Bactericidal Hydrogel Based on Sodium-Carboxymethylcellulose Contained Silver Nanoparticles: Obtaining and Properties


Stable silver nanoparticles in a sodium-carboxymethylcellulose hydrogel with a substitution degree of 0.65 - 0.85 and polymerization degree of 200 - 600 have been synthesized. Physical, chemical properties and antimicrobial activity of sodium-carboxymethylcellulose hydrogels contained silver nanoparticles were studied. The shape, number and size of silver nanoparticles (SNP) incorporated into the structure of hydrogels of sodium-carboxymethylcellulose were studied by using UV-VIS spectroscopy, transmission electron and atomic force microscopy. It was found that the silver nitrate concentration increase in sodium-carboxymethylcellulose solutions, as well as photoirradiation of the hydrogel lead to the changes of the silver nanoparticles size and shape. The studies have shown that the spherical silver nanoparticles of 5 - 35 nm in the structure of sodium-carboxymethylcellulose hydrogel possess high bactericidal activity. Our results have shown that changing of size and shape of silver nanoparticles contributes to appearance of their biological activity.

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Ergashovich, Y. , Abdukhalilovich, S. and Sharaphovna, R. (2018) Bactericidal Hydrogel Based on Sodium-Carboxymethylcellulose Contained Silver Nanoparticles: Obtaining and Properties. Open Journal of Polymer Chemistry, 8, 57-69. doi: 10.4236/ojpchem.2018.84006.

1. Introduction

Metal-polymeric hydrogels based on polyelectrolytes contained silver nanoparticles show perspective ability to application them in the medical practice as bactericidal and bacteriostatic soft coatings for the treatment of burns and wounds [1] .

Bactericidal metal-polymeric hydrogels for the treatment of burns and wounds must correspond to following requirements:

- should be prepared from non-toxic polymers which have prolong effect, good isolating and anti-microbial influence, sufficient air and vapor penetrability, and ability to prevent wound and burns from liquid evaporation; hydrogels should be transparent in order to control process of wound healing without removing a covering agent.

- hydrogels should hermetically cover the wounds or burns surface to protect the aggregation of exudate; hydrogels should be easily taken off the wound surface, washing painless with water and contain thixotropic agent preventing from dryness; hydrogels must be biodegradable, the time of complete resorption should be simultaneous with the time of wound healing; they should have a limited absorption capacity without changing the structure, and promote the formation of new epithelium [2] [3] .

The goal of the present work is the formation of stable silver nanoparticles in the polymer based on sodium-carboxymethylcellulose (Na-CMC) hydrogels and study their structure, physicochemical properties and bactericidal activity.

2. Experimental

2.1. Materials and Methods

Purified Na-CMC with degree of substitution (DS) = 0.65 - 0.85 and degree of polymerization (DP) = 200 - 600 obtained from cotton cellulose (CC) was used as a polymeric matrix. An aqueous solution of silver nitrate (GOST 1277-75 Reagents AgNO3, Specifications) was used for the formation of silver nanoparticles in the structure of Na-CMC hydrogel.

2.2. Synthesis of Silver Nanoparticles

For the obtaining Na-CMC hydrogels 2% - 4% aqueous solutions of purified Na-CMC samples with various DS and DP were selected after removal of gel fraction on a laboratory centrifuge MLW-T23 (Hungary) at 6000 rpm for 20 minutes.

An aqueous solution of AgNO3 with calculated concentrations of 0.1 - 0.01 M was added under stirring to Na-CMC solutions free of gel fraction, and stirring was continued until a homogeneous Ag+CMC hydrogel formation. Photochemical restoration of silver ions to nanoparticles in the structure of Ag+CMC was performed at 25˚C using a high pressure mercury lamp DRSh 250-3, λ = 365 nm (Russia).

2.3. Physicochemical Methods of Investigation

For the obtaining of Na-CMC hydrogel contained dispersed silver nanoparticles an ultrasonic disperser USDN-1, U-4.2, 44 kHz (Russia) was used. Viscosity of Na-CMC and Ag+CMC solutions was determined on a glass capillary viscometer VPJ-2 with capillary diameter 0.56 mm.

