Mycosynthesis,characterization and antibacterial properties of AgNPs against multidrug resistant (MDR)bacterial pathogens of female infertility cases
2015-05-16PonnusamyManogaranGopinath,GanesanNarchonai,DharumaduraiDhanasekaran等
Mycosynthesis,characterization and antibacterial properties of AgNPs against multidrug resistant (MDR)bacterial pathogens of female infertility cases
Ponnusamy Manogaran Gopinath,Ganesan Narchonai, Dharumadurai Dhanasekaran*,Anandan Ranjani,Nooruddin Thajuddin
Department of Microbiology,School of Life Sciences,Bharathidasan University,Tiruchirappalli 620 024,India
ARTICLEINFO
Article history:
Received 29 March 2014
Received in revised form
15 July 2014
Accepted 7 August 2014
Available online 27 August 2014
Multidrug resistance
A Recently,biosynthesis of silver nanoparticles using bacteria,fungus and plants has emerged as a simple and viable alternative to more complex physical and chemical synthetic procedures.The present investigation explains rapid and extracellular synthesis of silver nanoparticles using fungus Fusarium oxysporum NGD and characterization of the synthesized silver nanoparticles using UV-Vis spectroscopy,scanning electron microscopy, energy dispersive spectroscopy and X-ray diffraction analysis.The size range of the synthesized silver nanoparticles was around 16.3-70 nm.The FTIR studies showed major peaks of proteins involved in the synthesis of silver nanoparticles.Further,antibacterial effect of the silver nanoparticles against multidrug resistant pathogens Enterobacter sp.ANT 02[HM803168],Pseudomonas aeruginosa ANT 04[HM803170],Klebsiella pneumoniae ANT 03[HM803169]and Escherichia coli ANT 01[HM803167]was tested using turbidometric assay at 10,20,30,40 μg AgNPs/ml alone and in combination with ampicillin using agar well diffusion assay.All the resistant bacteria were found to be susceptible to the antibiotic in the presence of the silver nanoparticles.
©2015 Shenyang Pharmaceutical University.Production and hosting by Elsevier B.V.All rights reserved.
1. Introduction
Infectious agents can impair several essential human functions,including reproduction.Microbes can interfere with thereproductive function in both sexes.Especially,bacterial infections have long been recognized in association with female infertility[1,2].Indeed,the treatment of bacterial infections is increasingly complicated because of their ability to developresistance to antimicrobial agents.This resulted in severe debilitating and even life-threatening local and systemic infections,thus demanding the search for new antibacterial agents[3].
Presently,nanoscale materials have emerged as novel antimicrobial agents owing to their high surface area to volume ratio and their unique chemical and physical properties [4,5].Metal nanoparticles such as copper,zinc,titanium[6], magnesium,gold[7],and silver[8,9]have proved to be effective against a range of bacteria,viruses and eukaryotic microorganisms[10].Speci fi cally in the case of silver,the broad spectrum antimicrobialactivity encouragesitsuse in biomedical application,water and air puri fi cation,food production,cosmetics,clothing and numerous household products[11].
Metalnanoparticles havebeenstudiedextensively because of their exclusive catalytic,optical,electronic,magnetic and antimicrobial properties[12,13].Recent studies have shown that nanoparticles-based antimicrobial formulations could act as an effective bactericidal material[14].Therefore a lot of research has been directed in fi nding out an inexpensive and environmental friendly method for nanoparticle synthesis.In accordance to the above,the present study is to synthesize silver nanoparticle using a soil fungus,and assess its antibacterial activity alone and in combination with ampicillin against multidrug resistant bacterial pathogens of female infertility cases.
2. Materials and methods
2.1. Collection of microbial strains
Multidrug resistant bacterial isolates of female infertility cases(Enterobacter sp.ANT 02[HM803168],Pseudomonas aeruginosa ANT 04[HM803170],Klebsiella pneumoniae ANT 03 [HM803169]and Escherichia coli ANT 01[HM803167])were obtained from the Germplasm,Department of Microbiology, Bharathidasan University,Tiruchirappalli,India and maintained on nutrient agar slants.The isolates were tested against various groups of antibiotics in clinical practice to determine their antibiotic resistance[3].The fungus Fusarium oxysporum NGD was also obtained from the Germplasm.
