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Photoactive antimicrobial coating based on a PEDOT-fullerene C60 polymeric dyad

Eugenia Reynosoa, Andrés M. Durantinia, Claudia A. Solisb, Lorena P. Macorb, Luis A. Oterob, Miguel A. Gervaldob, Edgardo N. Durantinia and Daniel A. Heredia*a
aIDAS-CONICET, Departamento de Química, Facultad de Ciencias Exactas Físico-Químicas y Naturales, Universidad Nacional de Río Cuarto, Agencia Postal Nro. 3, X5804BYA Río Cuarto, Córdoba, Argentina. E-mail: dheredia@exa.unrc.edu.ar; Fax: +54 358 76233; Tel: +54 358 4676538
bIITEMA-CONICET, Departamento de Química, Facultad de Ciencias Exactas Físico-Químicas y Naturales, Universidad Nacional de Río Cuarto, Agencia Postal Nro. 3, X5804BYA Río Cuarto, Córdoba, Argentina

Received 1st May 2021 , Accepted 17th June 2021

First published on 5th July 2021


Abstract

A photostable and photodynamic antimicrobial surface was successfully obtained and applied to photoinactivate microorganisms. This approach was based on the synthesis of a fullerene C60 derivative (EDOT-C60) where fullerene C60 is covalently linked to 3,4-ethylenedioxythiophene (EDOT) through a 1,3-dipolar cycloaddition reaction. This dual-functional monomer bears an EDOT center connected via an alkyl chain to a fullerene C60 moiety. In this structure, EDOT acts as an electropolymerizable unit that allows the film formation over conducting substrates, while fullerene C60 performs the photodynamic antimicrobial activity. Electrochemical polymerization of EDOT was used to obtain stable and photodynamic polymeric films (PEDOT-C60) in a controllable procedure. Cyclic voltammetry and UV-visible spectroscopy studies showed that the fullerene C60 units were not altered during the electropolymerization process, obtaining surfaces with high fullerene content. Photobleaching measurements demonstrated that the electropolymerized films were highly photostable. Moreover, photodynamic properties of PEDOT-C60 were compared with fullerene C60 and showed that electrodeposited films were able to generate reactive oxygen species (ROS) through the two photomechanisms, producing singlet molecular oxygen (type II) and superoxide radical anion (type I). All studies demonstrated that fullerene C60 moieties covalently attached to the polymeric matrix mainly conserve the photodynamic characteristics. Hence, photodynamic action sensitized by PEDOT-C60 was assessed in vitro against Staphylococcus aureus. The photosensitized inactivation by the electropolymerized films on bacteria suspensions produced >99.9% reduction in S. aureus survival. Fluorescence microscopy experiments with S. aureus adhered to the PEDOT-C60 surface showed a complete microbe annihilation. Also, the eradication of biofilms formed on PEDOT-C60 surfaces resulted in a photokilling >99.9% after visible light irradiation. Our results demonstrated that these antimicrobial photodynamic polymeric films are a promising and versatile platform to photoinactivate microorganisms and to obtain photostable self-sterilizing surfaces.


1. Introduction

Hospital-acquired infections, also known as nosocomial infections, constitute a significant health problem nowadays.1 Not only do they prolong the hospitalization period but also remarkably increase morbidity and mortality in hospitalized patients. Also, the prolonged stay usually requires new antimicrobial treatments and supplementary studies, which results in a substantial increase in healthcare costs.2 Consequently, nosocomial infections need to be controlled within healthcare environments.3 Infections can be produced by an extensive variety of pathogens;4 however, Staphylococcus aureus prevails in hospital-associated facilities. This pathogen can colonize and form biofilms on surfaces,5,6 spreading resistant strains among healthcare personnel, medical instruments, and patients.2,5–8 Therefore, the development of antimicrobial coatings and self-sterilizing surfaces is crucial to diminish the frequency of infections, not only in hospital but also in common use facilities.

The development of self-sterilizing surfaces has become a trending topic in the last years.9–11 Aiming to reduce bacterial resistance spread, photodynamic inactivation (PDI) of microorganisms has been purposed as a promising and innovative approach to treat bacterial infections.12 This methodology is based on a light-activated photosensitizer (PS) combined with molecular oxygen, O2(3Σg). The PS excited state, generated by photon absorption, can transfer energy to O2(3Σg), generating singlet molecular oxygen (O2(1Δg), type II mechanism), or react directly with biological substrates producing radicals and, finally, other reactive oxygen species (ROS, type I mechanism).13 These cytotoxic ROS damage multiple macromolecules and organelles of the cellular system producing irreversible changes, overcoming any defense mechanism activated by the host and leading to the cell death. This therapeutic technique provides a powerful platform for the treatment of broad-spectrum pathogens, even antibiotic resistant bacteria.14,15 Furthermore, this antimicrobial strategy has also shown superior outcomes to eradicate biofilms in comparison with other conventional treatments.16–18

A wide variety of PSs attached to different surfaces have been employed for the inactivation of pathogenic microorganisms.19–24 Thereby, surfaces with immobilized PSs can be used to conserve sterilized and sanitized surfaces in healthcare environments. Surfaces are recognized as being the most important reservoirs of bacteria and potential areas for the development of biofilms in healthcare facilities.1 Thus, this antimicrobial therapy becomes as an encouraging strategy to limit the risk of cross-contamination and nosocomial infections.12,25

Our group has recently reported the electrochemical formation of antimicrobial polymeric films bearing porphyrins as photoactive units and carbazol moieties as polymerization centers.26,27 In vitro studies showed that these polymeric films were effective to photoinactivate microbes in planktonic media, and to eradicate biofilms. In addition, Comuzzi et al. reported the photokilling ability of polymeric materials obtained by imprinting a pentaphyrin derivative into electrodeposited dipyrromethane films.28 Although all these materials showed promising photokilling activity, the photostability of tetrapyrrolic macrocycle can be a disadvantage and a determining factor for practical applications. Taking this condition into account, fullerene C60 is a more photostable PS than porphyrinoid derivatives under visible light irradiation, since it undergoes relatively less photobleaching than tetrapyrrolic macrocycles.29–32 Blacha-Grzechnik et al. have recently demonstrated that films of polythiophene-C60 dyads, electrodeposited on indium–tin oxide (ITO) electrode, have the capability to produce O2(1Δg) under light irradiation.33 Nyga et al. have proved that selenophene-fullerene polymeric dyads, electrochemically deposited, were also able to generate O2(1Δg) after visible illumination.34

Within the group of electroactive molecules, 3,4-ethylenedioxythiophene (EDOT) is a versatile matrix to generate electrodeposited surfaces. EDOT can be readily electropolymerized and is a promising group for practical applications since several studies of electrodeposited films of poly(3,4-ethylenedioxythiophene) (PEDOT) composite materials have shown excellent stability and antifouling/antimicrobial properties.35–38 Thus, the derivatization of EDOT with a PS is an attractive idea to generate novel antimicrobial surfaces.

In this work we constructed a dual functional material, which combines the photodynamic and photostable properties of fullerene C60 with the well-known polymerizable EDOT group. Our approach was based on the design and synthesis of an electroactive and photodynamic monomer (EDOT-C60), which contains an EDOT center covalently linked to a fullerene C60 moiety (Scheme 1). The electropolymerization process of EDOT-C60 led to the synthesis and deposition of polymeric films (PEDOT-C60), which were characterized by cyclic voltammetry and scanning electron microscopy (SEM). Their spectroscopic features and photodynamic properties were also studied and compared with fullerene C60. Photodynamic inactivation mediated by PEDOT-C60 films, were tested in vitro against S. aureus, a major colonizer of hospital environments. The antimicrobial efficiency of the photodynamic material was assessed inactivating pathogens in: planktonic suspension, adhered cells to photosensitizing surface and biofilms. Our outcomes demonstrate the development of a new photostable and photodynamic antimicrobial surface. These findings pave the way for the fabrication of new, easy to produce, fullerene-based antimicrobial surfaces.

