Contamination of nanoparticles by endotoxin: evaluation of different test methods.
about
Endotoxin contamination: a key element in the interpretation of nanosafety studiesPre-clinical immunotoxicity studies of nanotechnology-formulated drugs: Challenges, considerations and strategyValue of phagocyte function screening for immunotoxicity of nanoparticles in vivoAcute exposure to silica nanoparticles enhances mortality and increases lung permeability in a mouse model of Pseudomonas aeruginosa pneumoniaToxicity of nanoparticles embedded in paints compared with pristine nanoparticles in miceComprehensive In Vitro Toxicity Testing of a Panel of Representative Oxide Nanomaterials: First Steps towards an Intelligent Testing StrategyProvenance information as a tool for addressing engineered nanoparticle reproducibility challengesEndotoxin Contamination in Nanomaterials Leads to the Misinterpretation of Immunosafety Results.MyD88-dependent pro-interleukin-1β induction in dendritic cells exposed to food-grade synthetic amorphous silica.PEGylation of cationic, shell-crosslinked-knedel-like nanoparticles modulates inflammation and enhances cellular uptake in the lung.Human health risk of ingested nanoparticles that are added as multifunctional agents to paints: an in vitro studyEndotoxin contamination of apolipoprotein A-I: effect on macrophage proliferation--a cautionary tale.The in-vivo use of superparamagnetic iron oxide nanoparticles to detect inflammation elicits a cytokine response but does not aggravate experimental arthritis.Detection of Endotoxin Contamination of Graphene Based Materials Using the TNF-α Expression Test and Guidelines for Endotoxin-Free Graphene Oxide Production.Comparative inhalation toxicity of multi-wall carbon nanotubes, graphene, graphite nanoplatelets and low surface carbon black.Nanosafety research--are we on the right track?Lipopolysaccharide Adsorbed to the Bio-Corona of TiO2 Nanoparticles Powerfully Activates Selected Pro-inflammatory Transduction Pathways.Calcium phosphate particles induce interleukin-8 expression in a human gingival epithelial cell line via the nuclear factor-κB signaling pathway.Choice of method for endotoxin detection depends on nanoformulation.Graphene and the Immune System: A Romance of Many Dimensions.Cytotoxic effects of nanosilver are highly dependent on the chloride concentration and the presence of organic compounds in the cell culture mediaIron oxide nanoparticles modulate lipopolysaccharide-induced inflammatory responses in primary human monocytes.Platinum nanozymes recover cellular ROS homeostasis in an oxidative stress-mediated disease model.Interference of silica nanoparticles with the traditional Limulus amebocyte lysate gel clot assay.Local Effects on Airway Inflammation and Systemic Uptake of 5 nm PEGylated and Citrated Gold Nanoparticles in Asthmatic Mice.Graphene and carbon nanotubes activate different cell surface receptors on macrophages before and after deactivation of endotoxins.A rapid screening method to evaluate the impact of nanoparticles on macrophages.Differences in MWCNT- and SWCNT-induced DNA methylation alterations in association with the nuclear deposition.Limulus amoebocyte lysate test via an open-microcavity