2.2. Preliminary screening of soil fungi for nanoparticle synthesis
F.oxysporum NGD was cultured in 250 ml of sabouraud dextrose broth(SDB)at 28±2°C for 7 days at 200 rpm(pH-6.5). After incubation,the biomass was separated by fi ltration and washed in sterile distilled water to remove any medium components.The separated biomass(20 g)was then introduced into 200 ml of sterile distilled water and incubated for 3 days.After 3 days of incubation the clear cell free extract was collected by fi ltration and was used for nanoparticle synthesis.50 ml of AgNO3solution(1 mM fi nal concentration)was challenged with 50 ml of cell fi ltrate in a 250 ml Erlenmeyer conical fl ask and stirred constantly for 30 min.Control (without silver ions)was run along with the experimental fl asks.The ability of the fungito synthesize silver nanoparticles was determined visually based on change in colour of the reaction mixture[9,12].
2.3. Characterization of AgNPs
Since rapid reduction of silver ions in F.oxysporum NGD cell fi ltratewasnoticedvisiblythroughgradualchangeinthecolour of the fi ltrate,the reaction mixture was subjected to optical measurements using an UV-Vis spectrophotometer scanning range between 250 and 800 nm at the resolution of 1 nm. Scanning electron microscope(JEOL Model JSM-6390 LV)with secondary electron detectors at an operating voltage of 20 kV was used to record the images of synthesized AgNPs(dry powder).Energy-dispersive X-ray(EDX)spectroscopy analysis for the con fi rmation of elemental silver was carried out using Thermo Noran EDSattachmentequipped with SEM,JEOLModel JSM-6390LV.The size and the morphology of the AgNPs were examined using atomic force microscope(di CP-II Veeco USA). The dried powder of silver nanoparticles was used for X-ray diffraction(XRD)analysis.XRDpatternswererecordedonX'Pert Pro,PANaltyical,USA operating at 40 kV and a current of 30 mA withCuKaradiation(1=1.54A°).Thediffractedintensitieswere recordedfrom30to752θangles.FTIRspectrumofthesynthesis mixture was recorded on a PerkinElmer 1600 instrument in the range 400-4000 cm-1at a resolution of 4 cm-1.
2.4. Antibacterial activity of AgNPs against multidrug resistant pathogens
2.4.1. Preparation of MDR bacterial cultures
The MDR Enterobacter sp.,P.aeruginosa,K.pneumoniae and E. coli were inoculated in sterile Luria Bertani broth(LB)and the broth was incubated at 37°C for 18 h.
2.4.2. Antibacterial activity of AgNPs
Effect of AgNPs on bacterial growth was determined in broth culture.To 50 ml LB broth,100 μl of bacterial culture was added,followed by the addition of silver nanoparticles suspensionrangingfrom 10to 40μg/mlforeach testorganism.All the fl asks were incubated at 37°C.Growth of Enterobacter sp., P.aeruginosa,E.coli and K.pneumoniae was indexed by measuring the optical density(OD)at λ=620 nm at regular intervals in UV-Vis spectrophotometer.The control was treated in a similar fashion without silver nanoparticles.The average triplicate value of growth curve was plotted between optical density and time.
2.5. Effect of AgNP-ampicillin mixture on MDR bacteria
The antibacterial activity of AgNPs in combination with ampicillin(10 μg/ml)was investigated by agar well diffusion method.Muller Hinton agar plates were inoculated separately with bacterial cultures namely Enterobacter sp.,P.aeruginosa,E. coli and K.pneumoniae at a concentration of 10-4to 10-5CFU/ ml using a sterile cotton swab and three wells(6 mm dia)were punched in each plate using sterile cork borer.100 μl each of ampicillin(10 μg/ml),silver nanoparticle suspension(20 μg/ ml)and mixture of AgNPs and ampicillin were added to agar wells.The plates were incubated at 37°C for 24 h and theantibacterial activity was measured as zone of inhibition.This procedure was repeated thrice.
