about
Selective recognition induced nanostructures in a cucurbit[7]uril-based host-guest system: micelles, nanorods and nanosheets.Long-Time Plasma Membrane Imaging Based on a Two-Step Synergistic Cell Surface Modification Strategy.Dependence of Alamethicin Membrane Orientation on the Solution Concentration.Lipid Fluid-Gel Phase Transition Induced Alamethicin Orientational Change Probed by Sum Frequency Generation Vibrational SpectroscopyAction of Gold Nanospikes-Based Nanoradiosensitizers: Cellular Internalization, Radiotherapy, and Autophagy.Synthesis of ultrastable and multifunctional gold nanoclusters with enhanced fluorescence and potential anticancer drug delivery application.Antimicrobial carbon nanospheres.Cholesterol-Assisted Bacterial Cell Surface Engineering for Photodynamic Inactivation of Gram-Positive and Gram-Negative Bacteria.Acetonitrile induces nonsynchronous interdigitation and dehydration of dipalmitoylphosphatidylcholine bilayers.Formation and transformation of the subgel phase in dioctadecyldimethylammonium bromide aqueous dispersions.Carbon quantum dots with intrinsic mitochondrial targeting ability for mitochondria-based theranostics.Hyperthemia-Promoted Cytosolic and Nuclear Delivery of Copper/Carbon Quantum Dot-Crosslinked Nanosheets: Multimodal Imaging-Guided Photothermal Cancer Therapy.Mitochondria-targetable carbon quantum dots for differentiating cancerous cells from normal cells.Controllable engineering of asymmetric phosphatidylserine-containing lipid vesicles using calcium cations.Ultrasmall and photostable nanotheranostic agents based on carbon quantum dots passivated with polyamine-containing organosilane molecules.One-Step Synthesis of Ultrasmall and Ultrabright Organosilica Nanodots with 100% Photoluminescence Quantum Yield: Long-Term Lysosome Imaging in Living, Fixed, and Permeabilized Cells.Enhanced Fluorescence Emission and Singlet Oxygen Generation of Photosensitizers Embedded in Injectable Hydrogels for Imaging-Guided Photodynamic Cancer Therapy.Photosensitizer (PS)/polyhedral oligomeric silsesquioxane (POSS)-crosslinked nanohybrids for enhanced imaging-guided photodynamic cancer therapy.Shape-Dependent Radiosensitization Effect of Gold Nanostructures in Cancer Radiotherapy: Comparison of Gold Nanoparticles, Nanospikes, and Nanorods.Turning double hydrophilic into amphiphilic: IR825-conjugated polymeric nanomicelles for near-infrared fluorescence imaging-guided photothermal cancer therapy.Enhanced Radiosensitization of Gold Nanospikes via Hyperthermia in Combined Cancer Radiation and Photothermal Therapy.Development of a Light-Controlled Nanoplatform for Direct Nuclear Delivery of Molecular and Nanoscale Materials.Synthesis of ultrastable copper sulfide nanoclusters via trapping the reaction intermediate: potential anticancer and antibacterial applications.Carbon Dot-Based Platform for Simultaneous Bacterial Distinguishment and Antibacterial Applications.In Situ Visualization of Lipid Raft Domains by Fluorescent Glycol Chitosan Derivatives.Folding Behaviors of Protein (Lysozyme) Confined in Polyelectrolyte Complex Micelle.Complexation of Lysozyme with Sodium Poly(styrenesulfonate) via the Two-State and Non-Two-State Unfoldings of Lysozyme.Fluorescent artificial enzyme-linked immunoassay system based on Pd/C nanocatalyst and fluorescent chemodosimeter.Self-assembled Rose Bengal-Exopolysaccharide Nanoparticles for Improved Photodynamic Inactivation of Bacteria by Enhancing Singlet Oxygen Generation Directly