2. Experimental sections

2.1 Synthesis

2.1.1 EDOT-Br. 4-(Dimethylamino)pyridine (DMAP; 54 mg, 0.46 mmol) and N-(3-dimethylaminopropyl)-N′-ethylcarbodiimide hydrochloride (EDC; 278 mg, 1.45 mmol) were successively added to a stirred solution of hydroxymethyl EDOT (EDOT-OH; 200 mg, 1.16 mmol) and 6-bromohexanoic acid (226 mg, 1.16) in anhydrous dichloromethane (DCM; 4 mL). The mixture was stirred at room temperature for 24 h under argon atmosphere. Then, DCM (20 mL) was added and the reaction mixture was washed with water (2 × 20 mL). The organic phase was dried with anhydrous MgSO4 and the solvent was removed under reduced pressure. The oily residue was purified by flash column chromatography (silica gel; DCM/cyclohexane, 1[thin space (1/6-em)]:[thin space (1/6-em)]1 → 1[thin space (1/6-em)]:[thin space (1/6-em)]0) to afford EDOT-Br (285 mg, 70%) as a yellow pale oil. 1H NMR (300 MHz, CDCl3) δ 6.36 (d, J = 3.6 Hz, 1H), 6.34 (d, J = 3.6 Hz, 1H), 4.42–4.34 (m, 1H), 4.33–4.30 (m, 2H), 4.25–4.01 (m, 2H), 3.40 (t, J = 6.7 Hz, 2H), 2.38 (t, J = 7.4 Hz, 2H), 1.88 (q, J = 7.1 Hz, 2H), 1.67 (q, J = 7.4 Hz, 2H), 1.53–1.46 (m, 2H). 13C NMR (75 MHz, CDCl3) δ 172.9, 141.2, 141.0, 100.0, 99.9, 71.4, 65.6, 62.2, 33.7, 33.4, 32.3, 27.6, 23.9. IR (film, [small nu, Greek, tilde]): 762, 1024, 1119, 1184, 1252, 1377, 1427, 1454, 1485, 1732, 2868, and 2932 cm−1. MS m/z 348 (M+) (348.0031 calculated for C13H17BrO4S).
2.1.2 EDOT-N3. EDOT-Br (170 mg, 0.49 mmol) and NaN3 (475 mg, 7.30 mmol) were dissolved in N,N-dimethylformamide (DMF; 7 mL) and stirred at 90 °C overnight under argon atmosphere. Then, DCM (25 mL) and water (25 mL) were added. The organic layer was extracted and washed with water (25 mL × 4). The organic solvent was removed under reduced pressure to afford EDOT-N3 (152 mg, 99%), as a yellow pale oil. 1H NMR (300 MHz, CDCl3) δ 6.36 (d, J = 3.5 Hz, 1H), 6.34 (d, J = 3.5 Hz, 1H), 4.42–4.33 (m, 1H), 4.33–4.29 (m, 2H), 4.25–4.20 (m, 2H), 3.27 (t, J = 6.8 Hz, 2H), 2.38 (t, J = 7.4 Hz, 2H), 1.76–1.55 (m, 4H), 1.49–1.38 (m, 2H). 13C NMR (75 MHz, CDCl3) δ 172.9, 141.2, 141.0, 100.0, 99.9, 71.4, 65.6, 62.2, 51.2, 33.7, 28.5, 26.2, 24.3. IR (film, [small nu, Greek, tilde]): 1026, 1094, 1185, 1487, 1738, 2097, 2868 and 2934 cm−1. MS m/z 311 (M+) (311.0940 calculated for C13H17N3O4S).
2.1.3 EDOT-C60. Fullerene C60 (463 mg, 0.64 mmol) and EDOT-N3 (100 mg, 0.32 mmol) were dissolved in dry 1,2-dichlorobenzene (o-DCB, 25 mL). The solution was refluxed for 36 h under argon atmosphere. Then, the organic solvent was removed under reduced pressure and the black solid residue was chromatographed (silica gel; toluene/cyclohexane, 1[thin space (1/6-em)]:[thin space (1/6-em)]1 → 1[thin space (1/6-em)]:[thin space (1/6-em)]0) to give EDOT-C60 (97 mg, 30%) as a dark brown powder. 1H NMR (300 MHz, CDCl3) δ 6.38 (d, J = 3.6 Hz, 1H), 6.35 (d, J = 3.6 Hz, 1H), 4.44–4.37 (m, 1H), 4.36–4.33 (m, 1H), 4.29–4.02 (m, 2H), 3.81 (t, J = 7.1 Hz, 2H), 2.50 (t, J = 7.3 Hz, 2H), 2.12–1.97 (m, 2H), 1.92–1.68 (m, 4H). 13C NMR (75 MHz, CDCl3) δ 173.2, 147.8, 146.8, 145.0, 144.7, 144.6, 144.5, 144.3, 144.2, 143.8, 143.7, 143.4, 143.1, 142.9, 142.8, 142.7, 142.6, 141.4, 141.2, 141.1, 140.8, 139.2, 138.5, 138.1, 137.3, 137.2, 136.2, 135.8, 133.7, 100.1, 100.0, 71.5, 65.7, 62.3, 51.4, 34.0, 29.2, 26.8, 24.7. IR (KBr, [small nu, Greek, tilde]): 525, 571, 754, 1025, 1181, 1370, 1427, 1484, 1738, 2857 and 2931 cm−1. ESI-MS m/z 1005.1041 (M + H)+ (calculated for C73H18NO4S 1004.0957).

2.2 Polymer films electrodeposition

The generation of polymeric films was performed by electrochemical methods, using a conventional three electrode glass cell. ITO electrodes (7 × 50 × 0.9 mm, Delta Technologies, Stillwater, MN, sheet resistance 8–12 Ω sq−1) were used as working electrodes, while a platinum mesh and a silver wire were used as counter electrode and pseudo-reference electrode, respectively. Applied potential was adjusted versus Saturated Calomel Electrode (SCE) formal potential using ferrocene as internal standard. DCM solutions containing monomer (0.5 mM) and tetrabutylammonium hexafluorophosphate (TBAPF6, 0.1 M) as supporting electrolyte were used for the electrodeposition. The monomer was polymerized and deposited over ITO surface by cyclic voltammetry (CV), cycling the electrode in the potential range between −1.0 and 1.4 V at 50 mV s−1 (Fig. 1).

2.3 Spectroscopic studies

UV-visible absorption measurements of EDOT-C60 were performed in air-equilibrated DCM solution at room temperature, using a quartz cell (10 mm path length). Absorption spectra of PEDOT-C60 films deposited on ITO were acquired by placing the sample in the spectrometer cell holder. The background correction was obtained by taking an UV-visible spectrum of an ITO electrode without the film.

2.4 Generation of O2(1Δg)

The generation of O2(1Δg) sensitized by PEDOT-C60 was determined by photooxidation of 9,10-dimethylanthracene (DMA) in DMF. This method was carried out in a quartz cell at room temperature. PEDOT-C60 surfaces were dipped in a solution of DMA (40 μM) and irradiated with light in a wavelength range between 455 and 800 nm (30 mW cm−2).39 A solution containing fullerene C60 and DMA (40 μM) was also irradiated (455–800 nm) and used as reference. The photooxidation rates of DMA were evaluated by following the decrease in the intensity of the DMA absorption band at λmax = 379 nm. The observed rate constants kDMAobs were determined from the slope of the plot ln(A0/A) vs. time. The quantum yield of O2(1Δg) generation (ΦΔ) was calculated by direct comparison between the kDMAobs of PEDOT-C60 and the reference (fullerene C60, ΦΔ = 1).40

2.5 Detection of superoxide radical anion

The nitro blue tetrazolium (NBT) method was used to detect superoxide radical anion (O2˙) formation in DMF.41 PEDOT-C60 film was dipped in a solution containing 0.2 mM NBT and 0.5 mM reduced nicotinamide adenine dinucleotide (NADH) in 2 mL of DMF/water (9/1), and it was irradiated with visible light (90 mW cm−2) at different times under aerobic condition.42 The NBT reduction was followed by the increase of the absorbance at λ = 560 nm (diformazan formation). A fullerene C60 solution was also used for comparison. Control experiments were performed in absence of NBT, NAHD or PEDOT-C60.

2.6 Photooxidation of L-tryptophan

PEDOT-C60 film was dipped in a solution of 25 μM L-tryptophan (Trp) in DMF (2 mL) and irradiated with visible light (90 mW cm−2) under aerobic conditions. A fullerene C60 solution was used for comparison. The kinetics of Trp photooxidation were monitored by following the decrease of the fluorescence intensity (I) at λ = 343 nm. Trp was excited at λexc = 290 nm. The observed rate constants (kTrpobs) were obtained as previously reported.43

2.7 Photostability measurements

Photobleaching studies of PEDOT-C60 were carried out in phosphate-buffered saline (PBS).26 PEDOT-C60 film was placed in a quartz cuvette containing PBS; then it was irradiated with visible light (90 mW cm−2) for 2 h under aerobic conditions. Absorption spectra were recorded at regular time intervals. The observed rate constant of photobleaching (kPobs) was determined as previously reported.26 The photobleaching lifetime (τP1/2) was determined according to: τP1/2 = ln(1/2)/kPobs.

2.8 Bacterial strains and preparation of cultures

The microorganism used was the strain of S. aureus ATCC 25923, which was previously characterized and identified.44 Microbial cells were grown aerobically in sterile condition overnight at 37 °C in 2 mL tryptic soy broth (TSB). An aliquot (60 μL) of the bacterial culture was aseptically transferred to 4 mL of fresh TSB and incubated at 37 °C to exponential phase of growth (absorbance 0.5 at 660 nm).

