about
The interplay of the gut microbiome, bile acids, and volatile organic compoundsDetection of colorectal cancer (CRC) by urinary volatile organic compound analysisDifferentiating coeliac disease from irritable bowel syndrome by urinary volatile organic compound analysis--a pilot studyRapid, accurate, and on-site detection of C. difficile in stool samples.Non-invasive exhaled volatile organic biomarker analysis to detect inflammatory bowel disease (IBD).The detection of patients at risk of gastrointestinal toxicity during pelvic radiotherapy by electronic nose and FAIMS: a pilot studyVariation in Gas and Volatile Compound Emissions from Human Urine as It Ages, Measured by an Electronic NoseApplication of a novel tool for diagnosing bile acid diarrhoea.The application of FAIMS gas analysis in medical diagnostics.Breathomics--exhaled volatile organic compound analysis to detect hepatic encephalopathy: a pilot study.A simple breath test for tuberculosis using ion mobility: A pilot study.Non-invasive distinction of non-alcoholic fatty liver disease using urinary volatile organic compound analysis: early results.Development and application of a new electronic nose instrument for the detection of colorectal cancer.Detection of potato storage disease via gas analysis: a pilot study using field asymmetric ion mobility spectrometryFabrication of 3-dimensional cellular constructs via microstereolithography using a simple, three-component, poly(ethylene glycol) acrylate-based system.A novel tool for noninvasive diagnosis and tracking of patients with inflammatory bowel disease.Dissolution kinetics of polycrystalline calcium sulfate-based materials: influence of chemical modification.Ultrasensitive detection of dopamine using a carbon nanotube network microfluidic flow electrode.Identifying volatile metabolite signatures for the diagnosis of bacterial respiratory tract infection using electronic nose technology: A pilot study.Non-invasive Diagnosis of Pancreatic Cancer Through Detection of Volatile Organic Compounds in Urine.Faecal volatile organic compounds analysis using field asymmetric ion mobility spectrometry: non-invasive diagnostics in paediatric inflammatory bowel disease.Evaluation of gut bacterial populations using an electronic e-nose and field asymmetric ion mobility spectrometry: further insights into 'fermentonomics'.Towards a truly biomimetic olfactory microsystem: an artificial olfactory mucosa.Editorial: Metabolomic analysis of breath volatile organic compounds--a new scent for inflammatory bowel disease.Fabrication of versatile channel flow cells for quantitative electroanalysis using prototyping.The Effect of Film Thickness on the Gas Sensing Properties of Ultra-Thin TiO₂ Films Deposited by Atomic Layer Deposition.An improved machine learning pipeline for urinary volatiles disease detection: Diagnosing diabetesLate-onset Sepsis in Preterm Infants Can Be Detected Preclinically by Fecal Volatile Organic Compound Analysis: A Prospective, Multicenter Cohort StudyNon-Invasive Diagnosis of Diabetes by Volatile Organic Compounds in Urine Using FAIMS and Fox4000 Electronic NoseNon-Invasive Detection of Anastomotic Leakage Following Esophageal and Pancreatic Surgery by Urinary Analysis.Post-CMOS wafer level growth of carbon nanotubes for low-cost microsensors--a proof of conceptInsights into 'fermentonomics': evaluation of volatile organic compounds (VOCs) in human disease using an electronic 'e-nose'Electronic nose versus canine nose: clash of the titansMimicking the biological olfactory system: a Portable electronic MucosaRapid manufacture of monolithic micro-actuated forceps inspired by echinoderm pedicellariaeDifferentiation Between Pediatric Irritable Bowel Syndrome and Inflammatory Bowel Disease Based on Fecal Scent: Proof of Principle StudyOptimized Sampling Conditions for Fecal Volatile Organic Compound Analysis by Means of Field Asymmetric Ion Mobility SpectrometryBreath Analysis Using eNose and Ion Mobility Technology to Diagnose Inflammatory Bowel Disease-A Pilot StudyDetection of Group B Streptococcus in pregnancy by vaginal volatile organic compound analysis: a prospective exploratory studySimultaneous Assessment of Urinary and Fecal Volatile Organic Compound Analysis in De Novo Pediatric IBD
