Bactericides Properties of Chitosan Metal Quantum Dots Microbial Pathogenicity Against E. coli, S. aureus, and S. Typhi

Cárdenas-Triviño, Galo; Saludes-Betanzo, María J.; Vergara-González, Luis

doi:https://doi.org/10.1155/2020/5920941

International Journal of Polymer Science

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Abstract Introduction Experimental Results Discussion Conclusions Data Availability Conflicts of Interest Acknowledgments Supplementary Materials References Copyright Related Articles

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Natural-Based Nanocomposites and their Biomedical Applications

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Research Article | Open Access

Volume 2020 | Article ID 5920941 | https://doi.org/10.1155/2020/5920941

Bactericides Properties of Chitosan Metal Quantum Dots Microbial Pathogenicity Against E. coli, S. aureus, and S. Typhi

Galo Cárdenas-Triviño,¹María J. Saludes-Betanzo,²and Luis Vergara-González²

Academic Editor: Ehsan N. Zare

Received12 Jun 2020

Revised03 Sept 2020

Accepted11 Sept 2020

Published25 Sept 2020

Abstract

The nanotechnology is considered as a tool to overcome antibiotic-resistant infections. The aim of this study was to investigate the antibacterial properties of quantum dots (QDs) of Au, Ag, and Cu supported in chitosan against Escherichia coli (ATCC 25922), Staphylococcus aureus (ATCC 29213), and Salmonella Typhi (ATCC 9993) strains. The QDs were synthesized by the method (Chemical Liquid Deposition, CLD) using 2-ethoxyethanol as solvent ( approximate dispersion concentration). Then, NPs supported in chitosan were synthesized by solvated metal atom dispersion (SMAD) in two concentrations, labelled [A] and [B] (0.05 and 0.1 g/L) for each metal with chitosan resulting in an average size of Au , Ag , and Cu , respectively. Several other techniques were performed such as TEM, SEM/EDX, TGA, DSC, and FT-IR for characterizing QDs. The antibacterial assay was performed with 8 agents on cultures of E. coli, S. aureus, and S. Typhi by disk diffusion, broth macrodilution, and determining death curve to the most sensitive pathogen. The antibacterial effect of the nanoparticles was compared using the diameter of growth inhibition zone by agar disk diffusion and through the minimal inhibitory concentration (MIC) and minimal bactericide concentration (MBC) obtained by macrodilution in batch culture with an initial inoculum of . The highest bactericidal effect was obtained with nanoparticles of Au, Ag, and Cu (0.1 g/L) with MIC and MBC of 200 and 400 mg/mL, respectively. The greatest bactericidal effect considering the three pathogens turned out to be Ag QDs (0.05 and 0.1 g/L). A bactericidal effect of metal nanoparticles is affected mainly by the electronegativity, the concentration of nanoparticles, and the bacterial age culture.

1. Introduction

The biocide properties of metal nanoparticles (MNPs) have generated great interest for their application as new antimicrobial agents [1, 2]. This is due to their higher surface area which would generate more contact with the cell surface of pathogens. This feature generates a tendency to form agglomerates mainly due to Van der Waals and electrostatic forces. The importance of stabilizing the high surface energy to avoid such agglomeration with the use of an agent capable of associating with the surface of the particles is finally in their suspended stabilization and subsequent improvement of antimicrobial activity [3]. One of the protective agents used to reduce the energy on the surface of the NPs is chitosan. This is a natural polymer of high availability, biodegradability, nontoxicity, biocompatibility, and with a polycationic structure that allows to form chelates with antimicrobial activity [4]. These characteristics make chitosan, and other natural polymers, an ideal material to be used as a support for metallic nanoparticles, with antibacterial properties, for its potential use in replacement of some conventional treatments with antibiotics [5, 6]. The rise of bacterial strains with acquired antibiotics resistance in recent years had been associated with the overuse of such drugs [7], increasing the morbidity and mortality that can require a greater cost of longer treatments including hospitalization [8, 9]. Furthermore, it is unlikely that bacteria could develop resistance to the NPs compared to antibiotics, since metals affect multiple targets in microbial cells including the cell membrane, DNA, and enzyme activity [10, 11, 12].