For the antibacterial drop-test, S. aureus in exponential phase of growth in TSB were centrifuged (3000 rpm for 15 min), and re-suspended in equal amount of PBS (pH = 7.4). Then, it was diluted to obtain ∼104 colony forming unit (CFU) per milliliter. The additives sodium azide and mannitol were added from a stock solution in water (2 M and 1 M, respectively). Microorganism was incubated with sodium azide (50 mM) and mannitol (50 mM) for 30 min in dark at 37 °C before the photoinactivation experiment.

For the S. aureus biofilm formation on PEDOT-C60, 100 μL of the TSB culture was transferred to the 24-well microtiter plates containing 1 mL of PBS solution and 0.9 mL of TSB. PEDOT-C60 fragment (1 × 1 cm) was placed in each well and incubated for 24 h at 37 °C under continuous stirring. Then, the surface containing the biofilm were aseptically washed with PBS (2 mL × 2) in order to remove non-adherent cells. The back of the electrode (surface of glass without PEDOT-C60) was cleaned using a cotton swab with 70% v/v ethanol.

2.9 PDI experiments: planktonic cells and mechanism studies

The PDI was evaluated on S. aureus growing as planktonic cells. A drop (200 μL) of S. aureus suspension in PBS (∼104 CFU mL−1) in the absence and in the presence of additives (sodium azide and mannitol) was deposited on the surface of the PEDOT-C60 (fragment of 1 × 1 cm) into a sterilized Petri dish. The PDI treatments in planktonic suspension were carried out with visible light irradiation (90 mW cm−2). PEDOT-C60 film with the drop was irradiated for 30 and 60 min. Then, viability of S. aureus was evaluated by serial dilution and plating on tryptic soy agar (TSA). Colonies formed were counted after 18 h of incubation at 37 °C in the dark.

2.10 PDI experiments: assembled biofilms

For the S. aureus biofilm inactivation, each PEDOT-C60 fragment containing the bacterial biofilm (24 h incubation) was washed with PBS (2 mL × 2) in order to remove non-adherent cells. The S. aureus biofilm (∼108 CFU mL−1 cm−2) on PEDOT-C60 was irradiated with visible light under the same conditions described above. After PDI treatment, the surfaces were transferred to Pyrex brand culture tubes (13 × 100 mm) containing PBS (2 mL), and the biofilm was disrupted mechanically to take off the adhered bacteria. Cell suspensions were serially diluted 10-fold in PBS. From each dilution, 20 μL aliquots were streaked horizontally on TSA plates in sextuplicate.45 Viable microbial cells were monitored and the number of CFU was determined after ∼24 h incubation at 37 °C in the dark.

2.11 PDI of bacteria attached to the surface using fluorescence microscopy

Bacterial inactivation at the single cell level was performed using the methodology described by us and others but with some modifications.46 Two types of chambers capable of containing up to 100 μL of solution were ensembled. One of the chambers had a plastic cylinder glue on top of a previously coated PEDOT-C60 surface, while in the other (used as the control), the cylinder was glued on an ITO-coated surface. Bacteria were incubated in the homemade chambers for 20 min at 37 °C. After this period, the chamber was washed with successive cycles of PBS buffer, remaining only bacteria that were attached to the surface. Then, 95 μL of the buffer was added followed by addition of propidium iodide (PI) (5 μL) and incubated for 20 min. The final concentration of PI in the solution was 1 μM.

Fluorescence emission from the PI was monitored using an inverted fluorescence microscope, exciting with green light and employing a band pass filter (515/35). The power measured out of the objective was 0.9 mW cm−2. Fluorescence from the PI was filtered using an emission band pass filter (645/75). The inactivation experiments started with irradiation of the sample with visible light (3.1 mW cm−2) and the energy dose for all the experiments was 5.6 J cm−2.

A Carl Zeiss CP ACHROMAT 100× objective was used in all experiments. Fluorescence was collected through the same objective and was capture with a CMOS camera. Phase contrast images were also acquired for each experiment to colocalize cells in the imaging region.

2.12 Scanning electron microscopy of S. aureus biofilm on PEDOT-C60

S. aureus biofilm on PEDOT-C60 samples were prepared as previously reported.47,48 The samples were then covered with gold and examined with a scanning electron microscope. SEM images were obtained with a field emission scanning electron microscope FE-SEM, Sigma Zeiss (LAMARX facilities).

3. Results and discussion

3.1 Synthesis of EDOT-C60

The electroactive monomer EDOT-C60 was synthetized following the synthetic sequence shown in Scheme 1. First, commercially available hydroxymethyl-EDOT was esterified with 6-bromohexanoic acid in presence of EDC and DMAP in DCM to provide EDOT-Br in 70% yield. Instead of the commonly used DCC, EDC was used since the water-soluble EDC byproduct is easily removed during the aqueous work-up. EDOT-Br was then submitted to a nucleophilic substitution with sodium azide in DMF, cleanly furnishing the azide EDOT-N3 in essentially quantitative yield. Finally, a dipolar [1,3]-cycloaddition between EDOT-N3 and fullerene C60 was carried out by refluxing in anhydrous o-DCB. Under this condition, the desired cycloadduct EDOT-C60 was obtained in 30% yield. Thus, the synthetic sequence gave rise to EDOT-C60 in 21% overall yield after three straightforward and scalable steps.
image file: d1ra03417k-s1.tif
Scheme 1 Synthetic pathway toward EDOT-C60.

The molecular structures of EDOT-C60 and its intermediaries were confirmed and determined by Fourier transform infrared (FT-IR) spectroscopy and nuclear magnetic resonance (NMR) (Fig. S1–S12). FT-IR spectroscopy was used to quickly obtain diagnostic information about the synthetic transformations. The disappearance of the OH stretch from the EDOT-OH and the appearance of the carbonyl stretching band at 1740 cm−1 were distinctive signals for the first chemical transformation. In the second reaction step, the unique azide band at 2097 cm−1 was clearly visible in the IR spectrum.49 Besides, the success of the cycloaddition reaction was noticed by the disappearance of the azide absorption and the presence of the characteristic band of the organofullerene system at 525 cm−1.50,51

The 1H NMR spectra of the three EDOT derivatives exhibited akin features due to their structural similarity. The 1H NMR spectrum of EDOT-C60 displayed thiophene protons at δ = 6.38 and 6.35 ppm (J = 3.7 Hz) as a consequence of the asymmetric substitution of the EDOT moiety. Additionally, the methylene and methine protons of the dioxin ring gave rise to complex multiples between 4.0 and 4.5 ppm. Furthermore, the resonances of the methylenes of the alkyl side chain were observed between 1.70 and 3.90 ppm, whilst the incorporation of fullerene C60 was evidenced by deshielded proton signals, generated by the electron-withdrawing properties of fullerene C60.

In relation to the 13C NMR spectrum, EDOT-C60 combined the characteristic resonances of the EDOT residue and the alkyl side chain, together with the diagnostic resonances corresponding to the fullerene C60 moiety. It is well-known that the alkyl-azide cycloaddition to fullerene C60 can afford two aza-bridged regioisomers (Fig. S13): a major product corresponding to the [5,6]-open dihydrofullerene and a minor one, corresponding to the [6,6]-closed structure.52,53 Interestingly, however, the [5,6]-open structure was selectively formed in EDOT-C60. This was determined from the carbon resonances corresponding to the fullerene C60 moiety, which were found in the range of 130–150 ppm, a spectral region attributable to sp2-type carbons.54 Further, the absence of signals corresponding to sp3 hybridized carbon atoms within the C60 framework (δ = 70–90 ppm) discarded the formation of a closed [6,6]-type structure.

3.2 Electrochemical formation of antimicrobial surface

Antimicrobial surfaces were generated by electrochemical polymerization and film deposition. This suitable and versatile methodology allows the polymer synthesis and film formation in one step at room temperature, avoiding solubility and/or stability requirements, that are necessary for polymer film formation by spin coating or vapor deposition methodologies.26,55,56 In order to explore the adequate conditions for electrochemical polymerization and film formation, CV analysis was conducted. Firstly, the redox behavior of EDOT-C60 monomer (0.5 mM) was investigated in an electrolyte solution containing TBAPF6 (0.1 M)/DCM over ITO electrode (Fig. 1A). The first cathodic scan of the monomer EDOT-C60 shows one reversible peak at −0.64 V. This peak was assigned to the first reduction of C60 moiety (Fig. 1A, light blue line).57 On the other hand, when a positive potential was applied, an irreversible oxidation process was detected at around 1.3 V, which can be ascribed to the formation of EDOT radical cations.57 These results are in agreement with the structural properties of EDOT-C60 monomer and prove that the main electronic characteristics of both moieties were retained in this new molecule. Furthermore, EDOT radical cations can react to form a PEDOT polymer.58 In fact, continuous cycling between −1.0 and 1.4 V produces increments in the oxidation–reduction currents after each new cycle, demonstrating the formation of an electrochemical active polymer on the electrode surface.
image file: d1ra03417k-f1.tif
Fig. 1 (A) Repetitive cyclic voltammograms of a 0.5 mM solution of EDOT-C60 in TBAPF6 (0.1 M)/DCM. Light blue line denotes the first cyclic voltammogram. (B) Cyclic voltammogram of a PEDOT-C60 film electro-deposited on ITO electrode in TBAPF6 (0.1 M)/DCM. Scan rate: 50 mV s−1.

