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Nanomaterials 2020, 10, 376 13 of 22 Nanomaterials 2020, 10, x FOR PEER REVIEW 13 of 22 Figure 6. Microbial growth kinetics in contact with GO. (a) C. albicans, (b) S. aureus, (c) P. aeruginosa, Figure 6. Microbial growth kinetics in contact with GO. (a) C. albicans, (b) S. aureus, (c) P. aeruginosa, and (d) E. coli. Several studies have investigated the antimicrobial properties of GO, and the reported results have been controversial [50–53]. The diiscrrepancciiess iin the published data have been attributed to difffferences in the physical-chemical characteristics of the GO used.. The size, surface area, functional groups,,oxoyxgyegnenconctoente,nsut,rfasucerfraocueghrnoeusgsh,nlaeysesr,nluamyebrer,npuumribtye,r,anpduarrirtyan,gaenmdenatrmraondgeeomfeGnOtsmheoedtes aofff eGcOt thsheeiretasntaimffeicrtobthiaelirpraonpteimrticerso. bBioatlhpthroepgeratipehs.iteBsoothurcteheangdrathpehilteeveslooufrocexidaantdionth/eexfolelviaetlioonf, gooxvideartnieodn/beyxftohleiaptiroenp,agraotvioernnmedetbhyodth,deepterermpairnaetimonosmtoefththoeds,edfetaetrumreins.eTmheoslattoefratlhseiszefoefaGtuOresh.eTehtse hlatserbaelesnizsehofwGnOtoshaeffetcsththaseibreaentismhoicwronbitaolafcfteicvtityh.eiHriagnhteimraicnrtoibiacltearcitaivliatcyt.ivHitigyhiesrdainsptilbaaycetderbiayl samctaivllitlyatiesrdali-sspizlaeydeGdObywshmeanllinlathereaflo-srimzeodfGsuOrfwacheecnoiantitnhge[f5o4r]m,wohfesurerafasclearcgoeastihneget[s54a]r,ewmhoereatosxlaicrgtoe bshaecteetrsiarfeormdoirsepetorsxeicdtGoOba[c5t5e]r.iaInfoarddistpioenrsteodthGeOab[5o5v]e.-Imneandtdioitnioend tfoacthoersa,bwohviec-hmdeenptieondedtofacvtoersy, hwighhichexdteenpteonndthtoe taypveroyf ghriagphheitxet,etnhteoanttimheictryopbeialoefffgercatpshoifteG,OthaereanintflimueicnrcoebdiablyeiftfsectosnocefnGtrOatiaorne, tihnefluinecnucbeadtiboyn citosncdointicoennst,reaxtpions,utrheetiimnceu, abnadtiothneccohnadriatciotenrsis,teicxspofsmuriecrtoimoreg,aannisdmtshuescehda.rLaicuteertisatli.c[s5o2]f dmeimcronosrgtranteisdmtshautsesdev.eLriaulegtrapl.h[e5n2e]dmeamteorniasltrdaitsepdetrhsiaotnssevheardalcgornacpehnetrnaetimona-tearniadltdimispe-edrseipoennsdheandt aconnticbeanctrearitaiol na-ctiavnidty. tIinmteh-edierpsetundye,ntheaninticbuabcatetiroianl oaf cGtiOvitdyi.spIenrstihoenisr (astucdoyn,cetnhteraitniocnusbfartoiomn 1o0ftoG8O0 μdgis/pmeLrs)iwonitsh(aEt.conlicceenlltsrasthionwsefdrotmhe1h0igtohe8s0tμagn/tmibLac)tweriitahlEa.ctciovlitcyelalms sohnogwtehde tdhieffehriegnhtegstrapnhtiebnaec-tberaisael macatitveritiyalsasmtuodnigedthaendiafnfearlemntosgtrcaopmhpenlet-eblaosses omfactelrlivailasbsiltiutydiaetda aconndceantraltmioonstofc8o0mμpgl/emteLl.oMssoroefovcelrl, mvioabstiloitfythaetabaccotnecrieanltirnaaticotinvaotfio8n0wμga/smoLb.seMrvoerdeoivnetrh,emfiorsttohfotuhreobfaicntceurbialtionnac.tHivuateiotnalw.raespobrtseedrvthede ginrotwhethfirinsthhiboiutiroonfoinfcEu.bcoaltiiobnac.tHeruiaebtyal.GrOep,obretiendgtahlemgorsotwcothmipnlheitbeliytiosnupopfrEe.scsoeldibwahctenritarebayteGdOw,ibtehin8g5 μalgm/mosLtGcoOmfpolret2elhy[s5u3p].pOretshsedrswtuhdeinest,rehaotwedevweirt,hh8a5veμgs/hmowLnGOthefocro2nhtra[5r3y.].IOnttherstudyiebs,yhNowguevyern, ehtaavle.,sthoewinetffhecctiovnetnraersys.oIfnGthOe s(utupdtyob4y00Nμgug/ymenL)etaagla.,inthste Ein. ecfofleicwtivaesndeesms ofnGstOra(teudp [t5o64]0. 0Tμhge/lmacLk) oafgaintsiftuEn.gcaoliawctaivsitdyemagoaninstsrtaCte.dalb[5ic6a]n.sTbhye GlaOckwoafsandteimfuonngsatlratcetidvitnytahgeasitnusdtiCes. aclabrirciaendsobuytGbOyLwiaest adle.m[5o7n] satnradteAdl-iTnhtahneisetut dali.e[s5c8a]r.rRieudizouet ably. Lreipeotratle.d[5a7]rapnidAanl-dThirarneivetrasilb. [le58a]t.tRacuhizmetnatl.orfebpaocrtterdiaal crealplsidtoanGdOir[r5e0v].ersible attachment of bacterial cells to GO [50]. Physical and chemical interactions between GO and bacterial cells are responsible for the antibacteriiallprropeerrttieiessooffththeeGGOO. .Whhenenbbacatcetreirailacleclelsllcsocmome ienitnotdoidreircetctocnotanctat cwtiwthithethsehasrhparepdgedesgoesr or basal planes of GO, membrane stress of bacteria can be induced, resulting in disruption and physical damage to cell membranes. The sharp edges of graphene sheets act as nanoknives, cuttingPDF Image | Graphene Oxide–Silver Nanoparticle Nanohybrids
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