| Nome |
# |
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An apolipoprotein-enriched biomolecular corona switches the cellular uptake mechanism and trafficking pathway of lipid nanoparticles, file e3835319-e477-15e8-e053-a505fe0a3de9
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374
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A protein corona-enabled blood test for early cancer detection, file e3835316-78dd-15e8-e053-a505fe0a3de9
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277
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Nanoparticles-cell association predicted by protein corona fingerprints, file e3835316-648d-15e8-e053-a505fe0a3de9
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226
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Exploitation of nanoparticle-protein interactions for early disease detection, file e3835324-d3dd-15e8-e053-a505fe0a3de9
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218
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Opsonin-deficient nucleoproteic corona endows unPEGylated liposomes with stealth properties in vivo, file e383532e-3177-15e8-e053-a505fe0a3de9
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122
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In vivo protein corona patterns of lipid nanoparticles, file e383531b-8c7e-15e8-e053-a505fe0a3de9
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109
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The intracellular trafficking mechanism of Lipofectamine-based transfection reagents and its implication for gene delivery, file e3835316-a782-15e8-e053-a505fe0a3de9
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102
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Plasmonics meets biology through optics, file e3835313-e93d-15e8-e053-a505fe0a3de9
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96
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Interplay of protein corona and immune cells controls blood residency of liposomes, file e3835324-17a1-15e8-e053-a505fe0a3de9
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96
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Efficient delivery of DNA using lipid nanoparticles, file 35c152ed-c1bc-48c9-957f-da99f7e42ffa
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87
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Optimal centrifugal isolating of liposome-protein complexes from human plasma, file e383532c-bb72-15e8-e053-a505fe0a3de9
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71
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Correction: Disease-specific protein corona sensor arrays may have disease detection capacity, file e3835325-1969-15e8-e053-a505fe0a3de9
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70
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Microfluidic formulation of DNA-loaded multicomponent lipid nanoparticles for gene delivery, file e383532e-0664-15e8-e053-a505fe0a3de9
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35
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Multiplexed detection of pancreatic cancer by combining a nanoparticle-enabled blood test and plasma levels of acute-phase proteins, file 07c9d2aa-13c8-456e-82c5-2813ee97fd57
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25
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Mechanistic insights into the release of doxorubicin from graphene oxide in cancer cells, file e3835328-ba66-15e8-e053-a505fe0a3de9
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24
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Personalized graphene oxide-protein corona in the human plasma of pancreatic cancer patients, file e383532e-5772-15e8-e053-a505fe0a3de9
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24
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Photo-thermal effects in gold nanorods/DNA complexes, file e383532e-a220-15e8-e053-a505fe0a3de9
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23
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Detection of pancreatic ductal adenocarcinoma by ex vivo magnetic levitation of plasma protein‐coated nanoparticles, file e383532e-2a18-15e8-e053-a505fe0a3de9
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22
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Killing cancer cells using nanotechnology: novel poly(I:C) loaded liposome-silica hybrid nanoparticles, file e3835313-eafd-15e8-e053-a505fe0a3de9
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21
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Effect of protein corona on the transfection efficiency of lipid-coated graphene oxide-based cell transfection reagents, file e383532d-f734-15e8-e053-a505fe0a3de9
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21
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The protein corona reduces the anticancer effect of graphene oxide in HER-2-positive cancer cells, file 68a71657-8e91-4df1-bbe7-808b319d058a
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17
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Microfluidic-generated lipid-graphene oxide nanoparticles for gene delivery, file e3835327-950d-15e8-e053-a505fe0a3de9
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16
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Inhibiting the growth of 3D brain cancer models with bio-coronated liposomal temozolomide, file e383532b-eb3f-15e8-e053-a505fe0a3de9
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12
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Insights into the effect of polyethylene terephthalate (PET) microplastics on HER2 signaling pathways, file 1f097d93-6f09-4922-bb5d-1b7598334843
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11
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A Proteomic Study on the Personalized Protein Corona of Liposomes. Relevance for Early Diagnosis of Pancreatic DUCTAL Adenocarcinoma and Biomarker Detection, file e383532f-2bef-15e8-e053-a505fe0a3de9
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11
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Magnetic Levitation of Personalized Nanoparticle–Protein Corona as an Effective Tool for Cancer Detection, file e383532f-0d4b-15e8-e053-a505fe0a3de9
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9
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Interaction of pH-sensitive non-phospholipid liposomes with cellular mimetic membranes, file e3835311-e5f2-15e8-e053-a505fe0a3de9
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8
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Reproducibility of biomolecular corona experiments: a primer for reliable results, file d4b93740-2c39-449e-9c9a-d0d162f2ef35
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5
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Toward an objective evaluation of cell transfection performance, file e3835311-f7ef-15e8-e053-a505fe0a3de9
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5
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Label-free quantitative analysis for studying the interactions between nanoparticles and plasma proteins, file e3835312-25d7-15e8-e053-a505fe0a3de9
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5
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A decade of the liposome-protein corona: lessons learned and future breakthroughs in theranostics, file 5b5b899d-459d-49fe-95bd-89fdd12fad43
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4
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The role of cytoskeleton networks on lipid-mediated delivery of DNA, file e3835312-422b-15e8-e053-a505fe0a3de9
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4
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Nanoparticle-biomolecular coron. A new approach for the early detection of non-small-cell lung cancer, file e383531e-07f1-15e8-e053-a505fe0a3de9
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4
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The biomolecular corona of gold nanoparticles in a controlled microfluidic environment, file e3835324-1cb8-15e8-e053-a505fe0a3de9
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4
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Disease-specific protein corona sensor arrays may have disease detection capacity, file e3835324-2447-15e8-e053-a505fe0a3de9
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3
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null, file e3835326-9493-15e8-e053-a505fe0a3de9