When the polymeric films onto electrodes are put into a DCM solution containing only supporting electrolyte, the redox response presents the oxidation/reduction peak currents corresponding to PEDOT and fullerene C60, respectively (Fig. 1B). A widening of the voltammetric peaks in the cathodic response is observed. This is common for organic polymeric films, due to the interaction between the redox centers in the solid state, changes in the solvation and charges diffusion phenomena.59 Moreover, when the number of cycles in the electrochemical deposition were modified, films with different absorption were produced (Fig. S14).

The electrodeposited films were stable, with excellent adhesion properties to the electrode. The homogeneous distribution of the film on the surface was observed by optical microscopy and the obtained images are shown in Fig. S15. Further, the surface morphology of the films was studied by SEM. As is shown in Fig. 2A, the SEM imagines of PEDOT-C60 demonstrated a total covering of the ITO electrode with the absence of pinholes or cracks, showing a smooth and homogeneous coating. At a higher magnification (Fig. 2B), a uniform and granulated surface formed by a compact and fused agglomeration was observed.


image file: d1ra03417k-f2.tif
Fig. 2 SEM imagines of PEDOT-C60 polymer film at different magnifications: (a) 23[thin space (1/6-em)]000×, and (b) 57[thin space (1/6-em)]000×.

The synthetic design of the C60-containing monomer allowed the direct growth of a PEDOT backbone holding fullerene C60 pendant groups. This led to the formation of a polymeric film with a high fullerene content, corresponding to one fullerene C60 unit per polymer repeat unit.

3.3 Spectroscopic characterization

Spectroscopic properties of the monomer EDOT-C60 and the electrodeposited polymer PEDOT-C60 were studied in solution and thin solid films, respectively. Fig. 3 shows the absorption spectrum of EDOT-C60 in DCM solution as well as the spectrum of PEDOT-C60 deposited on ITO. Both spectra exhibited the typical absorption of fullerene derivatives, characterized by a strong absorption in the UV region and weaker absorptions in the visible region, with a tail extending to the near-IR region.
image file: d1ra03417k-f3.tif
Fig. 3 (A) Electronic absorption spectrum of EDOT-C60 monomer in DCM at room temperature. (B) Absorption spectrum of PEDOT-C60 film on ITO. The inset shows a photo of the polymer PEDOT-C60 deposited on ITO.

As it can be observed in Fig. 3A, EDOT-C60 shows the characteristic electronic transitions of azafulleroids with two main absorption bands at 260 and 330 nm, and a small band at 445 nm.59,60 Furthermore, the electronic transition between 420–440 nm, distinctive of [6,6] closed ring configuration,60 is not present in EDOT-C60 spectrum. This spectroscopic evidence also confirms the formation of an open [5,6]-aza-bridged adduct.

Fig. 3B shows the absorption spectrum of electrodeposited PEDOT-C60 film on ITO electrode. The inset in Fig. 3B allows to appreciate how the electropolymerization process of the monomer lead to the formation of a yellow-brownish coating. The PEDOT-C60 polymeric surface combines the spectroscopic features of the fullerene-based chromophore and the conjugated polymeric chain of PEDOT.59,61 The electronics transitions corresponding to the fullerene absorption are broadened and bathochromically shifted compared to the monomer bands in solution. This is a consequence of the extensively aggregated system formed in the polymeric matrix. The broad absorption band center at 900 nm could be attributed to the π–π* transition of the extended conjugated polymer chain of PEDOT and to the partial oxidation of the film.61,62 Besides, the spectrum of PEDOT-C60 confirms not only that the electropolymerization of the EDOT-C60 generates a polymeric surface containing fullerene C60, but also that the spectroscopic properties of the fullerene-based chromophore are retained, evidencing that the chromophore structure is not altered during the electrodeposition process.

3.4 Polymeric surface photostability

One of the main requisites for the development of photoactive antimicrobial coatings is the photostability of the PS attached to the surface. This plays a predominant role in the reuse of the surface, which is essential for practical applications. Photodegradation processes, caused by exposure to light, affect the antimicrobial efficacy. Consequently, photobleaching studies of the PEDOT-C60 polymeric coatings were carried out using visible light irradiation.

The film photostability was investigated in PBS by monitoring the decrease of the absorption at 369 nm. PEDOT-C60 surfaces were irradiated for 2 h and the absorption spectra were acquired at regular intervals of time. Fig. S16 shows the insignificant spectroscopic variations exhibited for PEDOT-C60, with a negligible loss of absorbance after visible light exposure. Furthermore, discoloration of the surface was not observed. Thus, the polymeric surfaces can be exposed to visible irradiation retaining their spectroscopic characteristics.

As it can be observed in Fig. 4, the slight photodegradation process followed a first-order kinetic with the irradiation time. The value of the kPobs, obtained from the slope of the previous plot, was 6.53 × 10−4 min−1. This value was used to calculate the photodegradation lifetime, obtaining a τP1/2 of 17.7 h in PBS. Although it is not possible to compare photobleaching results obtained by other groups due to the different experimental conditions, our outcomes showed that PEDOT-C60 exhibited higher photostability (almost two times more) than our previously reported porphyrin-based antimicrobial surface under similar conditions.26 This demonstrates that PEDOT-C60 films exhibit a high photostability, which gives them long lifetime with good performance for practical applications.


image file: d1ra03417k-f4.tif
Fig. 4 First-order plot for the photodegradation of PEDOT-C60 surface dipped in PBS and irradiated with visible light.

PEDOT-C60 photostability can be explained considering that fullerene moieties are highly resistant to photobleaching.63,64 Most of the conventional PS are entirely decomposed, losing their photodynamic action at relatively low energy dose; while fullerene conserves its photoactivity after very high fluences.63 In addition, fullerene C60 moieties in PEDOT-C60 are embedded in the polymeric matrix, which could result in an opportune steric hindrance against the ROS that are responsible for the photooxidation reactions.

3.5 Photosensitized generation of O2(1Δg)

After a detailed characterization of the PEDOT-C60 polymeric film, its potential as an antimicrobial surface was first studied by assessing its ability to produce O2(1Δg) under light irradiation. To that end, decomposition of DMA photoinduced by PEDOT-C60 was used to monitor the O2(1Δg) generation.26,65 In this method, DMA quenches O2(1Δg) by a rapid chemical reaction, producing the endoperoxide derivative.66 The photodecomposition reaction was monitored by UV-visible spectroscopy following the decrease of the DMA absorption band at 379 nm.26

In order to evaluate the O2(1Δg) production photosensitized by PEDOT-C60, the surface was dipped in an air-equilibrated solution of DMA in DMF and it was then irradiated with light (455–800 nm). Absorption spectra acquired at different irradiation times showed the gradual decrease of the absorption bands of DMA (Fig. S17), indicating that O2(1Δg) was produced by the photosensitizing action of PEDOT-C60 polymeric films. It is worth to mention that PEDOT-C60 films were not dissolved during the kinetic study, which was evidenced by the absence of their absorption bands in the acquired spectra.