The aim of this study was to develop an antimicrobial agent with bactericide properties using a not conventional formulation in which the quantum dots of gold, silver, and copper supported in chitosan were used and their antibacterial activity was proved against three pathogens (Escherichia coli, Staphylococcus aureus, and Salmonella Typhi).

2. Experimental

2.1. Synthesis of Metal QDs (Au, Ag, and Cu) in Colloidal Suspension

The solvent 2-ethoxyethanol (Merck p.a.), nitrogen and nitrogen gas (Linde), and ultrapure metals analytical grade (Aldrich) were used. The colloids of Au, Ag, and Cu were prepared by a method called Chemical Liquid Deposition (CLD). The method involved codeposition with physical metal vapor and organic vapor under high vacuum pressure of 10^-5 bar and temperature of 77 K in a metal atom reactor [13]. The metal quantum dots of Au, Ag, and Cu in 2-ethoxyethanol were synthesized at a concentration of (19.69 mg Au, 10.77 mg Ag, and 6.35 mg Cu in 100 mL solvent). Then, those were characterized in order to determine if this concentration will produce stable colloids. Finally, after the characterization, supported metal QDs in chitosan were synthesized by the method of solvated metal atom dispersion (SMAD). This method allows to prepare very small particles due to the solvation of a polar organic solvent and allows to incorporate them in polymer either in a solid or liquid phase.

2.2. Characterization of Metal Colloids

Metal colloids were characterized by Ultraviolet and Visible Spectroscopy (UV-VIS) and transmission electron microscopy (TEM) with X-ray diffraction (XRD). The absorption spectra of UV-Visible NPs of colloidal solutions were measured by the selection of wavelengths from 200 to 500 nm at using a Shimadzu UV-spectrometer Corp, Kyoto Japan. The colloidal dispersions were diluted about 0.1 mL dispersion in 3 mL of 2-ethoxyethanol solvent, prior to analysis to avoid excessive concentration of colloidal particles and higher absorption. For transmission electron microscopy, a drop of colloidal dispersions was placed with their respective solvent and dried on a copper grid of 150 mesh carbon-coated. The transmission micrographs were obtained using a JEM JEOL1200 EX microscope operated with an accelerating voltage of 120 keV; this equipment reaches a resolution of 4 Å. Then, the equipment operates in X-ray diffraction (XRD) to determine the chemical species of nanoparticles. To obtain the size of the quantum dots, these will be determined by optical measurements (digital measurements in pixels), where specific particle diameters were measured at random by the Mac Biophotonics software Image J. Finally, the data obtained are plotted in the form of a frequency histogram with Gaussian distribution.

2.3. Synthesis of Metal Nanoparticles Supported in Chitosan

Chitosan (Qs) with 95% deacetylation degree and molecular weight 350.000 Da provided by Quitoquímica Co. (Coronel, Bío-Bío Region, Chile), 2-ethoxyethanol (Merck p.a.), liquid nitrogen, ultrapure nitrogen gas (Aga), and metals of analytical grade (Sigma-Aldrich). The QDs (Au, Ag, and Cu) supported on chitosan were synthesized by the method of solvated metal atom dispersion (SMAD). In the synthesis, the solvent is responsible to open the polymer chains of chitosan and allowed the inclusion of quantum dots [14].

The SMAD method involves the physical codeposition vapor of metal-organic vapors (2-ethoxyethanol) in the same physical conditions of the CLD method, but with the introduction of chitosan in the reactor [15]. Also, ethanol was used, basically both for their higher dielectric constant to help colloidal stabilization. The solvent is recovered after each reaction.

Two different concentrations of metal quantum dots (MQDs) were synthesized labeled as [A], which has a concentration of 5 mg in 100 mL of solvent and 2 g of chitosan (0.05 g/L 2gQs), and [B] 10 mg in 100 mL of solvent and 2 g of chitosan (0.10 g/L 2 g Qs). In terms of molarity, labeling [A] for QDs is as follows: Au , Ag , and Cu supported in 2 g of chitosan. The concentration [B] for QDs is as follows: Au , Ag , and Cu equally supported.