3. Results and discussion
3.1. Synthesis and characterization of silver nanoparticles using F.oxysporum NGD
The fungus F.oxysporum NGD showed rapid colour change in less than a minute and the colour intensity increased with time and became dark brown within 30 min.Appearance of brown colour is due to the surface plasmon resonance of silver nanoparticles.With the addition of AgNO3solution,the crude cell fi ltrate of F.oxysporum NGD changed from light yellow to brown within 3-7 min,whereas the control showed no colour change under the same experimental conditions (Fig.1).Thus the colour change of the reaction mixture clearly indicates the formation of AgNPs.Further the colour intensity of the reaction sustained even after 24 h of incubation,indicating that the particles were well dispersed in the aqueous medium,and there was no obvious aggregation [9,12].
Bioreduction of silver ions into nanoparticles was further con fi rmed by spectrophotometric analysis.The UV absorption spectra of silver nanoparticles at different time intervals are presented in Fig.2A.A surface plasmon absorption band with a maximum at 425 nm,indicate the presence of spherical or roughly spherical AgNPs.The position and shape of the plasmon absorption depends on the particles,size and shape,and dielectric constant of the surrounding medium[15].Absorption band at 425 nm rapidly increased initially in 15 min time interval,later reaching a plateau phase after 30 min(Fig.2B), which indicated that the synthesis was completed within 30 min of incubation[16].
Extracellular synthesis of silver nanoparticles by cell free fi ltrates of Aspergillus terreus[17],F.oxysporum[18],Fusarium acuminatum[13],Penicillium fellatum[19],Phytophthora infestans [20],Alternaria alternata[21],Agaricus bisporus[22]and Biopolarisnodulosa[23]has beendemonstrated.Though theactual mechanism involved in AgNP synthesis has not been worked out in this study,according to the earlier reports several proteins,free amino acids and NADH-dependent reductases[18] secreted by the fungus is responsible for the synthesis of nanoparticles.It could be noticed that in all the previous reports the reaction mixtures required 24 h-48 h for the reduction of the silver ions in the aqueous solution into nanoparticles.In the present study,the synthesis process initiated in few min and completed within 30 min.Therefore, this is the fi rst report on shortest time required to generate silver nanoparticles using fungi.
The SEM micrographs of silver nanoparticles(5 mg)(Fig.3) were roughly spherical to oval in nature with a little aggregation.The aggregation of AgNPs occurred during drying process(lyophilization)which is required for XRD analysis as well as for antibacterial studies.Ultra sonication technique was employed to separate the aggregated particles prior to antibacterial studies.EDS analysis provided additional evidence for the reduction of silver ions to nanoparticles.The optical absorption peak(Fig.4)approximately at 3 keV is typical for the metallic silver nanocrystals[24].Throughout the scanning range of binding energies,no peak belonging to impurity was detected.The results indicated that the reaction product was composed of highly pure Ag nanoparticles.The spectrum shows strong signal for Ag along with weak oxygen and carbon peak,which may be originated from the biomolecules bound to the surface of silver nanoparticles.The topological images of the AgNPs are shown in Fig.5.The depth image of atomic force microscopy(AFM)(Fig.5B)shows the spherical arrangement of silver nanoparticles within the diameter range of 6.3-12.67 nm.The XRD pattern of silver nanoparticles were compared and interpreted with standard data of International Centre of Diffraction Data(ICDD).Three characteristic peaks for silver nanoparticles appeared at 38.1°, 44.3°and 64.4°2θ angle(Fig.6)which corresponds to energetically distinct sites based on atom density.It suggests that the prepared silver nanoparticles are biphasic in nature.The size range of the nanoparticles was calculated using Scherrer formula(D=0.94 λ/β Cosθ)which was foundto be 16.3-70 nm. The variation in the nanoparticles size range in AFM and XRD studies may due to the aggregation of particles in lyophilisation process.