The consumption of DMA was also compared with a solution of fullerene C60 in DMF. The spectroscopy decay of DMA produced by the reference at different irradiation times is shown in Fig. S17. As is shown in Fig. 5, DMA photooxidation exhibited a pseudo first-order kinetic for both systems but with different rates of O2(1Δg) production. The values of kDMAobs were determined from the slopes of these plots and are gathered in Table 1.


image file: d1ra03417k-f5.tif
Fig. 5 First-order kinetic data fitting for the photooxidation of DMA in DMF sensitized by PEDOT-C60 (image file: d1ra03417k-u1.tif) and fullerene C60 (●). λirr = 455–800 nm. Values represent mean ± standard deviation (error bars) of three consecutive experiments.
Table 1 Photodynamic properties of PEDOT-C60 and the reference fullerene C60 in DMF
  kDMAobsa (s−1) ΦΔ kTrpobsa (s−1)
a Fitting error reported.b Value from ref. 40.
PEDOT-C60 (4.55 ± 0.02) × 10−5 0.16 ± 0.02 (8.78 ± 0.06) × 10−5
Fullerene C60 (2.87 ± 0.02) × 10−4 1b (1.12 ± 0.10) × 10−4


The quantum yield of O2(1Δg) production (ΦΔ) was calculated by comparing the kDMAobs value for the electrodeposited film with that for the reference (fullerene, ΦΔ = 1).40 Despite fullerene C60 has an efficient photodynamic activity with a high O2(1Δg) quantum yield production, the ΦΔ value for PEDOT-C60 was 0.16. This yield is appropriate since O2(1Δg) generation takes place on the surface of PEDOT-C60. Also, the production efficiency of O2(1Δg) of the film is lower since the aggregation processes in the solid state could be reducing the ΦΔ.32,67

The obtained ΦΔ value not only confirms that PEDOT-C60 is able to generate O2(1Δg), but also that it is more efficient compared to previous electrodeposited polymers.26,27,68 Furthermore, the O2(1Δg) production demonstrates that a photodynamic mechanism type II occurs when PEDOT-C60 is irradiated with light.

3.6 Generation of superoxide radical anion

The capability of PEDOT-C60 films to photosensitized ROS thorough a type I mechanism was studied by following the production of superoxide radical anion (O2˙). The NBT method was used to determine the generation of this ROS. NBT is a trapping reagent that is reduced by O2˙ to form diformazan. This photosensitized reduction is favored by the presence of reducing agents such as NADH and polar solvents.69,70 NADH-mediated O2˙ formation was monitored spectroscopically by following the increase of diformazan absorption band at λ = 560 nm (Fig. S18).

Fig. 6 shows the increase of diformazan absorption band as a function of the irradiation time when PEDOT-C60 and fullerene C60 were irradiated with visible light in air-equilibrated DMF. As it can be observed, the reduction of NBT was not observed for control experiments: absence of NADH or NBT, and PEDOT-C60 in dark. On the other hand, although both PEDOT-C60 and fullerene C60 showed higher absorption than NADH + NBT control, fullerene C60 exhibited a higher production of diformazan. Again, this can be explained because O2˙ is produced in the interface between the film and the solution.


image file: d1ra03417k-f6.tif
Fig. 6 O2˙ generation monitored by the NBT method following the increase in the absorption at 560 nm. Samples contain: PEDOT-C60, NBT and NADH (image file: d1ra03417k-u2.tif); fullerene C60 solution, NBT and NADH (▶); NBT and NADH (○); PEDOT-C60 and NTB (△); PEDOT-C60 and NADH (▽); PEDOT-C60, NBT and NADH, dark control (image file: d1ra03417k-u3.tif). [NBT] = 0.2 mM and [NADH] = 0.5 mM.

These results confirm that a type I mechanism takes place when the polymeric films are irradiated. Up to this point, O2(1Δg) and O2˙ are produced by PEDOT-C60 films after light irradiation. This is in concordance with the capability of the fullerene C60 to generate ROS through both type I and II pathways.27,30,43

3.7 Photooxidation of Trp

Photooxidation of Trp is a useful model to study the photodynamic properties, because it could be a target molecule of the photodynamic effect induced by PDI treatments. Trp is located as a residue on protein chains; therefore modifications in its chemical structure can produce significant alterations in the physicochemical properties of the proteins and subsequently lead to a cellular damage.71 Trp can be efficiently photooxidized by both type I and type II photomechanisms.71 It is one of the most susceptible amino acids to oxidation by radicals and O2(1Δg), with significant rates under physiological conditions.71

The photooxidation of Trp sensitized by PEDOT-C60 films and fullerene C60 was carried out in air-equilibrated DMF, following the decrease of the Trp emission band at 343 nm (see Fig. S19). As it can be observed in Fig. 7, the photodecomposition of Trp exhibited a pseudo-first order kinetic. The values of the kTrpobs for Trp degradation were obtained from the slope of these plots (Table 1). The two studied systems photodecomposed Trp at similar rates. The kTrpobs value for PEDOT-C60 was similar to that found for fullerene C60, with kTrpobs values of 8.78 × 10−5 s−1 and 1.12 × 10−4 s−1 for PEDOT-C60 and fullerene C60, respectively. This result discloses that Trp is a key target of the photodynamic action prompted by the electrodeposited films.


image file: d1ra03417k-f7.tif
Fig. 7 First-order plots for the oxidation of Trp (20 mM) photosensitized by the PEDOT-C60 surface (image file: d1ra03417k-u4.tif) and fullerene C60 (●) in DMF solution, λirr = 455–800 nm.

Comparing the kobs values for DMA and Trp, a high ration value of kfilmobs/kfullereneobs was obtained for the Trp decomposition (kfilmobs/kfullereneobs = 0.78) in comparation with the O2(1Δg) production observed in DMA photooxidation (kfilmobs/kfullereneobs = 0.16). Therefore, an electron transfer pathway could also be contributing to the Trp decomposition in DMF. PEDOT polymeric chain could absorb visible light, producing a photoinduced charge-separated state, as it was previously reported for a similar C60-containing electropolymer.59 Thus, fullerene C60 may be reduced to its radical anion (C60˙) by electron transfer from the PEDOT, and consequently, C60˙ could also transfer an electron to O2(3Σg) producing O2˙.72–74

3.8 Photoinactivation of S. aureus cell suspension and mechanism studies

The inactivating capability of this photoactive material was investigated in vitro by depositing a drop of a S. aureus suspensions on the PEDOT-C60 surface. This antibacterial drop-test can serve to determine the antimicrobial action of the film to inactivate S. aureus cells in contaminated water. In fact, it has already been used to evaluate the capacity of electrogenerated polymeric films to inactivate microorganisms.26,27 In this approach, 200 μL of PBS containing ∼104 cells was deposited on PEDOT-C60 and irradiated with visible light.

Fig. 8A shows the survival of bacterial cells after different irradiation times. Control experiments indicated that the viability of S. aureus was unaffected by keeping the cells on PEDOT-C60 surfaces in the dark for 60 min (Fig. 8A, treatment 1). In addition, after 60 min of irradiation, <1 log decrease was found for the ITO-coated glass (Fig. 8A, treatment 2). On the other hand, the viability of S. aureus cells deposited on PEDOT-C60 films was dependent on the light exposure time. A slight inactivation (∼1 log) was detected after 15 and 30 min of irradiation (Fig. 8A, treatment 3 and 4). While a ∼3.1 log decrease of S. aureus survival was produced after 60 min of irradiation (Fig. 8A, treatment 5). This result represents a value higher than 99,9% of cellular inactivation. Therefore, from all these data, it is inferred that the bacterial killing was produced by the photosensitization effect of the PEDOT-C60 polymeric film.


image file: d1ra03417k-f8.tif
Fig. 8 Survival of S. aureus (∼104 CFU mL−1) cell suspensions in PBS depositing a drop (200 μL) with the cells on PEDOT-C60. (A) (1) Control: cells deposited on PEDOT-C60 and kept in dark 60 min. (2) Control: cells deposited on ITO and irradiated 60 min. (3) Cells deposited on PEDOT-C60 and irradiated 15 min. (4) Cells deposited on PEDOT-C60 and irradiated 30 min. (5) Cells deposited on PEDOT-C60 and irradiated 60 min. (B) (1) Control: cells deposited on PEDOT-C60 and kept in dark 30 min. (2) Cells deposited on PEDOT-C60 and irradiated 30 min. (3) Cells containing 50 mM sodium azide deposited on PEDOT-C60 and kept in dark 30 min. (4) Cells containing 50 mM sodium azide deposited on PEDOT-C60 and irradiated 30 min. (5) Cells containing 50 mM mannitol deposited on PEDOT-C60 and kept in dark 30 min. (6) Cells containing 50 mM mannitol deposited on PEDOT-C60 and irradiated 30 min. Samples were irradiated with visible light.