Since the concentrations in terms of molarity are different, we carried out a synthesis of Ag QDs of in order to obtain a molar equivalence with Cu QDs, Cu [A]-Qs and analyzed the influence on bacterial susceptibility test. Doped chitosan with QDs and chitosan alone were suspended at 1% (w/v) in 1% acetic acid and stored in the freezer at 4°C in amber vials for the subsequent susceptibility test. The MW of chitosan remains the same after the reaction. There are other methods recently published to obtain nanoparticles [16, 17].

2.4. Characterization of Metal Nanoparticles Supported in Chitosan

The NPs supported on chitosan were characterized by measuring using the scanning electron microscopy (SEM) with X-ray spectroscopy (EDX), thermogravimetric analysis (TGA), differential scanning calorimetry (DSC), and Fourier transform infrared spectroscopy (FTIR). Transmission electron micrographs were obtained, placing a drop of colloidal dispersion on a grid, let it dry, and then coated with gold atoms for 3 min with a thickness of 150 Å. Then, the sample is dried to finally be observed under the microscope JSM 6380LV-JEOL Scanning Electron Microscope with 20 kV acceleration voltage. The TGA analysis for NPs supported was performed taking place in a thermogravimetric analyzer Q-1000 Thermo. The mass of the sample is generally in the range of . Samples were taken to a balance system equipped, and the temperature was increased from 25°C to 550°C at a heating rate of 10°C/min under a nitrogen gas atmosphere. To obtain the thermograms, the mass of the sample is continuously recorded as a function of temperature. The DSC analysis for QDs supported took place in a METTLER TOLEDO DSC analyzer, equipped with the STAR MODEL 822 software system. The mass of the sample was in a range of and a heating rate of 10°C/min under a nitrogen gas flow. The Fourier transform infrared (FTIR) spectra were performed on a Nicolet Magna 5PC spectrophotometer, and KBr pellets 2% concentration were prepared using the Omnic 5.2a program at room temperature.

2.5. Ultraviolet and Visible Spectroscopy

UV-VIS absorption spectra of the colloidal quantum dots in solutions were measured by wavelength selection, from 200 to 500 nm at 25°C, using a UV–Shimadzu Corp spectrometer, Kyoto, Japan. The baseline with the same solvent for the reaction was used, and each QDs (gold, silver, and copper) was examined at different times, to perform the study of the effect of sedimentation or flocculation and how the size of the colloids influences it. Colloidal solutions were diluted at approximately 0.1 mL of dispersion in 3 mL of pure solvent prior to analysis to avoid excessive agglomeration of colloidal particles and their high absorption.

2.6. Thermogravimetric Analysis

TGA analyses for supported NPs are performed on a Thermo Q-1000 thermogravimetric analyzer. The mass of the NPs is where they are carried to a balance system equipped with a heating temperature system that increases from 25 to 550°C with a heating rate of 10°C/min in gas nitrogen flow. To obtain the thermograms, the mass of the sample is continuously recorded according to the temperature.

2.7. Antimicrobial Activity Analysis

Escherichia coli (ATCC 25922), Staphylococcus aureus (ATCC 29213), and Salmonella Typhi (ATCC 9993) strain were used, and a stock of them was maintained at -20°C in San Sebastian University laboratory. All assay was performed in Mueller-Hinton (Merck) broth or agar and was prepared according to the manufacturer’s instructions and stored at 4°C.

Three different assays were performed to determine the antimicrobial properties of chitosan-supported NPs.

2.7.1. Disk Diffusion Test

The disc diffusion test was performed to determine the sensitivity of bacterial strains to chitosan alone and gold, silver, and copper NPs supported in chitosan (Au-Qs, Ag-Qs, and Cu-Qs). The assay was performed according to (CLSI) [18] guidelines using disk (6.3 mm diameter) impregnated with 20 μL of each solution to be tested.