in the Solution.Fluorescent Carbon Quantum Dots with Intrinsic Nucleolus-Targeting Capability for Nucleolus Imaging and Enhanced Cytosolic and Nuclear Drug Delivery.A Water-Soluble, Green-Light Triggered, and Photo-Calibrated Nitric Oxide Donor for Biological Applications.Glutathione-Depleting Gold Nanoclusters for Enhanced Cancer Radiotherapy through Synergistic External and Internal Regulations.Enhanced fluorescence of gold nanoclusters composed of HAuCl4 and histidine by glutathione: glutathione detection and selective cancer cell imaging.Molecular interactions between amantadine and model cell membranes.Enhanced cell membrane enrichment and subsequent cellular internalization of quantum dots via cell surface engineering: illuminating plasma membranes with quantum dotsHighly Sensitive and Selective Detection of Dopamine Using One-Pot Synthesized Highly Photoluminescent Silicon NanoparticlesOne-Step Synthesis of Superbright Water-Soluble Silicon Nanoparticles with Photoluminescence Quantum Yield Exceeding 80%Surface Orientation Control of Site-Specifically Immobilized Nitro-reductase (NfsB)Improving the Phototherapeutic Efficiencies of Molecular and Nanoscale Materials by Targeting MitochondriaWater‐Dispersible Candle Soot–Derived Carbon Nano‐Onion Clusters for Imaging‐Guided Photothermal Cancer Therapy
P50
Q34278550-C91A278A-CE85-4582-92B4-BD75B3F1E2E4Q35909866-779B4FD1-E308-4ECB-8BDD-1FAB7EEDF234Q36733647-1C523194-6A5A-41BE-A4CC-84AC987B0225Q37219922-66A429A8-2CA6-4D5A-864C-5A640FE7E13BQ38620750-67FCEE16-4066-4B5F-99FE-64F7C35BF81DQ38867051-93D7C6AC-519D-4BE0-A36D-C14345B56310Q40088788-60F2D205-BF83-449B-94F8-AD07E08035D3Q40243813-88511567-DDDC-410F-9E17-ED901130F7FAQ42909246-73290FE4-FF80-4555-B0EB-59C34BF64E50Q43613623-D103ACD8-6587-4146-A210-14AA54B3CF07Q46331885-9B5572AD-156E-41EB-A052-BC5A341B97F6Q47232374-1FF3A041-A233-487F-B3E1-745339493724Q47343158-B102AE65-EF5D-489F-BA3F-2EAAC8409E8EQ47346238-6E27BE94-725F-40DB-9674-4DED55EC3C71Q47602924-D82AB297-226E-431A-8B9A-6443F472A3B1Q47701224-996F0632-C42E-4943-805A-4FD6B1410540Q47780171-26E5141E-D156-4696-AE2C-ADD4CCF2213AQ47949536-E27E0EAB-3CAC-444E-B2CB-6AA52199D709Q48365340-43351026-DB87-4EE2-97E6-92E65CC28FDDQ48540643-E711B040-FDF2-4985-9CFB-6FC871B67A46Q49019928-B2264D45-0E52-4529-9AF9-FEB0BEA2EB9FQ50142461-0E201CE7-4C8E-4E63-AA52-27200010BF1AQ50997931-AF62C0AB-D849-420A-AE8E-69973476CD38Q51121114-50A0BD02-D011-457C-A917-3317F01FF906Q51299965-60FE5913-0C35-478D-B6F2-04A85AB0531CQ51410202-067AC940-E72D-47E1-BC84-5FF852563238Q51677615-4A233F9F-DD4B-4D1E-817E-EC8F2A3349CFQ51775245-EC50B5AD-CFC3-40CF-8E98-4B63F60BDA89Q52594375-11804A41-DC6E-4E54-9E37-2946FA37E1A3Q52672429-AD2563BA-46F8-4102-BE3A-A7FF661D8D2CQ52677196-C5D7C1CC-1B0E-4BB9-8A99-9BFADF35B054Q52726423-AE08A992-7801-48F7-9770-3CF015361EACQ53476364-6A29DF3E-B650-4F8B-8868-52E1F3E226F8Q53505595-A7951F7C-1B54-4E79-B6A1-BC9023587582Q57974244-D9C0EAD9-6204-4AE3-9BC1-CA75D3ECB18EQ57974279-E2A6455B-C9DC-4D1E-A1EC-D0AE9057469CQ57974325-6EF97CD0-1ED9-482C-A330-9CE2E841EDBBQ57974468-11DA93AB-6E50-40A0-9FD2-2E2E635BF40BQ59797014-3F6791DC-9FB9-4E09-93BF-CE3041A2FE9AQ62334578-4F6D80B3-D0A8-4EEC-9317-C542E37897E6
P50
description
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Fu-Gen Wu
@ast
Fu-Gen Wu
@en
Fu-Gen Wu
@es
Fu-Gen Wu
@nl
Fu-Gen Wu
@sl
type
label
Fu-Gen Wu
@ast
Fu-Gen Wu
@en
Fu-Gen Wu
@es
Fu-Gen Wu
@nl
Fu-Gen Wu
@sl
prefLabel
Fu-Gen Wu
@ast
Fu-Gen Wu
@en
Fu-Gen Wu
@es
Fu-Gen Wu
@nl
Fu-Gen Wu
@sl
P106
P31
P496
0000-0003-1773-2868