These findings can be compared to previous reports of PDI experiments carried out with carbon nanotubes (CNTs) which, together with fullerene C60, are the two most typical carbon-based nanomaterials. Although it is not correct to compare in vitro outcomes due to the diverse experimental conditions (number of cells, energy dose, PS concentration, etc.), our results showed that PEDOT-C60 presented a similar antimicrobial action than previously reported carbon-based nanomaterials. Serrano-Aroca et al. have shown that irradiation of carbon nanomaterials significantly improved their antibacterial properties, reaching a 99.7% inactivation of S. aureus after 3 h of LED irradiation.75 In addition, PEDOT-C60 presented a similar photoinactivation capability to porphyrin-CNT conjugates irradiated with visible light for 1 h.76

The effect of two scavengers of ROS (azide ion and mannitol) was also investigated in order to obtain information about the photodynamic mechanism involved in the in vitro photoinactivation. Sodium azide is a quencher of intracellular O2(1Δg),77 while mannitol acts as a scavenger of O2˙ and hydroxyl radical.78 According to this, 200 μL of PBS containing ∼104 cells and 50 mM sodium azide was deposited on PEDOT-C60 surface. No toxicity was detected using this concentration of azide ion in the dark (Fig. 8B, treatment 3). After 30 min irradiation, a lower cell inactivation was obtained in presence of sodium azide (Fig. 8B, treatment 4) compared to the treatment without the ROS scavenger (Fig. 8B, treatment 2). The addition of azide ion quenched the O2(1Δg), producing a protective effect on microbial cells. On the other hand, the presence of 50 mM mannitol was not toxic for bacteria cells on PEDOT-C60 in the dark (Fig. 8B, treatment 5). After 30 min of irradiation, the photokilling mediated by the surface exhibited a protective effect of around 1 log in suspensions containing mannitol (Fig. 8B, treatment 6), similar to the previous result. These outcomes indicate that two photooxidative pathways of action can take place under in vitro conditions, which is in concordance with the photodynamic studies carried out in solution.

3.9 Photoinactivation of S. aureus cells anchored to the surface

A common way bacterial infections spread is by surface contact transmission. This occurs particularly in common uses areas and facilities such as lobbies, doors, restrooms, dinners, and even public transport. Persons can also become infected by touching a contaminated surface and then touching their eyes, nose, mouth, and ears before washing hands. Another way of getting a disease transmitted by pathogens is by direct contact with an open wound, and the most common infection-causing bacteria is S. aureus.79 In this context, we have tested the inactivation capability of the surface monitoring bacterial inactivation at the single-cell level. This methodology was previously developed by us and others,46 and offers a simple and effective way of observing inactivation on a transparent surface employing PI as a cell death marker. Interaction of the dye with DNA or RNA duplexes emits red fluorescence after permeation through a ROS disrupted membrane on the surface of the material.80 This experiment may be considered as a proof of concept of airborne aerosolized contaminated water on a surface.

As it can be observed in Fig. 9 top panel, a complete inactivation of the pathogens was achieved by PEDOT-C60 photoactive material after applying the therapy for 30 min and a low energy dose (5.6 J cm−2). Control experiments were done using a glass coated ITO electrode lacking the polymer but treated with the same energy dose, and a coated PEDOT-C60 coverslip in dark conditions (Fig. 9, middle and bottom panels). These experiments show no cell death as was expected. In a previous work, electrodepositing a biscarbazol-dendrimeric Zn(II) porphyrin monomer, bacteria death was observed after applying the therapy for 7.5 min (0.3 J cm−2). The almost 20 times difference observed between these two surfaces can be attributed to the low absorption of visible light by the fullerene. However, the combination EDOT-fullerene offers a better control over the electrodeposition process and a higher photostability in comparison with the tetrapyrrolic macrocycle. In addition, the most relevant difference is that EDOT-C60 monomer requires only 3 simple synthetic steps, while biscarbazol-dendrimeric Zn(II) porphyrin monomer required a more complex sequence of ten steps to prepare the PS substituted with the electropolymerizable groups.26


image file: d1ra03417k-f9.tif
Fig. 9 Bright-field (first column) and fluorescence microscopy (second and third columns) images of S. aureus on the surface of a coverslip coated with PEDOT-C60 + light and the controls, ITO with no coating + light and a PEDOT-C60 surface in the dark. [PI] = 1 μM. Light dose: 5.6 J cm−2.

3.10 Photoinactivation of S. aureus biofilm

The antibacterial activity photoinduced by the PEDOT-C60 was also evaluated against S. aureus biofilm. This clinically important bacteria capable of growing on medical instruments and natural and inert surfaces is one of the main causes of the propagation of antibiotic resistance and the transmission of nosocomial infections.7,8 The biofilm physiology enables bacteria to survive prolonged exposure to antibiotics, in comparison with the cells in planktonic media.81

To study the capability of PEDOT-C60 to photoinactivate S. aureus biofilms, the surface was immersed into a S. aureus suspension and it was incubated for 24 h in order to form the biofilm. Then, it was submitted to different irradiation times (15, 30 and 60 min) with visible light. Survival of S. aureus biofilms formed on the PEDOT-C60 is shown in Fig. 10. Control experiments confirmed that the viability of the bacteria was unaffected by dark incubation on ITO electrode and PEDOT-C60 (Fig. 10, treatments 1 and 4). In addition, a slight inactivation lower than 1 log was found after 30 and 60 min of irradiation of the biofilm on ITO (Fig. 10, treatment 2 and 3). When the biofilms on PEDOT-C60 were irradiated for 15 or 30 min, a small and similar photosensitizing activity was found (Fig. 10, treatments 5 and 6). However, PEDOT-C60 showed a higher photosensitizing activity after 60 min of irradiation (Fig. 10, treatment 7), producing a >3 log decrease of biofilm survival, which represent >99.9% of cell photoinactivation. All these outcomes reveal that the biofilm eradication was produced by the photosensitizing action of PEDOT-C60. Hence, the combination of the electrodeposited polymeric films and visible light makes them promising self-sterilizing surfaces with a high antimicrobial action.


image file: d1ra03417k-f10.tif
Fig. 10 Survival of S. aureus biofilm on ITO electrode (treatments 1–3) and on PEDOT-C60 (treatments 4–7). (1) Control: biofilm on ITO electrode kept in dark 60 min. (2) Control: biofilm on ITO electrode irradiated 30 min. (3) Control: biofilm on ITO electrode irradiated 60 min. (4) Control: biofilm on PEDOT-C60 kept in dark 60 min. (5) Biofilm on PEDOT-C60 irradiated 15 min. (6) Biofilm on PEDOT-C60 irradiated 30 min. (7) Biofilm on PEDOT-C60 irradiated 60 min. Samples were irradiated with visible light.

The morphology and surface characteristics of S. aureus biofilm on PEDOT-C60 were analyzed by SEM. Large cellular aggregates were observed for biofilms on PEDOT-C60 kept in the dark (Fig. 11A). Different irradiation times with visible light cause a time-dependent disruption of the biofilms: after 30 min irradiation a significant reduction in the number of adhered bacteria and size of the aggregates were observed (Fig. 11B); while biofilms on PEDOT-C60 exposed to 60 min of irradiation turned into small clusters and a pronounced alteration of biofilm morphology (Fig. 11C). The effect can be more clearly evidenced in the magnified image showed in Fig. 11D. Thus, the antibacterial activity and the efficiency of the PDI treatment induce by PEDOT-C60 films could also be confirmed by SEM micrographs.


image file: d1ra03417k-f11.tif
Fig. 11 SEM images of S. aureus biofilm on PEDOT-C60. (A) Control: S. aureus biofilm on PEDOT-C60 keeping in the dark; (B) S. aureus biofilm on PEDOT-C60 exposed to visible light for 30 min; (C) S. aureus biofilm on PEDOT-C60 exposed to visible light for 60 min; (D) S. aureus biofilm on PEDOT-C60 exposed to visible light for 60 min at a higher magnification.

4. Conclusions

A suitable and straightforward method to produce antimicrobial and self-sterilizing surfaces based on a polymerizable fullerene derivative was established. This approach involved the design and synthesis of an electroactive monomer, which contains an electropolymerizable center of EDOT linked to a fullerene moiety. The monomer EDOT-C60 was easily obtained after three simple synthetic steps. The decoration of the heterocyclic EDOT unit with fullerene C60 substituent ensured the facile electropolymerization process, leading to the formation of polymeric films with pedant fullerene units. Cyclic voltammetry and UV-visible spectroscopy studies showed that fullerene units were not altered during the electropolymerization process, conserving the main photophysical characteristics of the chromophore in the polymer matrix. Fullerene C60 pendant groups in PEDOT chain also retain their photodynamic properties, being able to generate ROS through both type I and type II mechanisms. The PEDOT-C60 electrodeposited film exhibited good photostability thanks to the low photodegradation of fullerene C60. Thereby, in this work we achieve a good combination of photostability and high photodynamic activity reached by the presence of fullerene C60 in the polymeric chain. Hence, this photoactive material would result useful for practical applications.

The antimicrobial capability of the surfaces was evaluated in three different situations that can contaminate a surface: planktonic cells, bacteria attached to the surface and biofilms. In all cases, the PDI treatment showed an inactivation higher than 99.9%. Thus, our approach can be considered bactericidal or antimicrobial according to the American Society of Microbiology,82 since a decrease higher than 3 log CFU (photoinactivation >99.9%) was achieved for the three different conditions. Our outcomes demonstrated that this highly efficient photoactive self-sterilizing coating could make an important contribution to control the microbial proliferation and to maintain aseptic conditions, reducing the infections caused by surface-adhering pathogens.

