about
Reduction of Coxiella burnetii prevalence by vaccination of goats and sheep, The NetherlandsTick-borne infections in human and animal population worldwideQ fever in French GuianaEpidemiology of Coxiella burnetii infection in Africa: a OneHealth systematic reviewRapid, simple and sensitive detection of Q fever by loop-mediated isothermal amplification of the htpAB geneIn vitro and in vivo infectious potential of coxiella burnetii: a study on Belgian livestock isolatesQ28069944Emerging horizons for tick-borne pathogens: from the 'one pathogen-one disease' vision to the pathobiome paradigmWind-Mediated Spread of Low-Pathogenic Avian Influenza Virus into the Environment during Outbreaks at Commercial Poultry FarmsMALDI-TOF mass spectrometry and identification of new bacteria species in air samples from Makkah, Saudi ArabiaPresence of antibodies against Coxiella burnetii and risk of spontaneous abortion: a nested case-control studyAnalysis of the Caenorhabditis elegans innate immune response to Coxiella burnetiiFrom Q Fever to Coxiella burnetii Infection: a Paradigm Change.Coxiella burnetii (Q-Fever) Seroprevalence in Prey and Predators in the United Kingdom: Evaluation of Infection in Wild Rodents, Foxes and Domestic Cats Using a Modified ELISA.Seroprevalence of Q fever among human and animal in Iran; A systematic review and meta-analysis.Acute Q fever in febrile patients in northwestern of IranGenotyping of Coxiella burnetii from domestic ruminants and human in Hungary: indication of various genotypes.Surveys on Coxiella burnetii infections in Swedish cattle, sheep, goats and moose.Increasing prevalence of Coxiella burnetii seropositive Danish dairy cattle herdsThe prevalence of Coxiella burnetii infection in wild Korean water deer, Korea.Quantitative proteome profiling of C. burnetii under tetracycline stress conditions.Exposure and risk factors to coxiella burnetii, spotted fever group and typhus group Rickettsiae, and Bartonella henselae among volunteer blood donors in NamibiaCoxiella burnetii in central Italy: novel genotypes are circulating in cattle and goats.Development of a lipopolysaccharide-targeted peptide mimic vaccine against Q feverQ fever in pregnant goats: pathogenesis and excretion of Coxiella burnetii.Coxiella burnetii acid phosphatase inhibits the release of reactive oxygen intermediates in polymorphonuclear leukocytes.Genotyping of Coxiella burnetii from domestic ruminants in northern Spain.The contribution of proteomics towards deciphering the enigma of Coxiella burnetii.Prevalence of tick-borne pathogens in Ixodes ricinus and Dermacentor reticulatus ticks from different geographical locations in Belarus.No excess risk of adverse pregnancy outcomes among women with serological markers of previous infection with Coxiella burnetii: evidence from the Danish National Birth Cohort.Characterization of a lipopolysaccharide-targeted monoclonal antibody and its variable fragments as candidates for prophylaxis against the obligate intracellular bacterial pathogen Coxiella burnetii.Persistent high IgG phase I antibody levels against Coxiella burnetii among veterinarians compared to patients previously diagnosed with acute Q fever after three years of follow-up.A model for the early identification of sources of airborne pathogens in an outdoor environment.Characteristics of hospitalized acute Q fever patients during a large epidemic, The Netherlands.Q fever in France, 1985-2009.Cell-free propagation of Coxiella burnetii does not affect its relative virulenceHost cell autophagy in immune response to zoonotic infections.Proteomics paves the way for Q fever diagnostics.The Recent Evolution of a Maternally-Inherited Endosymbiont of Ticks Led to the Emergence of the Q Fever Pathogen, Coxiella burnetiiQ Fever: current state of knowledge and perspectives of research of a neglected zoonosis.
P2860
Q24605999-A5B4A200-82B7-4CC6-950C-74ADBDD18EDBQ26752436-C38EFE1A-EF9C-41B7-BAD5-88A965835472Q26996435-76960142-4278-416B-A8A4-CB87F835F994Q27304936-DE547314-2CC7-4F73-9F39-4203A68DFE61Q27305191-FBDEF16C-EF25-4C50-946B-7F41FE4F185DQ27311848-1F467F72-9401-4CC2-AD52-5E29CF2F2DDDQ28069944-5488D0C9-88B6-4666-8CB9-DEC7531457CBQ28085222-E5BD9252-CEE4-41F2-AFBD-0424901BC61AQ28393459-65010E11-2056-4743-A478-40EED14A4413Q28652218-B4AFCA84-3BB9-4D5A-9BB8-6A53F70945E4Q28731875-DAD19CFD-893F-45A2-8283-FBB9BED449ADQ28818232-1E5CE035-4816-40C1-A103-C557DCB4C316Q30241105-ADD244F6-951E-4F46-BC59-5F74EFE56892Q31149025-8AC2708B-4EA1-4676-868E-D4BAD1BD06C5Q33585323-E052D27E-0D4F-487C-AD58-004FD628AB49Q33585352-EEC3DD13-74DF-4EC3-8761-996A14573FF2Q33593541-102DD1CE-D1BE-40FE-B194-98D28DEAA8C2Q33957613-9787AA1D-8A85-4480-80F2-BA269D4A0EA2Q33969964-8B6E64C4-51A3-4123-81F2-C0ADF8CAC4BBQ34085431-26F41B31-93E1-455F-8E56-AF79C14D5B52Q34206345-2B028893-A586-4748-A0B6-B717E68D9185Q34258779-F6A08820-5B6F-4D5D-BCB5-92CF57AC6CC5Q34399694-F8797358-55E9-468C-AC18-50F2E3CBE483Q34440031-A5961E7A-8190-4055-9B7B-63BC3BBA5087Q34477583-ECF1D6B0-0036-4A4B-BC5E-7D1EA68EA2F6Q34484432-32860F1D-AA89-49CF-9106-220DDC65E403Q34507559-4E38A45D-FF12-47EE-847F-835DCF7367D5Q34518728-BEDE0755-DF72-448E-BB51-329EB6D2D9C6Q34563144-F4D77584-9046-4A62-98B5-768C6B779FB3Q34588226-B7234A38-E177-429F-90AF-B7EB450E3C4EQ34596111-1C800726-756A-4843-84D2-DCE5873F0023Q34989557-138F4390-82B6-4881-ABEC-7FE2874107D1Q35063730-AAF64466-4FCE-40BC-A07B-A376190BA3B3Q35116446-9BEC4BBE-5F3E-4A78-BCA1-0B11C9E24F64Q35193465-68BC8BE6-357A-4879-A8EB-933B620B29CCQ35203046-013459BB-AE25-4BD2-8974-251F97D25AEEQ35494248-30B6F737-9500-431D-838B-4981B032D591Q35565714-BB03225A-FE76-46CE-A646-11C6BDFFB841Q35610511-7832E36F-A6D4-4B7C-9125-2BD7081FEF3AQ35615074-2DCDDA59-B8CC-4024-B4A5-9F82D5B6E685
P2860
description
im Januar 2010 veröffentlichter wissenschaftlicher Artikel
@de
наукова стаття, опублікована в січні 2010
@uk
name
Q fever
@en
type
label
Q fever
@en
prefLabel
Q fever
@en
P1476
Q fever
@en
P2093
Emmanouil Angelakis
P304
P356
10.1016/J.VETMIC.2009.07.016
P577
2010-01-01T00:00:00Z