The functional groups mainly involved in the reduction of Ag+ions were predicted using FTIR spectroscopy(Fig.7).The absorption peaks of F.oxysporum cell fi ltrate(Fig.7B)located at 1092,1164,1240,1412,1630,2464,2572,2676 and 2778 cm-1in the regionof 500-3000cm-1areeitherred shiftedor increased or diminished in the spectrum of the synthesis mixture containing cell fi ltrate and AgNO3(Fig.7C).The distinct band at 1630 cm-1is assigned to the-NH2group[25]and the band intensity increased and shifted to 1636 cm-1,which indicates the formation of-NH3+groups due to the complexation of amino groups and carboxylic groups[26].During the silver nanoparticle synthesis,the relative intensity of peaks at 1092, 1164,1240,1412,and 2464 cm-1of cell fi ltrate are either diminished or disappeared.The bands at 1092 and 1164 cm-1are attributed to the vibration of C-O and C-OH stretch respectively[27,28].The peaks observed at 2572 and 2778 cm-1are assigned to the symmetric stretching of N-H/N+H2groups and the bands at 2464 and 1412 cm-1corresponds to the characteristic C-H and C-H2symmetric scissoring[29].The absorption peaks at 1240 and 2676 cm-1are due to the C-H stretch and O-H bending respectively[29].In Fig.7C,two new peaks appeared at 1111 and 2340 cm-1,which is assigned to rocking of amino acids NH3structure[30,31]and physisorbtion of CO2generated due to the decomposition of oxygen containing functional groups[32,33]respectively.The changes in the peak intensity and disappearance of peaks in spectrum of synthesis mixture is mainly due to the involvement of the biomolecules and their functional groups for the AgNPs synthesis and all these functional groups are recognized as the carbonyl groups and amide I band of proteins.On the whole,it is observed that the protein molecules of the fungus are mainly responsible for the synthesis of AgNPs. Earlier FTIR reports[34,35]prove the involvement of carbonyl groups present in the amino acid residues and peptides of proteins for the synthesis of AgNPs.These protein molecules may also play a signi fi cant role in the prevention of agglomeration and stabilization of the AgNPs in the aqueous medium by binding on to their surface and forming a protein coat[36].
3.2. Antibacterial activity of synthesized silver nanoparticles
The effectiveness of AgNPs on MDR bacterial strains were assessed by comparing bacterial growth rate under normal (control)and AgNPs treated(test)conditions.The lag,log, stationary and death phases were clearly represented in the control group but under treatment with various concentration of AgNPs(10,20,30 and 40 μg/ml),gradual decrease in the growth and lengthy log phase were recorded(Fig.8).This clearly states the concentration dependent inhibitory effect of AgNPs on MDR bacteria.Particularly,in Fig.8A and D there were no increase in the log phase of Enterobacter sp.and E.coli upto 12 h of incubation with 40 μg/ml of AgNPs,indicating complete inhibition of bacteria.Similarly,Fig.8B and C show diminution in the growth rate of P.aeruginosa and K. pneumoniaewhen increasing the AgNPsconcentration. Though silver nanoparticles are widely used in many antibacterial applications,the exact action of this metal on microbes is not clearly understood and is a debated topic.Quite a few mechanisms have been hypothesized that the AgNPs can cause cell lysis or growth inhibition.The proposed mechanisms are,(i)Silver nanoparticles have the ability to adhere to the bacterial cell wall and produces cracks and pits, through which the internal cell contents are released out[37], ultimately leading to structural loss and cell death[38].(ii) Silver ions released by the nanoparticles react with thiol groups(-SH)of bacterial enzymes and other cell membrane components to produce a stable S-Ag bonds or disul fi de bonds(R-S-S-R)[39,40].It has been proposed that the catalytic oxidation reaction of Ag+with the thiol group leads to inactivation or down regulation of 30 S ribosomal subunit protein,succinyl coenzyme A synthetase,maltose transporter (MalK),fructose bisphosphate adolase,transmembrane energy generation and ion transport,etc.This could possibly change the shape of cellular enzymes thereby affecting the cells function.(iii)Soft acid nature of silver eventually reacts with the cellular soft base components namely sulphur and phosphorus.During this reaction,the sulphur and phosphorus content of genomic DNA possibly gets affected by silvernanoparticles which would de fi nitely block DNA replication[41,42]and thus kills the bacteria.(iv)It has also been found that the nanoparticles can inhibit the signal transduction in bacteria by dephosphorylating the peptide substrates on tyrosine residues.All the above said actions of the nanoparticles could cause the cell death.However,the actual and most reliable mechanism is not fully understood or cannot be generalized.
In thepresentstudy,we observedvaryinginhibitoryeffects of the AgNPs against P.aeruginosa,K.pneumoniae,Enterobacter sp.and E.coli.According to the reports,the inhibitory effect of AgNPs fl uctuates in different bacteria due to the variation in their capsular and cell wall composition,thickness of the S-layer or a combination of these.Likewise,the bacterial growth rate and its byproducts may also in fl uence the inhibitory activity of AgNPs.Thus we conclude that,an increasing concentration of AgNPs is required to achieve a higher inhibitory effect.