2.7.2. Serial Macrodilution Method

One of the methods used to determine the minimal inhibitory concentration (MIC) is the broth dilution method [18]. This is based on the decreasing concentrations of an agent with antibacterial properties, acting on a standard inoculum of the microorganism. To achieve the macrodilution test in broth, an inoculum is initially prepared approximately at 10⁶ CFU/mL. Then, a series of tubes were set up with a solution of each agent to study from 0.010% to 0.16% w/v (100 to 1600 ppm) suspended in 1% acetic acid plus 2 mL of inoculum previously prepared around to finally produce an inoculum of and allowed to incubate at for 18-24 hours. The equivalence to QDs is shown in Table 1. The tube with a higher concentration that did not show growth, indicates the MIC. From each tube with no growth, a sample of 0.1 mL was obtained and streak onto a Mueller-Hinton agar plate and incubated 18-24 hours at . The higher dilution that did not shown growth of colonies in the plates was considered the MBC (minimal bactericidal concentration).

2.8. Death Curve Determination for E. coli by Direct Plate Counting Method

For death curve assessment, 10 mL of inoculum adjusted to 0.5 McFarland was added to 90 mL of fresh Mueller-Hinton medium to generate a final inoculum of . A final concentration of 400 mg/mL of chitosan doped with gold () and copper () was used (Au [B]-Qs and Cu [B]-Qs); a positive control was prepared in the same way that of the samples but without chitosan/quantum-dots. All tests were done in duplicate. The flasks were incubated at 37°C and 150 rpm. Every two hours, the samples were taken to perform the count of viable cells. For that, 1 ml of each flask was added to 9 ml of sterile distilled water and made serial dilutions 4 times to obtain 10⁶, 10⁵, 10⁴, and 10³ CFU/mL of the original inoculum. From each dilution, 0.1 ml was spread onto a Mueller-Hinton agar plate and incubated overnight at 37°C. Colony counts were done using a Suntex 570 colony counter. The viable bacterial counts were plotted against the exposure time of E. coli to antibacterial agents and compared with positive control.

3. Results

3.1. Characterization of Metal Quantum Dots of Au, Ag, and Cu in Colloidal Suspensions

The results determine that by the CLD method using 2-ethoxyethanol, it is possible to obtain Au, Ag, and Cu QDs with , , and , respectively; to simplify, we round the values obtained from the micrographs (Au , Ag , and Cu ). Also, the prevalence of spheroidal shape QDs of the three metals was observed. This can be correlated with the results of UV-VIS spectroscopy, summarized in Table 2. The spectra obtained for each run showed a single symmetrical band of surface plasmon resonance, reaching for Au QDs in a wavelength range of 235-505, then 383 for Ag and 210-305 nm for Cu, respectively.

Figure 1 shows the TEM images, with their respective histogram for a total of 100 QDs. For Au, Ag and Cu QDs solvated in 2-ethoxyethanol, Figure 2 shows the diffraction pattern.

(a)

(b)

(c)

(a)

(b)

(c)

Using the ED pattern (Figure 2), it was possible to confirm the crystalline nature through Miller’s indices and the presence of the Au, Ag, and Cu quantum dots at the nanometric level. Interplanar distances are from diffraction rings and can be indexed according to the cubic structure centered on the faces (fcc) of the metals. The Au’s QDs represent a mixture of cubooctahedral and icosahedral systems; Ag’s QDs a mixture of tetragonal, hexagonal, cubic, and trigonal; and Cu’s QDs a cubic and trigonal system.

3.2. Characterization of Metal Nanoparticles of Au, Ag, and Cu Supported in Chitosan

Through scanning electron microscopy (SEM), differences were observed in the morphology of the different composites obtained from the synthesized colloids, being the chitosan-Ag the smoother surface. Furthermore, EDX confirms the presence of the metal on the surface.

The elemental analysis of each composite through dispersive X-ray spectroscopy (SEM/EDX) provides the Au quantum dots [B] are those with the lowest atomic percentage (0.06%) in the polymer surface compared to Ag and CuNPs. This explains that the AuQDs are mostly absorbed by the polymer, CuQDs [B], that have the highest metal percentage (1.59%) which leads to greater instability and tendency to agglomeration and oxidation. The results can be complemented with those obtained by X-ray diffraction (XRD) of the CuQDs. Obtaining absolute certainty of the composition of metals in the polymer requires elemental analysis by atomic absorption.

Figure 3 shows the SEM micrograph and EDX analysis of quantum dots supported on chitosan concentration [B]. TGA tests were performed for all blends metal polymer and the polymer itself.