The optical absorption spectra of hydrogels were recorded on a Specord M210 UV-Vis spectrophotometer (Germany) at the wavelength range from 200 to 900 nm. The length of optical channels was 2 mm. The morphology of the nanometal-polymer surface layers was studied using a transmission electron microscope TEM-100 (Ukraine) and an atomic-force microscope AFM-5500 (Austria) in films obtained from hydrogels of Na-CMC, Ag+CMC and Ag0CMC. The distribution of metal particles in polymer matrix by size, and the variation coefficient was determined by the calculation of the corresponding photomicrographs in MathCad program.

2.4. Determination of Bactericidal Activity

For the testing of bacterial activity of hydrogels the pathogen microorganisms Staphylococcus epidermidis and Candida albicans were used. The following samples were added to test-tubes containing Thioglycollic medium (for Staphylococcus epidermidis) and Saburo (for Candida albicans): 1) Control Na-CMC hydrogel; 2) Na-CMC hydrogel contained Ag+, C Ag + = 0.025 wt.%; 3) Na-CMC hydrogel contained Ag0, C Ag 0 = 0.025 wt.%; 4) Na-CMC hydrogel contained Ag0, C Ag 0 = 0.25 wt.%; 5) Na-CMC hydrogel contained Ag0, C Ag 0 = 2.5 wt.%.

10% NaCl solution in the same medium was used as a control. Within six hours, the final concentration of 150 cells/ml test culture was added in each test-tube. Samples were incubated at 34˚C during 48 hours (for Staphylococcus epidermidis) and 72 h (for Candida albicans).

3. Results and Discussion

Solubility and purity degree are the most important physicochemical characteristics of Na-CMC that determine possibility of their application in some products. We investigated the composition of water-soluble and insoluble fractions of purified Na-CMC samples with different DS and DP.

As seen from Table 1, with increasing DS, a part of soluble Na-CMC fraction in water is increased, and content of insoluble gel fraction is decreased. With increasing DS, part of gel fraction of Na-CMC in water decreases.

Probably, it occurs due to the decreasing of hydrogen bonds intensity between the macromolecules and an increasing of DS in Na-CMC. Moreover, the composition and properties of Na-CMC gel fraction depend on the type of cellulose raw material and methods of Na-CMC obtaining.

It was found that the content of gel fraction in Na-CMC samples of cotton pulp in all DP and DS intervals is more than those of Na-CMC sample 4 (Table 1). This could be explained by high DS of Na-CMC. The above-described investigation provided a polymeric matrix for the Na-CMC hydrogel contained ions and silver nanoparticles.

Further studies were aimed at the formation and stabilization of silver ions and nanoparticles in Na-CMC polymer base and study their properties. Aqueous

Table 1. Effects of DS and DP of Na-CMC samples on quantity and composition of water-soluble and insoluble fractions.

solutions of Na-CMC exhibited the properties of polyelectrolyte. Derivatives of Na-CMC with alkali metal ions such as Na+, K+, NH 4 + are quickly soluble in water [4] .

Na-CMC compounds with polyvalent metals such as calcium, magnesium, copper, lead, and zirconium are insoluble in water due to the intermolecular cross-linking, and they form stable hydrogels. Sediment gel forms by aluminum ions addition to Na-CMC solution [5] . Table 2 shows the characteristics of Na-CMC samples with different DS and DP contained different amounts of silver ions.

We have studied the conditions and the replacement of sodium ions by silver ions in Na-CMC solutions. It was determined that when Na+-ions in Na-CMC with DS 0.65; 0.69; 0.85; 0.88 replaced by 0.35; 0.4; 0.5 and 0.6 mol% ions of Ag+, a stable Ag+CMC hydrogel bad soluble in water is formed, in opposite to alkali metal salts of Na-CMC. Apparently, carboxyl groups of Na-CMC are able form a complex ion with ions of silver [6] .