3.3. Antibacterial effect of AgNPs and ampicillin(AMP) complex
Development of ampicillin resistance among a variety of bacteria is due to hyper production of classical β-lactamases, synthesis of inhibitor-resistant TEM(IRT)β-lactamases,hyperproduction of chromosomal AmpC β-lactamase,OXA βlactamases and changes in membrane permeability.Resistance to antibiotics makes bacteria more dif fi cult and expensive to eradicate.Thus treatment with a combination of drugs is necessary to clear infections of resistant bacteria.
Ampicillin molecule couples on the surface of silver nanoparticles due to synergistic effect producing AgNPs and ampicillin complex[43].This complex greaten the inhibitory effect against all the ampicillin resistant bacteria when ampicillin alone had no/little inhibitory effect on the test organisms and therefore the bacteria are considered to be resistant to the antibiotic.However,all the bacteria were found to be sensitive to AgNPs to varying extent upto 20 μg/ml dose.Addition of ampicillin in the presence of AgNPs slightly enhanced the inhibitory effect towards all the tested bacteria by an increase of 2-3 mm inhibition zone(Figs.9 and 10).Among the tested organisms Enterobacter sp.(Fig.9A)was found to be highly sensitive with larger inhibition zone when compared to P. aeruginosa(Fig.9B),K.pneumoniae(Fig.9C)and E.coli(Fig.9D).
As pointed above,all the tested clinical pathogens showed resistance towards ampicillin either by producing β-lactamases or changes in their membrane permeability.While treating these MRD isolates with AgNPs-ampicillin complex, the AgNPs lyse the cell wall and causes the leakage of internal cellular material leading to death of the pathogen.On the other hand,ampicillin enters the cell through damages caused by AgNPs and results in irreversible inhibition of the enzyme transpeptidase which ultimately stops their cell wall synthesis.Thus the results clearly represents that the sensitivity of the MDR bacterial pathogens increased with AgNPs-ampicillin complex in comparison with AgNPs.
4. Conclusion
Silver nanoparticles have been synthesized using fungal extract and positively complexed with ampicillin in order to destroy the ampicillin resistant bacterial pathogens.Though AgNPs and ampicillin complex undoubtedly combat antibiotic resistance pathogens,further researches are required to fi nd out the exact mechanism of AgNPs and ampicillin complex formation to improve their inhibitory activity.Further investigations are required in this direction for the complete elimination of multidrug resistant pathogens using AgNPs as an adjuvant.
Acknowledgements
The authors acknowledge with thanks the Department of Science and Technology,Government of India,for providing the fi nancial assistance in the form of Research Fellowship under the DST-Promotion of University Research and Scienti fi cExcellence (PURSE)scheme (Ref.No.41891/E8/2010 dated 12.12.11)to P.M.Gopinath.
We also thank University Grants Commission,Government of India for providing fi nancial assistance(Ref.No.41-1135/2012(SR)dated 26.06.2012).
REFERENCES
[1]Comhaire FH,Mahmoud AMA,Depuydt CE,et al. Mechanisms and effects of male genital tract infection on sperm quality and fertilizing potential:the andrologist's viewpoint.Hum Reprod Update 1999;5:393-398.
[2]Khalili MB,Shari fi-Yazdi MK.The effect of bacterial infection on the quality of human^as spermatozoa.Iranian J Pub Health 2001;35:62-67.
[3]Anchana Devi C,Ranjani A,Dhanasekaran D,et al. Surveillance of multidrug resistant bacteria pathogens from female infertility cases.Afr J Biotechnol 2013;12:4129-4134.
[4]Kim JS,Kuk E,Yu KN,et al.Antimicrobial effects of silver nanoparticles.Nanomed Nanotech Biol Med 2007;3:95-101.
[5]Morones JR,Elechiguerra JL,Camacho A,et al.The bactericidal effect of silver nanoparticles.Nanotechnology 2005;16:2346-2353.
[6]Schabes-Retchkiman PS,Canizal G,Herrera-Becerra R,et al. Biosynthesis and characterization of Ti/Ni bimetallic nanoparticles.Opt Mater 2006;29:95-99.