Conflicts of interest

There are no conflicts to declare.

Acknowledgements

Authors are grateful to Consejo Nacional de Investigaciones Científicas y Técnicas (CONICET, PIP-2015 1122015 0100197 CO) of Argentina, SECYT Universidad Nacional de Río Cuarto (PPI-2020 Res. 083/20) and Agencia Nacional de Promoción Científica y Tecnológica (FONCYT, PICT-2016-2370, PICT-2016-0667) for financial support. E. R., A. M. D., L. P. M., C. A. S., L. A. O., M. A. G., E. N. D. and D. A. H. are Scientific Members of CONICET.

References

  1. D. R. Jenkins, Medicine, 2017, 45, 629–633 CrossRef.
  2. Y. Li, Z. Gong, Y. Lu, G. Hu, R. Cai and Z. Chen, Int. J. Surg., 2017, 42, 164–169 CrossRef PubMed.
  3. H. A. Khan, F. K. Baig and R. Mehboob, Asian Pac. J. Trop. Biomed., 2017, 7, 478–482 CrossRef.
  4. H. A. Khan, A. Ahmad and R. Mehboob, Asian Pac. J. Trop. Biomed., 2015, 5, 509–514 CrossRef.
  5. N. A. Turner, B. K. Sharma-Kuinkel, S. A. Maskarinec, E. M. Eichenberger, P. P. Shah, M. Carugati, T. L. Holland and V. G. Fowler, Jr, Nat. Rev. Microbiol., 2019, 17, 203–218 CrossRef CAS.
  6. E. J. Choo, Infect. Chemother., 2017, 49, 158–159 CrossRef.
  7. R. Parastan, M. Kargar, K. Solhjoo and F. Kafilzadeh, Gene Rep., 2020, 20, 100739 CrossRef.
  8. K. M. Craft, J. M. Nguyen, L. J. Berg and S. D. Townsend, MedChemComm, 2019, 10, 1231–1241 RSC.
  9. B. Song, E. Zhang, X. Han, H. Zhu, Y. Shi and Z. Cao, ACS Appl. Mater. Interfaces, 2020, 12(19), 21330–21341 CrossRef CAS PubMed.
  10. A. M. C. Maan, A. H. Hofman, W. M. de Vos and M. Kamperman, Adv. Funct. Mater., 2020, 30, 2000936 CrossRef CAS.
  11. S. Rtimi, S. Giannakis and C. Pulgarin, Molecules, 2017, 22, 1074 CrossRef PubMed.
  12. M. Q. Mesquita, C. J. Dias, M. G. P. M. S. Neves, A. Almeida and M. A. F. Faustino, Molecules, 2018, 23, 2424–2460 CrossRef PubMed.
  13. A. M. Durantini, D. A. Heredia, J. E. Durantini and E. N. Durantini, Eur. J. Med. Chem., 2018, 144, 651–661 CrossRef CAS PubMed.
  14. M. R. Hamblin and G. Jori, Photodynamic Inactivation of Microbial Pathogens: Medical and Environmental Applications, Royal Society of Chemistry, Cambridge, UK, 2011 Search PubMed.
  15. P. Dharmaratne, D. N. Sapugahawatte, B. Wang, C. L. Chan, K.-M. Lau, C. Lau, K. P. Fung, D. K. P. Ng and M. Ip, Eur. J. Med. Chem., 2020, 200, 112341 CrossRef CAS.
  16. M. Sadekuzzaman, S. Yang, M. F. R. Mizan and S. D. Ha, Compr. Rev. Food Sci. Food Saf., 2015, 14, 491–509 CrossRef.
  17. X. Hu, Y.-Y. Huang, Y. Wang, X. Wang and M. R. Hamblin, Front. Microbiol., 2018, 9, 1299 CrossRef.
  18. W. C. M. A. de Melo, P. Avci, M. Nóbrega de Oliveira, A. Gupta, D. Vecchio, M. Sadasivam, R. Chandran, Y.-Y. Huang, R. Yin, L. R Perussi, G. P. Tegos, J. R. Perussi, T. Dai and M. R. Hamblin, Expert Rev. Anti-Infect. Ther., 2013, 11, 669–693 CrossRef CAS.
  19. S. R. Martínez, Y. B. Palacios, D. A. Heredia, V. Aiassa, A. Bartolilla and A. M. Durantini, ACS Appl. Mater. Interfaces, 2021, 13, 11597–11608 CrossRef PubMed.
  20. S. Noimark, C. W. Dunnill and I. P. Parkin, Adv. Drug Delivery Rev., 2013, 65, 570–580 CrossRef CAS.
  21. C. Spagnul, L. C. Turner and R. W. Boyle, J. Photochem. Photobiol., B, 2015, 150, 11–30 CrossRef CAS.
  22. W. J. Peveler, S. Noimark, H. Al-Azawi, G. B. Hwang, C. R. Crick, E. Allan, J. B. Edel, A. P. Ivanov, A. J. MacRobert and I. P. Parkin, ACS Appl. Mater. Interfaces, 2018, 10, 98–104 CrossRef CAS PubMed.
  23. J. Hynek, J. Zelenka, J. Rathouský, P. Kubát, T. Ruml, J. Demel and K. Lang, ACS Appl. Mater. Interfaces, 2018, 10, 8527–8535 CrossRef CAS PubMed.
  24. W. Zhou, S. Begum, Z. Wang, P. Krolla, D. Wagner, S. Bräse, C. Wöll and M. Tsotsalas, ACS Appl. Mater. Interfaces, 2018, 10(2), 1528–1533 CrossRef CAS PubMed.
  25. R. A. Craig and C. P. McCoy, in Antimicrobial Coatings and Modifications on Medical Devices, Springer, Cham., 2017, pp. 241–266 Search PubMed.
  26. D. A. Heredia, S. R. Martínez, A. M. Durantini, M. E. Pérez, M. I. Mangione, J. E. Durantini, M. A. Gervaldo, L. A. Otero and E. N. Durantini, ACS Appl. Mater. Interfaces, 2019, 11, 27574–275877 CrossRef CAS.
  27. M. B. Ballatore, J. Durantini, N. S. Gsponer, M. B. Suarez, M. Gervaldo, L. Otero, M. B. Spesia, M. E. Milanesio and E. N. Durantini, Environ. Sci. Technol., 2015, 49, 7456–7463 CrossRef CAS PubMed.
  28. C. Comuzzi, A. Fiorot, A. Baggio, M. Maifreni, P. Strazzolini, M. Marino and S. Susmel, ChemPlusChem, 2020, 85, 776–782 CrossRef CAS.
  29. Y.-Y. Huang, S. K. Sharma, R. Yin, T. Agrawal, L. Y. Chiang and M. R. Hamblin, J. Biomed. Nanotechnol., 2014, 10, 1918–1936 CrossRef CAS.
  30. M. B. Spesia, M. E. Milanesio and E. N. Durantini, Fullerene Derivatives in Photodynamic Inactivation of Microorganisms, in Nanostructures for Antimicrobial Therapy, ed. A. Ficai and A. M. Grumezescu, Elsevier, Amsterdam, 2017, ch. 18, vol. 1, pp. 413–433 Search PubMed.
  31. S. K. Sharma, L. Y. Chiang and M. R. Hamblin, Nanomedicine, 2011, 6, 1813–1825 CrossRef CAS PubMed.
  32. I. V. Bagrov, I. M. Belousova, A. V. Ermakov, V. M. Kiselev, I. M. Kislyakov, T. K. Kris'ko and T. D. Murav'eva, Opt. Spectrosc., 2008, 105, 720–725 CrossRef CAS.
  33. A. Blacha-Grzechnik, M. Krzywiecki, R. Motyka and M. Czichy, J. Phys. Chem. C, 2019, 123, 25915–25924 CrossRef CAS.
  34. A. Nyga, R. Motyka, G. Bussetti, A. Calloni, M. S. Jagadeesh, S. Fijak, S. Pluczyk-Malek, P. Data and A. Blacha-Grzechnik, Appl. Surf. Sci., 2020, 525, 146594 CrossRef CAS.
  35. B. Cao, C.-J. Lee, Z. Zeng, F. Cheng, F. Xu, H. Cong and G. Cheng, Chem. Sci., 2016, 7, 1976–1981 RSC.
  36. M. Sánchez-Jiménez, F. Estrany, N. Borràs, B. Maiti, D. Díaz Díaz, L. J. del Valle and C. Alemán, Soft Matter, 2019, 15, 7695–7703 RSC.
  37. T. Goda and Y. Miyahara, Langmuir, 2019, 35(5), 1126–1133 CrossRef CAS.