The limits of Ag+CMC hydrogels formation defined as the content of silver ions and the molecular parameters of Na-CMC are presented in the Table 2. With increasing of Na-CMC DS, the concentration of silver ions necessary for the formation of bad soluble in water Ag+CMC hydrogel is increased.

Numerous studies have shown that silver nanoparticle contained materials possess a good antimicrobial and wound healing properties [7] . Therefore, we have studied the conditions of obtaining Ag+CMC hydrogels contained stabilized silver nanoparticles by using photochemical methods [8] . Comparison of different methods of silver ions reduction to nanometallic state has shown that the photochemical reduction is the most effective to control the size of nanoparticles and obtain products pure of the reducing agent transformation products [9] .

Stable nanoparticles synthesized by photochemical method have a narrow distribution in particle sizes and high stability in an aqueous medium (chemical reduction, high-frequency electric discharge, ultrasonic dispersing, and the condensation of metal vapors) being used as matrix ionic polymer solution that simultaneously function as nanoparticle stabilizing agent, in compare to colloidal

Table 2. Physicochemical characteristics of Na-CMC containing silver ions.

systems obtained by traditional method. Photochemical method makes possible the management of process in-time and in-site, as distinct from the chemical methods applying thermodynamically and kinetically unstable systems [10] .

It is known that the formation of colloidal silver particles in prolonged photon irradiation above the band-gap is the basis of the photographic process in silver halides. This electron-stimulated process of colloidal particles formation has been explained by the Mott-Gurney theory [11] [12] . During photochemical reduction, the optically generated electron migrates and catches with the electron catcher at the bedding interface and near the surface. The negative charge attracts one of interstitial Ag+ ions presented in thermodynamic equilibrium which move to the trapped electron. This is the first step in the sequence of the electrons and interstitial atoms trapping and formation of silver clusters and nanoparticles as a basis of latent image.

Analyzing spectroscopic data of based on silver nanoparticles and Na-CMC nanocomposites, it may suppose that the negative ion in carboxymethyl group is “a trap” for the positively charged silver ion [12] .

Then, the reaction sequence on the mechanism of the Mott-Gurney will be as follow:

Thus, the photostimulated formation of silver nanoparticles in the Ag+CMC hydrogel can be considered as electron-stimulated nuclear process that may be based on Mott-Gurney theory [11] as the photography process.

To confirm this assumption, spectra of Na-CMC, Ag+CMC, and Ag0CMC were taken. After UV-irradiation, Na-CMC solutions containing silver ions formed enough stable colloidal systems of nanosilver of pale-yellow color with maximum at λmax = 416 nm attributed to silver nanoparticles of 5 - 25 nm [12] (Figure 1, curve-3).

No changes were observed in the spectra of initial Na-CMC solutions (Figure 1, curve-1) and no unreduced silver ions in Ag+CMC (Figure 1, curve-2) at 250 - 900 nm.

With increasing the time of photolysis the color of solutions is changed from pale yellow to brown. According to the literature [12] , such changes are probably depended on the increased quantity and size of silver nanoparticles.

To confirm this assumption, absorption spectra were taken at the different periods of irradiation of Ag+CMC systems at Na-CMC concentration of 0.008 mol (2%) and silver nitrate of 3 × 10−5 mol. Figure 2 shows the UV-spectrum of Na-CMC hydrogel contained silver nanoparticles which obtained at different photo irradiation periods.

As can be seen in Figure 2., the shoulder at the region λmax = 270 nm had been observed in the spectrum (Figure 2, curve-2) in 5 minutes of photo irradiation which could be attributed to stable polyanion charged silver clusters, approximately Ag 8 2 + [12] [13] .

In 15 and 20 minutes of photolysis, increasing of the absorption band intensity at λmax = 270 nm (Figure 2, curves-2, 3) had been observed at the spectrum which depends on formation of large stabilized clusters of silver with sizes 2 - 8 nm, and λmax = 420 nm (Figure 2, curve-4) attributed to the larger silver nanoparticles with sizes of 5 - 35 nm [13] .