[7]Gu H,Ho PL,Tong E,et al.Presenting vancomycin on nanoparticles to enhance antimicrobial activities.Nano Lett 2003;3:1261-1263.
[8]Dhanasekaran D,Latha S,Saha S,et al.Biosynthesis and antimicrobial potential of metal nanoparticles.Int J Green Nanotechnol 2011;3:72-82.
[9]Dhanasekaran D,Latha S,Saha S,et al.Extracellular biosynthesis,characterisation and in-vitro antibacterial potential of silver nanoparticles using Agaricus bisporus.J Exp Nanosci 2013;8:579-588.
[10]Gong P,Li H,He X,et al.Preparation and antibacterial activity of Fe3O4@Ag nanoparticles.Nanotechnology 2007;18:604-611.
[11]Marambio-Jones C,Hoek EMV.A review of the antibacterial effects of silver nanomaterials and potential implications for human health and the environment.J Nanopart Res 2010;12:1531-1551.
[12]Duran N,Marcato PD,Alves OL,et al.Mechanistic aspects of biosynthesis of silver nanoparticles by several Fusarium oxysporum strains.J Nanobiotechnology 2005;3:1-7.
[13]Ingle A,Gade A,Pierrat S,et al.Mycosynthesis of silver nanoparticles using the fungus Fusarium acuminatum and its activity against some human pathogenic bacteria.Curr Nanosci 2008;4:141-144.
[14]Gade AK,Bonde P,Ingle AP,et al.Exploitation of Aspergillus niger for synthesis of silver nanoparticles.J Biobased Mater Bio 2008;2:243-247.
[15]Pal S,Tak YK,Song JM.Does the antibacterial activity of silver nanoparticles depend on the shape of the nanoparticle?A study of the gram-negative bacterium Escherichia coli.Appl Environ Microbiol 2007;73:1712-1720.
[16]Gherbawy YA,Shalaby IM,El-sadek MSA,et al.The antifasciolasis properties of silver nanoparticles produced by Trichoderma harzianum and their improvement of the antifasciolasis drug triclabendazole.Int J Mol Sci 2013;14:21887-21898.
[17]Li Y,Duan X,Qian Y,et al.Nanocrystalline silver particles: synthesis,agglomeration,and sputtering induced by electron beam.J Colloid Interface Sci 1999;209:347-349.
[18]Ahmad A,Mukherjee P,Senapati S,et al.Extracellular biosynthesis of silver nanoparticles using the fungus Fusarium oxysporum.Colloid Surf B 2003;28:313-318.
[19]Kathiresan K,Manivannan S,Nabeel MA,et al.Studies on silver nanoparticles synthesized by a marine fungus, Penicillium fellutanum isolated from coastal mangrove sediment.Colloid Surf B 2009;71:133-137.
[20]Thirumurugan G,Shaheedha SM,Dhanaraju MD.In vitro evaluation of antibacterial activity of silver nanoparticles synthesised by using Phytophthora infestans.Int J ChemTech Res 2009;1:714-716.
[21]Gajbhiye M,Kesharwani J,Ingle A,et al.Fungus-mediated synthesis of silver nanoparticles and their activity against pathogenic fungi in combination with fl uconazole.Nanomed Nanotech Biol Med 2009;5:382-386.
[22]Dhanasekaran D,Thangaraj R.Evaluation of larvicidal activity of biogenic nanoparticles against fi lariasis causing Culex mosquito vector.Asian Pac J Trop Dis 2013;3:174-179.
[23]Saha S,Sarkar J,Chattopadhyay D,et al.Production of silver nanoparticles by a phytopathogenic fungus Bipolaris nodulosa and its antimicrobial activity.Dig J Nanomater Biostruct 2010;5:887-895.
[24]Kalishwaralal K,Deepak V,Ramkumarpandian S,et al. Extracellular biosynthesis of silver nanoparticles by the culture supernatant of Bacillus licheniformis.Mater Lett 2008;62:4411-4413.
[25]Serratosa JM,Johns WD,Shimoyama A.IR study of alkylammonium vermiculite complexes.Clay Clay Miner 1970;18:113.