optical biosensor.Determining the relationship between nanoparticle characteristics and immunotoxicity: key challenges and approaches.The DaNa2.0 Knowledge Base Nanomaterials-An Important Measure Accompanying Nanomaterials Development.Nanosicherheitsforschung - sind wir auf dem richtigen Weg?Nano-TiO2modulates the dermal sensitization potency of dinitrochlorobenzene after topical exposureOptimising the use of commercial LAL assays for the analysis of endotoxin contamination in metal colloids and metal oxide nanoparticles
P2860
Q28071776-5F4CE47D-56FA-47DF-96A8-FBE52B68B09BQ28081577-5D3D2B2F-4531-414E-98F9-5712E9952511Q28084932-CF7F2681-6468-4D56-BAD5-2677C9E57486Q28387365-D9AEA343-1105-4E3D-8BAE-C6DC0305AE1AQ28392281-5FB3899A-7828-4EDD-BBBA-0157F256DA38Q28394673-7253C138-44A2-47C7-A8E1-0F42AEB0CAC0Q29048614-FB47BF45-6783-4494-810F-A1BBD80FC923Q33645662-52B031FB-CF3E-4F4E-AA0F-BA33E6CD91FEQ33827649-9FF24F4E-158E-4E06-BF77-C0527DC849C2Q34604942-7580D5CA-50BA-4D72-8190-F7C1138CF577Q35073035-5CE15CAF-281F-4E4F-B1B5-14EECFCA705FQ35418139-DB4D1732-4D24-43F1-A06A-3B6BD73152CDQ35587047-F67CD208-EBFC-4627-90D3-8CA7E7A66338Q36202649-BC3B1219-F5AF-4B44-8134-CB01ABA87FA1Q37037991-AE338EAE-FE77-4F4D-87EE-0C7F5B5A94D7Q38258828-D4C69A2D-9181-4FF1-A8B7-22640C8AF58CQ38616701-B4E7B06A-D638-49B9-A7C5-4B5A7CA01571Q39002081-B079FC25-BC0E-444C-9F80-F14DB45CCB55Q39041437-8BEF64A9-340A-433D-A15D-F9D5CA194E5EQ39403516-56DC98C8-E882-483D-84AB-E65B8569F287Q40948454-E3C43C45-D505-40E5-8E1E-9DF5C1A5A781Q41123309-CC33D237-918B-48CE-91D9-58251E64C730Q46604327-B9F65CFD-947E-4A68-8943-971BEF7C7F66Q47942103-CED0B80A-33CD-4085-B2D9-77493279AE7EQ48012996-BE13619B-2F8A-4FAD-ACD4-F73EC960B591Q48171720-D5697A8C-FA93-43E4-8453-42D023BCF28FQ48285320-66A690D3-9398-454F-8E48-71E16D7119CFQ49537557-9C5DF684-9589-46E9-99A5-C31C1FE8A37CQ50057023-F3C97BBE-22AC-4EDB-A646-192C80ED0B52Q53755427-ED4F3116-A733-4343-9D59-66BC3CCF9B10Q55259891-20D5F598-BB63-42A7-B799-817B90C328A4Q55931657-6457240C-256A-4811-BAB9-353F9DC2B96DQ57009956-33737FC9-8BAF-4607-8E3C-591B0FBA820CQ58742973-155844BB-1FA7-4BD1-A9B8-A6AD4BB4172A
P2860
Contamination of nanoparticles by endotoxin: evaluation of different test methods.
description
2012 nî lūn-bûn
@nan
2012年の論文
@ja
2012年学术文章
@wuu
2012年学术文章
@zh-cn
2012年学术文章
@zh-hans
2012年学术文章
@zh-my
2012年学术文章
@zh-sg
2012年學術文章
@yue
2012年學術文章
@zh
2012年學術文章
@zh-hant
name
Contamination of nanoparticles by endotoxin: evaluation of different test methods.
@en
Contamination of nanoparticles by endotoxin: evaluation of different test methods.
@nl
type
label
Contamination of nanoparticles by endotoxin: evaluation of different test methods.
@en
Contamination of nanoparticles by endotoxin: evaluation of different test methods.
@nl
prefLabel
Contamination of nanoparticles by endotoxin: evaluation of different test methods.
@en
Contamination of nanoparticles by endotoxin: evaluation of different test methods.
@nl
P2093
P2860
P356
P1476
Contamination of nanoparticles by endotoxin: evaluation of different test methods.
@en
P2093
Jean-Pierre Kaiser
Kirsten L Van Landuyt
Luana Golanski
Peter Hm Hoet
Peter Wick
Stefano Zuin
Stijn Smulders
P2860
P2888
P356
10.1186/1743-8977-9-41
P577
2012-11-09T00:00:00Z
P5875
P6179
1002878295