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Carbon Nanomaterials Interfacing with Neurons: An In vivo PerspectiveAll-optical processing with molecular switchesCarbon nano-onions (multi-layer fullerenes): chemistry and applications.Biocompatibility and biodistribution of functionalized carbon nano-onions (f-CNOs) in a vertebrate model.Impact of Carbon Nano-Onions on Hydra vulgaris as a Model Organism for NanoecotoxicologyCarbon nanomaterials: multi-functional agents for biomedical fluorescence and Raman imaging.Recent developments in carbon nanomaterial sensors.Multi-Functionalized Carbon Nano-onions as Imaging Probes for Cancer Cells.Recent advances in smart biotechnology: Hydrogels and nanocarriers for tailored bioactive molecules depot.Photo-controlled release of zinc metal ions by spiropyran receptors anchored to single-walled carbon nanotubes.Screening the cytotoxicity of single-walled carbon nanotubes using novel 3D tissue-mimetic models.Digital communication through intermolecular fluorescence modulation.Signal communication between molecular switches.Multichannel digital transmission in an optical network of communicating molecules.Determination of spiropyran cytotoxicity by high content screening and analysis for safe application in bionanosensing.A switch in a cage with a memory.Surface analysis of zinc-porphyrin functionalized carbon nano-onions.Carbon nano-onions as fluorescent on/off modulated nanoprobes for diagnosticsConjugated Quantum Dots Inhibit the Amyloid β (1-42) Fibrillation ProcessNative chemical ligation,thiol-ene click: a methodology for the synthesis of functionalized peptides.Antibody-gold quantum dot-PAMAM dendrimer complex as an immunoglobulin immunoassay.Iron-related toxicity of single-walled carbon nanotubes and crocidolite fibres in human mesothelial cells investigated by Synchrotron XRF microscopy.Probing Metal Ion Complexation of Ligands with Multiple Metal Binding Sites: The Case of Spiropyrans.Signal processing at the molecular level.Highly surface functionalized carbon nano-onions for bright light bioimaging.Synthesis and Characterization of Far-Red/NIR-Fluorescent BODIPY Dyes, Solid-State Fluorescence, and Application as Fluorescent Tags Attached to Carbon Nano-onions.Interaction studies between photochromic spiropyrans and transition metal cations: the curious case of copper.Synthesis and characterization of boron azadipyrromethene single-wall carbon nanotube electron donor-acceptor conjugates.Functionalization of carbon nanoparticles modulates inflammatory cell recruitment and NLRP3 inflammasome activation.Immunoasssay based on the antibody-conjugated PAMAM-dendrimer-gold quantum dot complex.Internalization of Carbon Nano-onions by hippocampal cells preserves neuronal circuit function and recognition memory.Photo-Responsive Graphene and Carbon Nanotubes to Control and Tackle Biological Systems.Synthesis and photochemical properties of spiropyran graft and star polymers obtained by ‘click’ chemistryQuantifying the contributions of inner-filter, re-absorption and aggregation effects in the photoluminescence of high-concentration conjugated polymer solutionsTowards Solutions of Single-Walled Carbon Nanotubes in Common SolventsExfoliation in ecstasy: liquid crystal formation and concentration-dependent debundling observed for single-wall nanotubes dispersed in the liquid drug γ-butyrolactoneDebundling of Single-Walled Nanotubes by Dilution: Observation of Large Populations of Individual Nanotubes in Amide Solvent DispersionsFabrication of stable dispersions containing up to 70% individual carbon nanotubes in a common organic solventEffect of solvent and dispersant on the bundle dissociation of single-walled carbon nanotubeLipophilic guanosine derivatives as carbon nanotube dispersing agents
P50
Q26745423-766AC48A-17F0-4A9A-8475-11F355B2B174Q34022781-2D310DBE-A3F0-4DD1-AC5D-54520FC04C32Q34463292-FD8B8804-1AB0-4220-AAFC-D000720BB5DFQ37285284-624068A0-87FC-4C82-891B-CE80CA6739FBQ37638486-7C2D82E0-70D6-41ED-8015-EC136A81DAB0Q38269244-2564247E-E417-4BDC-A9FF-DCE0552A2B9AQ38484734-93C7CEDA-15E6-4381-A39E-1FB378544559Q38941896-1F99EF35-FBF7-4226-BC70-93E53BB62EF6Q39319671-0F2D907C-032F-4BF6-81CA-4812EDC3A85DQ39374319-B5CD1E12-1EBD-4BC4-9002-E2F02C4DFD8DQ39454798-8D12151D-9875-4EB9-ACA5-63A6D1A0AAA6Q39570522-4DB17C6B-66DF-4591-A682-031C830C9275Q39584142-5A2CBCA9-6DCE-42F9-980E-75B2BC6001FEQ39595062-E5885F17-1742-49D2-B176-07FEFC44D970Q39660961-3322DF46-FFEF-4455-B835-97FF7902A3B4Q39665547-E2FE8A94-086C-4D90-8298-B888F6F6DAD7Q41362910-15B8B6B8-5F1C-4814-8F54-832073E0333FQ42371098-653E9483-1EC3-405D-A736-B88B034DDAD2Q42684539-F8CF0EB2-84E4-421D-BD83-8CB0818C3D83Q45805205-CAD5750C-69EE-4BA3-8E84-2AE8D625D12BQ47759138-4C88AD4A-E818-48A8-9707-47457B7AB546Q48042878-682494F2-FB4D-4115-A072-1EE880914487Q48115650-EA7EC978-ECE4-4326-BFBA-D43BAC39833AQ49324891-040738F3-277C-4EA8-BF5E-1C2757AF6321Q49926313-C90A980A-404A-4FB1-B3D2-D17022532028Q50444447-916A758E-5294-4FB2-B52D-898483A8D4A2Q50506504-03F3D4F4-0F24-48C8-BB82-5D11D6DCA90AQ50527413-024A3C1A-FC1C-4D5C-B0EE-6AD90A728836Q50847633-7CD75CF2-CCD9-4318-9D21-776E7A73A187Q51097859-A19DA47C-661D-4C99-9D54-F7BFC6D13004Q52317407-5449F997-44EC-402E-A070-57E5CB66CE5AQ55079674-C9785EB5-6801-4D25-83C2-283694BE8A73Q58422884-F79AC86E-FC52-418E-B57F-1667BBF7448CQ58902363-2F130B9D-680D-4695-9223-57254A96E084Q58902384-906F9D23-1DEC-432F-AA7F-015D1270348AQ58902405-8089073A-BCD7-44A3-946F-9AD558518F64Q58902453-E81BB08A-BDDD-407B-A25F-5BFAF1DF1688Q58902462-7F70F0B9-F81F-4528-B942-EB9B0CF365BCQ58902515-3858359A-6660-4C76-84C8-A42634BC26DAQ59652278-A8895F3E-6416-4C44-8ECF-A184D292D993
P50
description
hulumtuese
@sq
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Silvia Giordani
@ast
Silvia Giordani
@en
Silvia Giordani
@es
Silvia Giordani
@nl
Silvia Giordani
@sl
type
label
Silvia Giordani
@ast
Silvia Giordani
@en
Silvia Giordani
@es
Silvia Giordani
@nl
Silvia Giordani
@sl
prefLabel
Silvia Giordani
@ast
Silvia Giordani
@en
Silvia Giordani
@es
Silvia Giordani
@nl
Silvia Giordani
@sl
P108
P1053
C-5343-2009
P106
P21
P2798
P31
P3829
P496
0000-0002-9212-5067