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Q28082012-51673683-9D07-43CA-9C80-8F5259C35392Q28543425-CB61D5E4-A172-4DAA-8733-FEE3C04F7F3EQ28543828-17942B21-EA2F-4430-9CC7-6C8B66E56FAEQ34469362-13DD41BE-82D8-4D0C-8316-F3F35E4C6D86Q35872914-8076EC44-A707-48FE-9FDD-314DC84CB71DQ36534462-AB46A306-B257-497B-BCB3-7ED5B6EC9108Q36736010-D2415384-C4E0-46B0-928A-5182982DBC74Q37290508-9CE30E04-F961-45AC-92B4-63BAB1883DABQ38553136-14E9FA26-490C-4E96-8C80-D395279A54E4Q38909538-A2B4028B-EFBD-4E22-876B-61E12E5F4A94Q39421505-41F9EAE4-7920-4EA1-BD6B-0B2CA5403AA7Q40794447-B28E73A1-1E8B-4500-BB4D-501CA0CEAA67Q41736729-F585DC8F-EE94-4F65-8EA8-FE5C0947875DQ41900113-9819D79B-0752-4713-B493-2964F8B7FCEBQ43898459-F4D41AAF-F2B8-402D-A61A-F6B3970DB625Q44109663-BDECD1D7-4D47-4510-A020-0EA86B433153Q45894162-5BB02BC1-E620-4EA8-AF06-15E06D584E46Q46700428-114BC8BA-A894-4B3E-8EBE-4251558BC1DDQ47134751-6D8AE6EB-8778-47DB-A73D-3406F1E42F7CQ47356857-93C48859-9514-49DF-92FA-BFF944B2AD29Q47911056-61866860-6C4B-46C1-8AE2-3DA1758D1CDDQ48776572-0EFC15DA-BC80-4C3B-9920-684BE01FC749Q51027265-030B173F-BE9A-4BCF-8949-02FDCBB80FFDQ51704007-3425909A-4E02-4D67-8373-A00684109198Q51711790-DD788BBA-620B-4C80-ADAB-A1048DF0ABEAQ53443797-4AFB3F97-751B-4B52-9C8C-2283123EC2D0Q58691740-2F157D55-5C61-441C-8588-70484E9EFF05Q59173616-BB10EA98-40FE-4B66-9841-D00A3837FEA3Q60922096-78753E3F-D430-49E1-837D-35C243F0838CQ64970383-186D9F0A-AC76-4426-A684-D8A5B2BCD576Q82316798-311D2DD0-2635-4509-A172-B2A31E760554Q83122060-2CC03A91-2BFA-45A0-8C0C-D96A8B62014DQ83706614-797F42F2-D23B-4837-B276-A81D62C23A7EQ84071740-44186E21-C332-4A10-8CBC-48C28432E676Q84569933-EB40A94E-824A-4055-A87C-3ECD0C92C13AQ88774953-952A7F6C-7BE2-448B-9F6D-0536138F8B5FQ88962703-A47A8F74-7332-4BC5-949B-4786833E0E1AQ90240014-BB296B34-B14B-42D5-924A-740C964DB048Q90484005-6E1410D9-884D-4543-A0C8-6E6FD9EE6EEBQ90775624-2B116895-EA70-4AF4-B45D-38B419DA8BFC
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description
hulumtues
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onderzoeker
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researcher
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հետազոտող
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James A. Covington
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James A. Covington
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James A. Covington
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James A. Covington
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James A. Covington
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James A. Covington
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James A. Covington
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James A. Covington
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James A. Covington
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James A. Covington
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James A. Covington
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James A. Covington
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James A. Covington
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James A. Covington
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James A. Covington
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P1153
7005284700
P21
P2456
P31
P496
0000-0003-1307-6488