[26]Peniche C,Arguelles-Monal W,Davidenko N,et al.Selfcuring membranes of chitosan/PAA IPNs obtained by radical polymerization:preparation,characterization and interpolymer complexation.Biomaterials 1999;20:1869-1878.
[27]Ahmad I,Jie MSFLK.Oleochemicals from isoricinoleic acid (Wrightia tinctoria seed oil).Ind Eng Chem Res 2008;47:2091-2095.
[28]Galande C,Mohite AD,Naumov AV,et al.Quasi-molecular fl uorescence from graphene oxide.Sci Rep 2011;1:1-5.
[29]Bright A,Devi TSR,Gunasekaran S.Spectroscopical vibrational band assignment and qualitative analysis of biomedical compounds with cardiovascular activity.Int J Chem Tech Res 2010;2:379-388.
[30]Hodzic IM,Niketic SR.Synthesis and characterization of a novel(glycinato-N,O)yttrium(III)complex.J Serb Chem Soc 2001;66:331-334.
[31]Malekfar R,Daraei A.Raman scattering and electrical properties of TGS:PCo(9%)crystal as ambient temperature IR detector.Acta Phys Pol A Gen Phys 2008;114:859.
[32]Feng X,Matranga C,Vidic R,et al.A vibrational spectroscopic study of the fate of oxygen-containing functional groups and trapped CO2in single-walled carbon nanotubes during thermal treatment.J Phys Chem B 2004;108:19949-19954.
[33]Matranga C,Chen L,Bockrath B,et al.Displacement of CO2by Xe in single-walled carbon nanotube bundles.Phys Rev B 2004;70:165416.
[34]Balaji DS,Basavaraja S,Deshpande R,et al.Extracellular biosynthesis of functionalized silver nanoparticles by strains of Cladosporium cladosporioides fungus.Colloid Surf B 2009;68:88-92.
[35]Mandal S,Gole A,Lala N,et al.Studies on the reversible aggregation of cysteine-capped colloidal silver particles interconnected via hydrogen bonds.Langmuir 2001;17:6262-6268.
[36]Shaligram NS,Bule M,Bhambure R,et al.Biosynthesis of silver nanoparticles using aqueous extract from the compactin producing fungal strain.Process Biochem 2009;44:939-943.
[37]Feng QL,Wu J,Chen GQ,et al.A mechanistic study of the antibacterial effect of silver ions on Escherichia coli and Staphylococcus aureus.J Biomed Mater Res 2000;52:662-668.
[38]Guggenbichler JP.The Erlanger silver catheter:in vitro results for antimicrobial activity.J Infect 1999;27:S24-9.
[39]Davies RL,Etris SF.The development and functions of silver in water puri fi cation and disease control.Catal Today 1997;36:107-114.
[40]Yamanaka M,Hara K,Kudo J.Bactericidal actions of a silver ion solution on Escherichia coli,studied by energy- fi ltering transmission electron microscopy and proteomic analysis. Appl Environ Microbiol 2005;71:7589-7593.
[41]Klueh U,Wagner V,Kelly S,et al.Ef fi cacy of silver-coated fabric to prevent bacterial.colonization and subsequent device-based bio fi lm formation.J Biomed Mater Res 2000;53:621-631.
[42]Fox CL,Modak SM.Mechanism of silver sulfadiazine action on burn wound infections.Antimicrob Agents Chemother 1974;5:582-588.
[43]Brown AN,Smith K,Samuels TA,et al.Nanoparticles functionalized with ampicillin destroy multiple-antibioticresistant isolates of Pseudomonas aeruginosa and Enterobacter aerogenes and methicillin-resistant Staphylococcus aureus. Appl Environ Microbiol 2012;78:2768-2774.
*Corresponding author.Bioprocess Technology Laboratory,Department of Microbiology,School of Life Sciences,Bharathidasan University,Tiruchirappalli 620 024,India.Tel.:+91 9486258493.
E-mail addresses:dhansdd@gmail.com,pmg.bdu@gmail.com(D.Dhanasekaran).
Peer review under responsibility of Shenyang Pharmaceutical University.
http://dx.doi.org/10.1016/j.ajps.2014.08.007
1818-0876/©2015 Shenyang Pharmaceutical University.Production and hosting by Elsevier B.V.All rights reserved.
Silver nanoparticles
Fusarium oxysporum
AgNPs-Ampicillin complex Infertility
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