(a)

(b)

(c)

Table 3 summarizes the results of the percentage of mass and atomic percentage of the QDs of Au, Ag, and Cu in concentration [B], read in the graphs obtained in Figure 3.

3.3. UV-Vis

The optical absorption spectra of metallic QDs are referred to by surface plate resonances [20]. These resonances are located at larger wavelengths as the particle size increases. Figure 4 shows the result of the UV-VIS analysis NPs after their synthesis (30 min) and 3 months later. Only a slight difference in the spectrum between the two is observed, indicating the high stability of the QDs over time.

3.4. Thermogravimetric and Scanning Calorimetry Analysis

Thermogravimetry analyses were performed for all polymer-metal mixtures and for the polymer itself. Figure 5 shows the TGA of chitosan, showing the respective temperature of the maximum rate of decomposition and the behavior of the polymer when it is heated above 100°C. There is a slight weight loss around 100°C, which is attributed to the evaporation of water, whose content is about 3 to 5%. The bottom line shows a sharp decrease around 200°C, which ends up with the loss of almost the entire sample.

The results of the thermogravimetric method show that the thermal degradation of the MQDs supported on chitosan has a decomposition temperature (DT) lower than the pure polymer. This is because the metal QDs act as an impurity lowering the temperature of decomposition of the latter, which increases the entropy to be a composite. But in the metals with higher oxidation potentials such as Ag and Cu, the Td decreases with the amount of metal QDs. See Figures 6, 7, and 8.

However, this difference between the pure chitosan and chitosan doped with NPs is low and is within the range of 3°C, so the NPs did disrupt the inherent physical properties of chitosan itself.

With respect to the DSC results, Table 4 summarizes all the kinetic parameters for the thermal degradation of chitosan and chitosan doped with MQDs. The DSC either exo or endo shows values lower than pure chitosan; those results confirm the influence as impurities of the nanoparticles.

3.5. Fourier Transformed Infrared Spectroscopy

FT-IR analyses for solvent, chitosan, and metal NPs supported in Qs are shown in Figure 9. Absorption spectra are analyzed in the midrange and far range through the peaks obtained.

Table 5 presents the allocations of the peaks of the solvent, chitosan, and NPs Au, Ag, and Cu in their two concentrations ([A] and [B]).

The FT-IR analysis for the solvent, chitosan, and MQDs supported was carried out in the middle and far range spectra. The analysis can clarify that for midrange spectra, only show typical absorptions of chitosan does not appear any new absorption band of the polymer with the QDs. The analysis can clarify that for midrange spectra, only typical absorptions of chitosan are shown and any new absorption band of the polymer with the QDs does not appear. Evidence shows the interaction between the amino groups of the Qs and the atoms of the surface of MQDs. Also seen in this spectrum are the new bands near 150 cm^-1 which can be assigned to metal-metal interaction (MM) of the quantum dots.

3.6. Antimicrobial Activity Analyses

3.6.1. Agar Diffusion Method

As expected, the best activity was seen in all assay with a higher concentration of QDs ([B]). As shown in Figure 10, a trend of increased susceptibility was found to E. coli especially to Au QDs.

However, for S. aureus, a best or similar activity was shown using the lowest concentration [A] with all QDs. Antibacterial activity was seen too in not doped chitosan against the three tested bacterial strains.

3.6.2. Serial Macrodilution

Table 6 presents the results of MIC and MBC obtained in each composite studied. As shown, no correlation between QD concentration and CMI-CBM was observed in all cases. For example, E. coli present the same MIC to AgQDs although [A] concentration is half of [B] concentration. The same occurs with other microorganisms and metal suggesting that metal concentration is not the only variable that influences the antibacterial activity.

3.6.3. Dead Curve of E. coli

Figure 11 describes the death curve of E. coli in the presence of gold and copper quantum dots at a concentration of 0.1 g/L in 2 g of chitosan (concentration [B]). The results show that E. coli is more sensitive to copper QDs, producing the best bactericidal effect after 16 h of incubation with a reduction of 5 logs ( to ). Conversely, the gold nanoparticles have the major antimicrobial effect after 7 hours of incubation with a slight reduction of 1 log ( to ).