  38. S. Gomez-Carretero, R. Nybom and A. Richter-Dahlfors, Adv. Healthcare Mater., 2017, 1700435 CrossRef.
  39. M. B. Ballatore, M. E. Milanesio, H. Fujita, J. S. Lindsey and E. N. Durantini, J. Biophotonics, 2020, 13, e201960061 CrossRef.
  40. T. Hamano, K. Okuda, T. Mashino, M. Hirobe, K. Arakane, A. Ryu, S. Mashiko and T. Nagano, Chem. Commun., 1997, 1, 21–22 RSC.
  41. R. Liu, S. Fu, H. Zhan and L. A. Lucia, Ind. Eng. Chem. Res., 2009, 48, 9331–9334 CrossRef CAS.
  42. A. C. Scanone, S. C. Santamarina, D. A. Heredia, E. N. Durantini and A. M. Durantini, ACS Appl. Bio Mater., 2020, 3(2), 1061–1070 CrossRef CAS.
  43. M. B. Ballatore, M. B. Spesia, M. E. Milanesio and E. N. Durantini, RSC Adv., 2018, 8, 22876–22886 RSC.
  44. M. B. Ballatore, M. B. Spesia, M. E. Milanesio and E. N. Durantini, Eur. J. Med. Chem., 2014, 83, 685–694 CrossRef CAS.
  45. D. D. Ferreyra, E. Reynoso, P. Cordero, M. B. Spesia, M. G. Alvarez, M. E. Milanesio and E. N. Durantini, J. Photochem. Photobiol., B, 2016, 158, 243–251 CrossRef CAS PubMed.
  46. S. R. Martínez, Y. B. Palacios, D. A. Heredia, M. L. Agazzi and A. M. Durantini, ACS Infect. Dis., 2019, 5(9), 1624–1633 CrossRef PubMed.
  47. E. Reynoso, D. D. Ferreyra, E. N. Durantini and M. B. Spesia, Photodermatol., Photoimmunol. Photomed., 2019, 35, 322–331 CrossRef CAS PubMed.
  48. M. B. Spesia, D. A. Caminos, P. Pons and E. N. Durantini, Photodiagn. Photodyn. Ther., 2009, 6, 52–61 CrossRef CAS PubMed.
  49. N. Berton, I. Fabre-Francke, D. Bourrat, F. Chandezon and S. Sadki, J. Phys. Chem. B, 2009, 113, 14087–14093 CrossRef CAS PubMed.
  50. A. Hirsch, T. Grosser, A. Skiebe and A. Soi, Chem. Ber., 1993, 126, 1061–1067 CrossRef CAS.
  51. J. Averdung, J. Mattay, D. Jacobi and W. Abraham, Tetrahedron, 1995, 9, 2543–2552 CrossRef.
  52. A. Hirsch and M. Brettreich, Fullerenes: Chemistry and Reactions, John Wiley & Sons, 2006 Search PubMed.
  53. M. M. Cases, M. Duran, J. Mestres, N. Martín and M. Solá, J. Org. Chem., 2001, 66, 433–442 CrossRef CAS.
  54. M. Prato, Q. Chan Li and F. Wudl, J. Am. Chem. Soc., 1993, 115, 1148–1150 CrossRef CAS.
  55. A. C. Pinho and A. P. Piedade, Polymers, 2020, 12, 2469 CrossRef CAS PubMed.
  56. K. Namsheer and C. S. Rout, RSC Adv., 2021, 11, 5659–5697 RSC.
  57. M. B. Suarez, C. Aranda, L. Macor, J. Durantini, D. A. Heredia, E. N. Durantini, L. Otero, A. Guerrero and M. Gervaldo, Electrochim. Acta, 2018, 292, 697–706 CrossRef CAS.
  58. E. Nasybulin, S. Wei, M. Cox, I. Kymissis and K. Levon, J. Phys. Chem. C, 2011, 115, 4307–4314 CrossRef CAS.
  59. M. Otero, T. Dittrich, J. Rappich, D. A. Heredia, F. Fungo, E. Durantini and L. Otero, Electrochim. Acta, 2015, 173, 316–322 CrossRef CAS.
  60. A. Yashiro, Y. Nishida, M. Ohno, S. Eguchi and K. Kobayashi, Tetrahedron Lett., 1998, 39, 9031–9034 CrossRef CAS.
  61. D. A. Heredia, E. J. Gonzalez Lopez, E. N. Durantini, J. Durantini, T. Dittrich, J. Rappich, L. Macor, C. Solis, G. M. Morales, M. Gervaldo and L. Otero, Electrochim. Acta, 2019, 311, 178–191 CrossRef CAS.
  62. D. DeLongchamp and P. T. Hammond, Adv. Mater., 2001, 13, 1455–1459 CrossRef.
  63. M. R. Hamblin, Photochem. Photobiol. Sci., 2018, 17, 1515–1533 CrossRef CAS PubMed.
  64. F. Käsermann and C. Kempf, Rev. Med. Virol., 1998, 8, 143–151 CrossRef.
  65. D. A. Heredia, A. M. Durantini, A. M. Sarotti, N. S. Gsponer, D. D. Ferreyra, S. G. Bertolotti, M. E. Milanesio and E. N. Durantini, Chem.–Eur. J., 2018, 24, 5950–5961 CrossRef CAS.
  66. A. Gomes, E. Fernandes and J. L. Lima, J. Biochem. Biophys. Methods, 2005, 65, 45–80 CrossRef CAS PubMed.
  67. L. Kong and R. G. Zepp, Environ. Toxicol. Chem., 2012, 31, 136–143 CrossRef CAS.
  68. M. D. Funes, D. A. Caminos, M. G. Alavarez, F. Fungo, L. A. Otero and E. N. Durantini, Environ. Sci. Technol., 2009, 43, 902–908 CrossRef CAS PubMed.
  69. G. J. Maghzal, K. H. Krause, R. Stocker and V. Jaquet, Free Radical Biol. Med., 2012, 53, 1903–1918 CrossRef CAS.
  70. Y. Yamakoshi, N. Umezawa, A. Ryu, K. Arakane, N. Miyata, Y. Goda, T. Masumizu and T. Nagano, J. Am. Chem. Soc., 2003, 125, 12803–12809 CrossRef CAS PubMed.
  71. M. Ehrenshaft, L. J. Deterding and R. P. Mason, Free Radical Biol. Med., 2015, 89, 220–228 CrossRef CAS PubMed.
  72. M. E. Milanesio, M. G. Alvarez, V. Rivarola, J. J. Silber and E. N. Durantini, Photochem. Photobiol., 2005, 81, 891–897 CrossRef CAS.
  73. R. Koeppe and N. S. Sariciftci, Photochem. Photobiol. Sci., 2006, 5, 1122–1131 CrossRef CAS.
  74. M. B. Ballatore, M. B. Spesia, M. E. Milanesio and E. N. Durantini, Eur. J. Med. Chem., 2014, 83, 685–694 CrossRef CAS PubMed.
  75. L. Elias, R. Taengua, B. Frígols, B. Salesa and Á. Serrano-Aroca, Int. J. Mol. Sci., 2019, 20, 3603 CrossRef CAS PubMed.
  76. U. Sah, K. Sharma, N. Chaudhri, M. Sankar and P. Gopinath, Colloids Surf., B, 2018, 162, 108–117 CrossRef CAS.
  77. E. F. F. da Silva, B. W. Pedersen, T. Breitenbach, R. Toftegaard, M. K. Kuimova, L. G. Arnaut and P. R. Ogilby, J. Phys. Chem. B, 2012, 116, 445–461 CrossRef CAS.
  78. T. T. Maisch, C. Bosl, R.-M. Szeimies, N. Lehn and C. Abels, Antimicrob. Agents Chemother., 2005, 49, 1542–1552 CrossRef CAS.
  79. J. Li, X. Liu, L. Tan, Z. Cui, X. Yang, Y. Liang, Z. Li, S. Zhu, Y. Zheng, K. W. K. Yeung, X. Wang and S. Wu, Nat. Commun., 2019, 10, 4490 CrossRef.
  80. M. Rosenberg, N. F. Azevedo and A. Ivask, Sci. Rep., 2019, 9, 6483 CrossRef.
  81. A. Kumar, A. Alam, M. Rani, N. Z. Ehtesham and S. E. Hasnain, Int. J. Med. Microbiol., 2017, 307, 481–489 CrossRef CAS PubMed.
  82. E. Alves, M. A. Faustino, M. G. Neves, A. Cunha, J. Tome and A. Almeida, Future Med. Chem., 2014, 6, 141–164 CrossRef CAS PubMed.

Footnote

Electronic supplementary information (ESI) available. See DOI: 10.1039/d1ra03417k

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