about
Characterization of a Dipartite Iron Uptake System from Uropathogenic Escherichia coli Strain F11The Haber-Weiss cycle--70 years laterBioavailability of metal ions and evolutionary adaptationA fresh view of the cell biology of copper in enterobacteria.Efficient degradation of phenol using natural clay as heterogeneous Fenton-like catalyst.Targeting iron metabolism in drug discovery and deliveryProteomic analysis of the copper resistance of Streptococcus pneumoniae.Nfu facilitates the maturation of iron-sulfur proteins and participates in virulence in Staphylococcus aureus.The teratogenicity and the action mechanism of gallic acid relating with brain and cervical musclesBiomarkers of OH radical damage in vivo.Challenges in the chemotherapy of Chagas disease: Looking for possibilities related to the differences and similarities between the parasite and host.Heterogeneous fenton catalysts based on activated carbon and related materials.Iron metabolism in man.Oxidative and nitrative alpha-synuclein modifications and proteostatic stress: implications for disease mechanisms and interventions in synucleinopathies.Electrochemical advanced oxidation and biological processes for wastewater treatment: a review of the combined approaches.Recent developments in understanding the iron acquisition strategies of gram positive pathogens.The Janus face of iron on anoxic worlds: iron oxides are both protective and destructive to life on the early Earth and present-day Mars.Heavy metal transport by the CusCFBA efflux system.The biological chemistry of the transition metal "transportome" of Cupriavidus metallidurans.In vivo ROS production and use of oxidative stress-derived biomarkers to detect the onset of diseases such as Alzheimer's disease, Parkinson's disease, and diabetes.Lactoferrin directly scavenges hydroxyl radicals and undergoes oxidative self-degradation: a possible role in protection against oxidative DNA damageMechanism of the catalytic deperoxidation of tert-butylhydroperoxide with cobalt(II) acetylacetonate.Suppression of MKK5 reduces ozone-induced signal transmission to both MPK3 and MPK6 and confers increased ozone sensitivity in Arabidopsis thaliana.Sunlight and free radicals.Increasing the ketone selectivity of the cobalt-catalyzed radical chain oxidation of cyclohexane.Experimental phasing using zinc and sulfur anomalous signals measured at the zinc absorption peak.Dual fluorescence nanoconjugates for ratiometric detection of reactive oxygen species in inflammatory cells.Synergistic gold-copper detoxification at the core of gold biomineralisation in Cupriavidus metallidurans.Photoactivation and relaxation studies on the cyanobacterial orange carotenoid protein in the presence of copper ion.Iron oxides (inhalable fraction) [MAK Value Documentation, 2011]ANTIOXIDANT ENZYME RESPONSE AND REACTIVE OXYGEN SPECIES PRODUCTION IN MARINE RAPHIDOPHYTES1Facile synthetic fabrication of iron oxide particles and novel hydrogen superoxide supercapacitorsEffect of ocean warming and acidification on the Fe(II) oxidation rate in oligotrophic and eutrophic natural watersAntioxidant Defenses and Trace Metal Bioaccumulation Capacity of Cymbula nigra (Gastropoda: Patellidae)
P2860
Q27667898-E53BEA78-9FA1-4F2A-BE82-0406DDD355E2Q28201133-150A0541-660F-4505-BE22-3074A79DA4C7Q28655003-2CE9D389-3695-40CB-ADDE-BDCEC91F1FADQ30317940-046306AB-3166-47CB-B0D5-417CADE1BD50Q33459899-0F39613C-1FBB-4397-AC01-D4A74DB9CF41Q33757232-95FAC9D1-7AD6-48DB-A0C0-783FC586FBEFQ35546786-DDD8FA74-7347-4258-BCB2-67A10DE41D3BQ35596266-B73DADB9-89BC-4953-8E44-00382B493397Q35648188-3A616303-81DE-4CBE-834B-C59FEC185BB8Q36402082-7FEFABE9-A5F7-47D5-BA49-30EB53228D2FQ37670897-ECC9C754-9A6A-4AB8-9E60-1F76CF0DC982Q37967659-132FF832-CA05-4FDE-AD76-8E233E14B2D7Q38042571-1F180F60-BBEC-45DE-808E-6492C11C0DDBQ38085689-A58A0346-2B9E-41A8-AF15-D289D10843C0Q38223240-25029AC4-71AF-4F2B-8905-32F8D8467BDBQ38415707-EAFB5688-0A22-4402-A0DB-5151019E13EEQ38431566-30A140F9-EF72-4E92-9D19-193B4D450B17Q38563751-B1DBDDE8-5FF2-4E16-A054-9FE626E8AC61Q38804600-DA169577-4D24-4C6D-B22A-3FE24B5F183CQ39217187-241AAAAE-BAA5-4460-9B57-A993136AC3B3Q41902041-D00BB684-DE1E-49A3-B9BD-8580CD641A91Q42859463-041BD216-B45D-417F-B8B7-9F2F749F6C77Q42943709-9D74CA5E-D3AD-4C79-A7C9-7B8E5F469DDDQ43470087-9F2F6A01-11E7-4960-B1F7-1C306FFC5B52Q44119707-7246F73E-7F02-43F6-AA94-A3548728EDF3Q44516881-F076EF52-64C3-4FF6-8FD1-503F7291B9BAQ46337112-70D985A6-59F5-4AB6-82C9-AD3AAD2F121EQ48296839-82421CA0-4067-4C6C-86ED-C814A6CF6358Q50214053-BDF4E107-99D1-4791-87AF-47A1E62A02A1Q56211650-509A1692-55D0-485E-A3CC-681FA458A1B1Q57235402-DA6EBE8D-C604-4BAA-882B-784012C0B3CBQ57756247-7AC6DCF8-F7DE-4249-B74B-1F2173CF190FQ58067504-921E6977-EA70-4895-8701-546888509A9AQ58151251-16221A84-10AD-4671-B9CE-496CAF43A615
P2860
description
1932 nî lūn-bûn
@nan
1932 թուականի Դեկտեմբերին հրատարակուած գիտական յօդուած
@hyw
1932 թվականի դեկտեմբերին հրատարակված գիտական հոդված
@hy
1932年の論文
@ja
1932年論文
@yue
1932年論文
@zh-hant
1932年論文
@zh-hk
1932年論文
@zh-mo
1932年論文
@zh-tw
1932年论文
@wuu
name
Über die Katalyse des Hydroperoxydes
@ast
Über die Katalyse des Hydroperoxydes
@en
type
label
Über die Katalyse des Hydroperoxydes
@ast
Über die Katalyse des Hydroperoxydes
@en
prefLabel
Über die Katalyse des Hydroperoxydes
@ast
Über die Katalyse des Hydroperoxydes
@en
P356
P1433
P1476
Über die Katalyse des Hydroperoxydes
@en
P2093
P2888
P304
P356
10.1007/BF01504715
P577
1932-12-01T00:00:00Z
P6179
1050537720