4. Discussion

The size of nanoparticles synthesized ranged between 5 to 10 nm, and for that, we call them quantum dots [21, 22]. According to Shah et al. [10], silver QDs exhibit the antimicrobial effect in very low concentration due to a large active surface area and high surface charge density, compared to silver metal.

With regard to the ED of Au, QDs generally represent a cube octahedral and icosahedral structure and the NPs of Ag and Cu, a mixture of rectangular and cubic structures. When considering the error rate, greater certainty is found in the crystalline nature of the Au and Ag QDs, since there is greater sharpness in the diffraction rings (Figures 2(a) and 2(b)) with respect to Cu’s QDs (Figure 2(c)), so Ag’s QDs would be the ones with the highest cubic crystallinity, followed by Cu’s, while those of Au are entirely icosahedral which could influence the difference in bactericidal activity of QDs against E. coli and S. aureus cultures. The Au QDs having an icosahedral structure have a greater area of contact with the cell wall because this structure has 20 faces compared to the Ag and Cu QDs, which have cubic structure (smaller area). This would lead Au QDs to a greater interaction between the metal structure and the phosphate groups present on the cell surface, or the DNA present in the cell, which would generate a greater biocidal effect on these two pathogens.

When considering the three pathogens in the variance analysis, Ag QDs ([A] and [B]) turn out to be the most biocidal effect on these two pathogens, so more than the crystalline structure of the QDs and electronegativity [23]. It seems that the size of these is what would most influence the biocidal activity because it was shown that Ag has a diameter () approximately twice smaller than Au and Cu ( and , respectively).

The elemental analysis of each composite by means of dispersive X-ray spectroscopy (SEM/EDX) determines that Au QDs, both in concentration [A] and [B], are those with the lowest atomic percentage (0% for those of [A] and 0.06% for [B]) in the surface of the polymer compared to the Ag and CuQDs. This could suppose that Au QDs are absorbed by the polymer and tend to be less likely to oxidize, unlike Cu [B] QD which has the highest percentage (1.59% for [B]) leading to an increased instability and a tendency to agglomeration and oxidation. But to have absolute certainty of the composition of the metals in the polymer, elemental analysis by atomic absorption is required.

As for the results obtained in thermogravimetric methods, it is observed that the thermal degradation of metal QDs supported in chitosan has a lower decomposition temperature than that of pure polymer. This is because the covered metal nanoparticles act as an impurity by lowering the decomposition temperature of the metal, which increases entropy as it is a composite. However, this difference between pure chitosan and doped chitosan QDs is sparse and is within a range of 291-296°C, so QDs do not alter the inherent physical properties of the chitosan itself. MQDs generally decrease Td, because they are incorporated, and increase system entropy. In addition, DSC shows that all QDs undergo the same transition change as chitosan when subjected to heating of 10°C, i.e., they go through a cold crystallization prior to the fusion process.

FT-IR analyses confirm the interaction of gold, silver, and copper QDs due to the M-N (Metal-Amine) groups of the chitosan. A decrease in the absorption wavelength of M-N occurs due to the back bonding of nitrogen electrons into the orbitals of the metal. Due to the presence of the M-M (Metal-Metal) interaction present in the far infrared, it is clear that there is a duality of metal particles, presenting the two forms, oxidized and nonoxidized of metal QDs. This may be because 2-ethoxyethanol is used as a solvent in the stirring stage within the reactor, which can oxidize the supported colloid in the polymer matrix, even if it is dry. According to Mayer et al. [24], MQDs are encapsulated in a sphere of solvation that helps stabilize QDs with subsequent inclusion in the chitosan matrix at the time of synthesis. Also checked in the FT-IR is the M-O (oxygen - OH of the solvent) stretch that is generated in the far range, which determines the interaction of the metal particles with the electron pair of the 2-ethoxyethanol OH functional group, through the M-O bond. In addition, the results show high carbon content present in metals so that the above mentioned by Mayer et al. [24] is met.

