda que dependen de su fase inorgánica (anatasa, rutilo o brookita). No obstante, la actividad fotocatalítica del dióxido de titanio oscila en la región UV (ƛ>387nm), y ello ha representado el mayor esfuerzo en investigación, en búsqueda de conseguir que el dióxido de titanio tenga función de autodesinfección en la región de luz visible, aumentándose así sus aplicaciones en la industria biomédica. En este artículo se realizó una revisión crítica de la literatura disponible, sobre el uso de nanopartículas para materiales antibacterianos y aplicaciones del dióxido de titanio, haciéndose énfasis en el mecanismo de acción de estas partículas con sistemas biológicos y posibles modificaciones para mejorar su actividad fotocatalítica mediante la interacción con luz visible.

The constant occurrence of multiresistant microorganisms (bacteria, viruses, fungi) has increased the search for antibacterial materials that may be effective to be applied in various areas such as textile industry, animal feeding, water treatment, medical, drug and cosmetic industry. It is well known that inorganic antibacterial agents as silver, copper, zinc oxide and copper oxide nanoparticles have attired special attention in the course of time due to their stability and the absence of biosafety problems. Despite this, just recently, have the titanium dioxide nanoparticles been gaining more attention for biomedical application, since these particles become antibacterial agents through a process of photo-activation and present absorption of certain wavelengths depending on their inorganic phase (anatase, rutile or brookite). Nevertheless, the photocatalytic activity of the titanium dioxide ranges in the UV zone ((?>387nm), and this has required greater efforts in terms of research, to make the titanium dioxide have the auto-disinfection function in the visible light zone, so as to increase the number of uses in the biomedical industry. This article was aimed at making a critical literature review on the use of nanoparticles for antibacterial materials, and the applications of titanium dioxide, thus making emphasis on the mechanism of action of these particles with the biological systems and the possible changes with a view to improving its photocatalytic activity by means of the interaction with the visible light.