The purpose of this is to analyse human exhaled breath by means of a device called electronic nose(eNose) in patients with non-alcoholic fatty liver disease (NAFLD) as a way to non-invasive assessment of liver disease.This device is medically adapted and clinically validated in patients with lung conditions.
Human exhaled breath contains over 3000 volatile organic compounds (VOCs) that vary in relative concentration in health and disease. Metabolic disorders affecting the liver, such as NAFLD, produce disproportionate organic compounds produced as a by-product of metabolism and thus expired in exhaled breath, excreted in urine and detectable in blood. NAFLD prevalence is increasing and has reached epidemic proportions affecting 90% of obese adults and 22%-53% of obese children.Liver biopsy is the gold standard in diagnosing NAFLD, but it is unpleasant and can lead to complications. There is an unmet need to develop a non-invasive method of assessing liver disease. Comon Invent (Delft, Netherlands) together with the respiratory department at the Amsterdam Medical Centre (AMC), University of Amsterdam, have adapted the electronic nose known as SpiroNose as a prototype device for clinical use. Sensitive electronic sensors detect molecules in breath and generate signals. Complex algorithms and analytical technics allow pattern recognition of breath samples from different subjects. Well charaterised patients will be selected into clinical categories of non-alcoholic fatty liver disease with and without cirrhosis and be compared with healthy individuals. Edinburgh will be the only site conducting this study. In addition to exhaled breath analysis, blood and urine will be collected to study the end products of metabolism.Furthermore, stool and urine collected from some subjects will be analysed to understand the role of gut bacteria in fermentation, metabolic products as a result cause VOC production.
Study Type
OBSERVATIONAL
Enrollment
90
Patients and Healthy volunteers ( as defined in 3 cohorts) will breath into disposable, once-use only bacterial filter channeled into electronic device comprising on sensors capable to reacting to organic compounds. Breathing manoeuvre will be simple, non-exertional and relaxed. 2 breathing manoeuvres will be performed and sensor responses will be captured.
Clinical Research Facility - Wellcome Trust, Royal Infirmary Site
Edinburgh, Midlothian, United Kingdom
Characterise the electronic signature "breath-print" in pre-defined cohorts
Identify disease specific electronic nose wave pattern
Time frame: 12 months
Characterisation of exhaled breath composition
Molecular characterisation of breath volatile organic compounds through Gas Chromatography and Mass Spectrometry
Time frame: 12 months
Profiling intestinal microbiome and assessing end-metabolic products in urine
Demonstrate dysbiosis in stool microbial and characterise metabolic products in urine of cohorts studied
Time frame: 12 months
This platform is for informational purposes only and does not constitute medical advice. Always consult a qualified healthcare professional.