In microbial susceptibility tests, both agar diffusion and macro serial dilution show a tendency of a best antimicrobial activity of QDs at concentration [B] against Gram-negative (G(-)) bacteria (E. coli and S. Typhi) and concentration [A] on Gram-positive (G(+)) S. aureus. This may be due to the structure of the cell wall where the G (-) have an outer membrane with lipopolysaccharide (LPS), which is a highly electronegative charge. On the other hand, the teichoic acid present on the surface of G(+) bacteria is less electronegative, which would generate more adsorbed chitosan on Gram-negative bacteria and therefore greater inhibitory effect, which is why according to Chung et al. [25], increased antimicrobial activity is obtained against E. coli culture than in S. aureus.

The lower inhibition zone shown by S. Typhi means that this microorganism was the most resistant to the tested compounds. This result is consistent with macrodilution in broth. This may be due to the chemical composition of the LPS layer, which is composed of sugars such as galactose, glucose, rhamnose, and mannose that form sequences of four or five units that are often branched. This can be an obstacle for the binding of chitosan to fatty acids present in the LPS by an amino ester bond [26]. Another factor that could influence the resistance of this bacteria is its ability to survive at low pH media and the presence of many organic acids [27], and the chitosan-QDs were solubilized in 1% acetic acid.

The low ratio MBC/MIC (1 or 2) observed means that NPs have a predominantly bactericidal behavior [28]. The Ag NPs showed the best antibacterial effect expressed as the lower MIC for the bacterial strains tested. This could be explained because Ag’s NPs are the smallest, which would facilitate their entry into the cell and hence its attack mechanism [29].

A best antibacterial effect was observed in the chitosan-supported metal QDs, compared to nondoped chitosan at 2% (w/v) which means that the combined antibacterial effect of chitosan and QDs had a synergistic effect.

It was also observed that Ag NPs synthesized at a concentration 7.7 M (molar concentration equal to Cu [A] QDs) show statistically different results from MIC to the treatments Ag [A], Ag [B], and Cu[A], so the wrapped metal and concentration are not the only variables that influence bacteriostatic activity.

The results of the death curve of QDs of Au [B]-Qs and Cu [B]-Qs against E. coli show that Cu-QDs has the higher bactericidal activity after 16 h incubation, but after two hours, the effect is similar to the maximum obtained by Au QDs. These differences could be explained by the different action mechanisms of metals, which both interfere with the membrane structure, but copper nanoparticles produce multiple other toxic effects such as reactive oxygen species generation, lipid peroxidation, protein oxidation, and DNA degradation so its lethality is greater [30, 31, 32].

5. Conclusions

Through the synthesis process used in this research (CLD), it was possible to obtain QDs of Au, Ag, and Cu of relatively small size (6.0–10.0 nm on average) and uniform distribution.

The results obtained by UV-Vis and TEM confirm the presence of metals in colloidal suspension.

In the supported metal QDs, SEM with dispersive X-ray spectroscopy (EDX) makes it possible to corroborate the presence of metal clusters supported in chitosan, where the results obtained by the FT-IR method, in the far range, demonstrate that there is an interaction between the supported QDs in chitosan with the polymer matrix.

Thermal methods verify that the nanometals incorporated in the Qs do not lose the inherent thermodynamic properties of the polymer matrix and that these composites are stable up to 250°C.

The QDs of Au, Ag, and Cu obtained by the CLD method, supported in Qs by the SMAD method, and the Qs themselves, have antimicrobial activity and are demonstrated in diffusion assays in agar and in macrodilution in broth against E. coli, S. aureus, and S. Typhi strains, where the concentration, size, and crystalline structure of QDs together with the structure of the cell surface and the age of the culture influence the mentioned activity.

The results show that the MIC and disk diffusion test must be complemented with a death curve because the effect in the time of nanoparticles is quite different although the MIC were similar.

Data Availability

The data and additional material that support this study can be acquired directly in communication with the corresponding author.

Conflicts of Interest

The authors declare that they have no conflict of interest.

Acknowledgments

The authors thank the financial support of Conicyt, Fondecyt Grants 1080704 and 1140025. Thanks are due to Dr. J. Lisperguer for the DSC data.

Supplementary Materials

Supplementary 1. Annex 1 shows the IR spectra of the silver and copper QDs, (Ag [A]-Qs) and (Cu [A]-Qs) respectively.

Supplementary 2. Annex 2 shows the detailed statistical analysis of antibacterial activity.

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Copyright © 2020 Galo Cárdenas-Triviño et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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