Further irradiation till 60 minutes led to the appearance of absorption bands with maxima at regions λmax = 290 nm and λmax = 420 nm (Figure 2, curve-5) is due to increasing of the number of larger clusters and silver nanoparticles of 5 - 35 nm [13] .

In addition, a weak maximum in the near-IR region of the spectrum in λmax = 850 nm (Figure 2, curve-5) is observed owing to exclusively rod-shaped silver nanoparticles [13] .

Figure 1. UV-VIS absorption spectra of the samples: 1) Na-CMC, 2) Ag+CMC, 3) Ag0CMC. Time of UV-irradiation for samples was 25 min; [Na-CMC] = 0.008 mol (2%); [AgNO3] = 3 × 105 mol (0.25 wt.%).

Figure 2. UV-VIS absorption spectra of photochemical reduction of silver ions in Ag+CMC samples. Concentration of [Na-CMC] = 0.008 mol (2%); and [AgNO3] = 3 × 105 mol (0.25 wt.%). Period of UV-irradiation 0 (1), 5 (2), 15 (3), 20 (4), and 60 (5).

For the purpose of shapes and sizes of silver nanoparticles determination in Na-CMC structure the obtained samples were investigate on a TEM microscope. Impact time of UV-irradiation to changing the sizes and shapes of silver nanoparticles are presented in Figure 3.

It was established that at UV-irradiation of samples in 15 minutes spherical silver nanoparticles with the sizes from 2 - 20 nm till 5 - 35 nm (Figure 3(a), Figure 3(b)) are formed. At further UV-irradiation till 60 minutes the spherical nanoparticles turn into bigger with sizes 50 - 100 nm (Figure 3(c)) due to a simultaneous restoration of silver ions bound to carboxyl anions in Na-CMC structure and free silver ions. These processes proceed with different speed and lead to increase of polydispersion and nanoparticles shape changing.

Figure 3. AFM microphotograph of Na-CMC hydrogel contained SNP (a), (b), (c) and their histograms. Concentration of [Na-CMC] = 8 × 10−3 mol (2%); [AgNO3] = 3 × 10−5 mol (0.25 wt.%). Time of UV-irradiations 20 min. (a); 30 min. (b); 60 min. (c).

In the next step we studied impact of silver ions concentration to changing size and form of silver nanoparticles in Na-CMC hydrogel. Transmission electron microscopy investigation of Ag+CMC metal complexes of contained silver nanoparticles was carried out (Figure 4).

TEM images are shown, that at low concentrations (0.025 wt.% and 0.25 wt.%) AgNO3 formed spherical silver nanoparticles with sizes of 0.65 - 8 nm (Figure 4(b)) and 2 - 30 nm (Figure 4(c)). With increasing of AgNO3 concentration in Na-CMC hydrogel up to 2.5 wt.%, nanoparticles become rod-shape with l = 40 - 120 nm and d = 5 - 60 nm (Figure 4(d)).

The mechanism of rod-like shaped silver nanoparticle formation in these conditions is still unclear [14] . Thus, the size and shape of silver nanoparticles formed in Ag+CMC hydrogels by photochemical reduction of silver ions depend on DS, concentration of Na-CMC solution, concentration of Ag+, and time of photochemical irradiation. In the presence of Na-CMC the macroanions effectively bind Ag+-ions, and the UV reduction led to the successive formation of clusters and nanosilver depending on the concentration of silver ions.

Decrease of the carboxymethyl anions relative content caused by lowering of the reaction medium pH calls a dramatic decrease in the efficiency of silver ions binding after their UV-irradiation because of their aggregation with the formation of silver nanorods. It could be explained by the increasing of silver ions concentration in CMC structure with simultaneous restoration of silver ions bound to carboxylate anion of Na-CMC (nanoreactor) [10] and free silver ions. These processes carry out with different speeds and lead to polydispersity of formed nanoparticles.