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3
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Mechanistic insights into the superior DNA delivery efficiency of multicomponent lipid nanoparticles: an in vitro and in vivo study, file b387ab7e-c53b-484c-ae10-e6399179d89c
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2
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Mechanistic understanding of gene delivery mediated by highly efficient multicomponent envelope-type nanoparticle systems, file e3835312-2790-15e8-e053-a505fe0a3de9
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2
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A proteomics-based methodology to investigate the protein corona effect for targeted drug delivery., file e3835312-f255-15e8-e053-a505fe0a3de9
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2
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The liposome–protein corona in mice and humans and its implications for in vivo delivery, file e3835312-ffe6-15e8-e053-a505fe0a3de9
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2
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Role of cholesterol on the transfection barriers of cationic lipid/DNA complexes, file e3835313-7467-15e8-e053-a505fe0a3de9
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2
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Surface chemistry and serum type both determine the nanoparticle–protein corona, file e3835316-49df-15e8-e053-a505fe0a3de9
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2
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Biophysics and protein corona analysis of Janus cyclodextrin-DNA nanocomplexes. Efficient cellular transfection on cancer cells, file e3835318-7a1c-15e8-e053-a505fe0a3de9
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2
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Applications of nanomaterials in modern medicine, file e383531b-25c3-15e8-e053-a505fe0a3de9
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2
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Tailoring Lipoplex Composition to the Lipid Composition of Plasma Membrane: A Trojan Horse for Cell Entry?, file e383531b-6640-15e8-e053-a505fe0a3de9
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2
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Improving the accuracy of pancreatic cancer clinical staging by exploitation of nanoparticle-blood interactions: A pilot study, file e3835320-5a30-15e8-e053-a505fe0a3de9
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2
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A comprehensive analysis of liposomal biomolecular corona upon human plasma incubation: the evolution towards the lipid corona, file e3835324-934f-15e8-e053-a505fe0a3de9
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2
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null, file e3835326-9494-15e8-e053-a505fe0a3de9
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2
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Protein corona profile of graphene oxide allows detection of glioblastoma multiforme using a simple one-dimensional gel electrophoresis technique. A proof-of-concept study, file e383532d-7aad-15e8-e053-a505fe0a3de9
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2
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Nanotechnology Meets Oncology: A Perspective on the Role of the Personalized Nanoparticle-Protein Corona in the Development of Technologies for Pancreatic Cancer Detection, file 2fbfce6f-4de4-455e-98cf-27047ee00c0e
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1
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Nanoscale structure of protamine/DNA complexes for gene delivery, file e3835311-caf1-15e8-e053-a505fe0a3de9
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1
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Time Evolution of Nanoparticle-Protein Corona in Human Plasma: Relevance for Targeted Drug Delivery, file e3835312-5660-15e8-e053-a505fe0a3de9
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1
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Analytical Methods for Characterizing the Nanoparticle-Protein Corona, file e3835312-f4d4-15e8-e053-a505fe0a3de9
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1
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Do plasma proteins distinguish between liposomes of varying charge density?, file e3835312-ff22-15e8-e053-a505fe0a3de9
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1
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Role of temperature-independent lipoplex-cell membrane interactions in the efficiency boost of multicomponent lipoplexes, file e3835313-7557-15e8-e053-a505fe0a3de9
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1
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Transfection efficiency boost of cholesterol-containing lipoplexes, file e3835313-8c5a-15e8-e053-a505fe0a3de9
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1
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Getting the most from gene delivery by repeated DNA transfections, file e3835313-eafe-15e8-e053-a505fe0a3de9
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1
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null, file e3835316-592f-15e8-e053-a505fe0a3de9
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1
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Manipulation of lipoplex concentration at the cell surface boosts transfection efficiency in hard-to-transfect cells, file e3835316-6415-15e8-e053-a505fe0a3de9
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1
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Lipid composition: a “key factor” for the rational manipulation of the liposome–protein corona by liposome design, file e3835316-8ba9-15e8-e053-a505fe0a3de9
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1
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null, file e3835316-8cd6-15e8-e053-a505fe0a3de9
|
1
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Exploitation of nanoparticle-protein corona for emerging therapeutic and diagnostic applications, file e3835316-97d8-15e8-e053-a505fe0a3de9
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1
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The protein corona of circulating PEGylated liposomes, file e383531b-15d1-15e8-e053-a505fe0a3de9
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1
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The biomolecular corona of nanoparticles in circulating biological media, file e383531d-54bc-15e8-e053-a505fe0a3de9
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1
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Cationic lipid/DNA complexes manufactured by microfluidics and bulk self-assembly exhibit different transfection behavior, file e3835320-18be-15e8-e053-a505fe0a3de9
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1
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Microfluidic manufacturing of surface-functionalized graphene oxide nanoflakes for gene delivery, file e3835320-18c3-15e8-e053-a505fe0a3de9
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1
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Effect of glucose on liposome–plasma protein interactions: relevance for the physiological response of clinically approved liposomal formulations, file e3835320-1fc5-15e8-e053-a505fe0a3de9
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1
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Brain Targeting by Liposome-Biomolecular Corona Boosts Anticancer Efficacy of Temozolomide in Glioblastoma Cells, file e3835320-5a35-15e8-e053-a505fe0a3de9
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1
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Human biomolecular corona of Liposomal Doxorubicin: the overlooked factor in anticancer drug delivery, file e3835322-369d-15e8-e053-a505fe0a3de9
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1
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null, file e3835326-9492-15e8-e053-a505fe0a3de9
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1
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Efficient pancreatic cancer detection through personalized protein corona of gold nanoparticles, file e383532c-10bf-15e8-e053-a505fe0a3de9
|
1
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| Totale |
2.212 |