Increase of particle sizes, their aggregation and change of spherical shape suggest that the macromolecular envelope forming in decrease of concentration of Ag+CMC complexes, essentially being centers of photoreduction and subsequent growth of nanoparticles, becomes less solid. At that, the growth, coagulation, and possibly, coalescence of particles continue.

Figure 4. TEM micrographs of Na-CMC hydrogel contained silver nanoparticles. (a) pure Na-CMC soluteon; (b) Na-CMC:AgNO3 (0.08:3 × 106 mol) 0.025 wt.% AgNO3; (с) Na-CMC:AgNO3(0.08:3 × 105 mol) 0.25 wt.% AgNO3, with spherical structure of silver nanoparticles; (d) Na-CMC:AgNO3 (0.08:3 × 104 mol) 2.5 wt.% AgNO3 rod-shape structure of silver nanoparticles.

The homogeneity of nanoparticle sizes is reach due to formation of the Na-CMC macromolecule charged envelopes that cover silver nanoparticles and prevent their aggregation. Increasing of Na-CMC local concentration, by one hand, provides an electrostatic and steric stabilization of silver nanoparticles, and, by other hand, creates conditions in which the complete removal of radicals interaction in UV-photolysis of Ag+CMC is impossible. To evaluate stability of the silver nanoparticles formed in Na-CMC hydrogels, the UV spectra of Na-CMC hydrogels contained silver nanoparticles (Figure 5(a), Figure 5(b)) kept for the different time periods were taken.

As it can be seen from Figure 5(b), the shape and content of silver nanoparticles in Na-CMC hydrogels during prolonged keeping under 25˚C did not change. Basing on the experimental results, we can conclude that, depending on the molecular weight, degree of substitution, the ratio of Na-CMC and AgNO3, and the reaction conditions, the size and shape of silver nanoparticles formed in Na-CMC hydrogels by the photochemical reduction can be controlled.

The following conditions of homogeneous silver nanoparticles formation were chosen:

Time of UV-irradiation 30 minutes; content of Na-CMC in solution 0.008 mol; content of AgNO3 in solution 3 × 10−5 mol. Spherical silver nanoparticles of 5 - 35 nm formed in hydrogel at the selected conditions. Stabled shape and size of silver nanoparticles in the Na-CMC hydrogel structure in long keeping confirms the important role of the chosen polymer matrix stabilization.

The biological activity of silver nanoparticles formed in Na-CMC hydrogels were investigated on Staphylococcus epidermidis and Candida albicans strains.

Figure 5. UV-absorption spectra of Na-CMC hydrogels contained silver nanoparticles at the different time periods. Time of UV irradiation is 30 min. Concentration of AgNO3 is 0.25 wt.%. (a) The absorption spectra taken after hydrogels obtaining; (b) The absorption spectra of hydrogels after one month. (c) The absorption spectra of hydrogels after six months.

2% Na-CMC hydrogel was selected as a control, an aqueous solution of silver nitrate, 2% Ag+CMC hydrogel, and Na-CMC hydrogel contained silver nanoparticles were taken as test objects. Microbiological investigations of the above samples were carried out using method [15] . Results of investigation presented in Table 3.

As shown in Table 3, the control sample 2% Na-CMC hydrogel has no antimicrobial activity of the polymeric matrix in both microorganism strains. An aqueous solution of AgNO3 exhibited bacteriostatic activity against Staphylococcus epidermidis, but no activity against Candida albicans.

Silver ions contained Na-CMC hydrogel exhibited bacteriostatic activity against Staphylococcus epidermidis at 30% higher than the water solution of silver nitrate at the similar concentration. It doesn’t show antimicrobial activity against Candida albicans.

The relatively high activity of the silver ions in the structure of Na-CMC against free silver nitrate ions because silver nitrate ions of their high movability in aqueous solutions and quickly connects with functional groups on the surface strains as Staphylococcus epidermidis and fungus Candida albicans. The silver ions being in the structure of Na-CMC hydrogel have limited mobility and keep the biological activity for a long time.

In the examination Na-CMC hydrogel, contained silver nanoparticles was found that they are active anti strains of Staphylococcus epidermidis for three times higher than an aqueous solution silver nitrate, and exhibit a high bactericidal activity against fungi Candida albicans, this evidence by the absence of fungal growth medium.

The relatively high antimicrobial activity of silver nanoparticles in compare with silver ions may be caused by:

- Inability of silver nanoparticles make chemical bonds with the functional groups on the surface of Staphylococcus epidermidis and Candida albicans cells, and, probably, by their ability to penetrate into the nucleus of cells and inhibit their growth and activity [16] ;

- Lowering of the silver nanoparticle sizes lead to increasing of the total surface area and acceleration of their contact and penetration into the both strains cell nucleus ability;

- Increasing of nanoparticle sizes and changing of their shape from spherical to rod-shaped, on the one hand, bring to fast decrease of total surface area, and, on the other hand, to limited ability of entering into the cell nucleus of Staphylococcus epidermidis and Candida albicans strains.

Comparative antimicrobial activity of silver nanoparticles with different sizes and shapes are presented in Table 4. Na-CMC hydrogels containing silver nanoparticles with spherical structures and sizes 5 - 35 nm showed a highest activity against Staphylococcus epidermidis and Candida albicans due to high values of their surface area and ability to penetrate into the cell nucleus [16] [17] . Na-CMC hydrogel contained rod-shape silver nanoparticles with l = 50 - 140 nm and d = 15 - 40 nm was less active than hydrogels contained silver nanoparticles with spherical structure, but they are more active in compare to Na-CMC hydrogel contained silver ions.

Table 3. Comparative results of investigation of the bactericidal activity of Na-CMC hydrogels contained silver ions and silver nanoparticles.

Note. Colony of forming unit CFU/ml―a unit of measurement is the number of colony forming units per milliliter of fluid.

Table 4. Comparative results of the antimicrobial activity of Na-CMC hydrogel contained silver nanoparticles of different shapes and sizes.

In addition, Na-CMC hydrogel containing 2 - 20 nm silver nanoparticles was proved to be less active than other hydrogels. This result may be explained by the fact that the total content of silver nanoparticles in such Na-CMC hydrogel turned out to be almost an order of magnitude less than in the samples of hydrogel containing 5 - 35 nm (spherical) and rod-shaped nanoparticles of silver.

4. Conclusions

Optimal conditions of silver nanoparticles with different shapes and sizes formation in the structure of Na-CMC hydrogels of different DS and DP were determined by the photoirradiation of hydrogels.

It was established that the replaced silver ions in Na-CMC macromolecules mainly subject to restoration and play the role of in which the carboxylic groups of a negative ion, according to the theory of Mott-Gurney, are the for positively charged ions of silver and promote the photostimulated formation of silver nanoparticles. UV-spectroscopic method for control of the form and sizes of silver nanoparticles at process of their restoration is developed.

It was established that depending on concentration of polymeric substrate, silver ions and UV-irradiation, spherical and rod-like stabilized silver nanoparticles of different sizes form in the structure of Na-CMC. The conditions of the formation of silver nanoparticles with different shape and size in dependence of components interaction reaction parameters and photochemical restoration were revealed.

Correlation dependence between the size and shape of silver nanoparticles in Na-CMC structure and their biological activity was established. It was shown that size of the silver nanoparticles decreasing promotes the increase of their antimicrobial activity at the same concentrations in polymeric matrix. The prepared biodegradable Na-CMC hydrogels contained silver nanoparticles are of interest as bactericidal and bacteriostatic covering agents for the treatment of burns and trophic ulcers.


This work was supported by the grants of Committee for Science and technology of Uzbekistan FА-А-13-Т011 < > and YА-12-2 < >. The authors would like to thank to Rashidova Sayora Sharaphovna, the Honoured Worker of Science of Republic Uzbekistan, Doctor of Chemical science, professor, academician of Academy of Sciences of RUz for giving direction and advice, and to the Laboratory of Physical-chemical Analysis for assistance in physical-chemical investigations and measurement of samples.

Conflicts of Interest

The authors declare no conflicts of interest.


[1] Sherbakov, A.B., et al. (2006) Silver Preparations: Yesterday, Today and Tomorrow. Pharmaceutical Journal, 5, 45-57.
[2] Antonov, S.F., Paramonov, B.A., Drobitsa, V.P., Ribalchenko, O.V. and Shlyakov, A.M. (2008) Biocompatible Structures Containing Silver Nanoclusters and Their Use for the Treatment of Burns and Ulcers: Safety Study of Bioactivity. International Nanotechnology Forum, Moscow, Vol. 1, 134-135.
[3] Semkina, O.A., Javakhyan, M.A., Liauchuk, T.A., et al. (2005) Excipients Used in the Art Dosage Forms (Ointments, Gels, Liniments, Creams). Chemical-Pharmaceutical Journal: Scientific and Technical Trade Journal, 39, 45-48.
[4] Rogovin, Z.A. (1972) Cellulose Chemistry. Publishing “Chemistry”, Moscow.
[5] Sarymsakov, A.A. (2005) Medium- and Low-Substituted Carboxymethyl Cellulose—Preparation, Properties and Applications. Book, Tashkent.
[6] Pyatnitskiy, I.V. and Suchan, V.V. (1975) Analytical Chemistry of Silver. Nauka, Moscow. 264 p.
[7] Chen, D., Xi, T. and Bai, J. (2007) Biological Effects Induced by Nanosilver Particles: In Vivo Study. Biomedical Materials, 3, 126-128.
[8] Courrol, L.C. (2007) A Simple Method to Synthesize Silver Nanoparticles by Photo-Reduction. Lilia Coronato Courrol, Flravia Rodrigues de Oliveira Silva, Larercio Gomes. EPUSP, 18, 12-16.
[9] Loginov, A.V., Gorbunova, V.V. and Boysova, T.B. (1997) Methods for Preparation of Metal Colloids. Journal General Chemistry, 6, 189-200.
[10] Yunusov, K.E., Sarymsakov, A.A., Atakhanov, A.A., Ashurov N.S. and Rashidova S.S. (2011) Physicochemical Studies of Cotton Cellulose and Its Derivatives Containing Silver Nanoparticles. Chemistry of Natural Compounds, 47, 370-373.
[11] Mott, N.F. and Gurney, R.W. (1940) Electronic Processes in Ionic Crystals. Oxford University Press, New York City.
[12] Oksigenler, B.L., Turaeva, N.N., Yunusov, K.E., Sarymsakov, A.A. and Rashidova, S.S. (2009) The Mechanism of the Influence of Ultraviolet Radiation on the Growing and Properties of Silver Nanoparticles in the Polymer Solutions. Book of Abstracts, Tashkent, 82-85.
[13] Kreibig, U. and Vollmer, M. (1995) Optical Properties of Metal Clusters. Springer, Berlin.
[14] Sergeev, B.M., Kiryuhin, M.V., Prusov, A.N. and Sergeyev, V.G. (1999) Preparation of Silver Nanoparticles in Aqueous Solution of Polyacrylic Acid. Bulletin of Moscow State University, Series of Chemistry I, 40, 129-133.
[15] Mirzoeva, A.E. (2002) Methods for General Bacteriology. Moscow.
[16] Shahverdi, A.R., Fakhimi, A., Shahverdi, H.R. and Minaian, S. (2007) Synthesis and Effect of Silver Nanoparticles on the Antibacterial Activity of Different Antibiotics against Staphylococcus Aureus and Escherichia Coli. Nanomedicine, 3, 168-171.
[17] Yunusov, K.E., Sarymsakov, A.A. and Rashidova, S.S. (2014) Structure and Properties of Biodegradable Carboxymethyl Cellulose Films Containing Silver Nanoparticles. Polymer Science: Series A, 56, 276-281.

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