Can volatile compounds in exhaled breath be used to monitor control in diabetes mellitus?

Although it has been known for centuries that there are compounds in exhaled breath that are altered in disease, it is only in the last few decades that it has been possible to measure them with sufficient accuracy and precision to make them clinically useful. The clinical utility of breath analysis has also been limited by the practical difficulties of collecting representative breath samples, free from contaminants. More recent methods of breath analysis have allowed real-time analysis of breath, eliminating the need for sample collection, and therefore potentially allowing the rapid feedback of results to patient and clinician. One possible future application of breath analysis may be the monitoring of metabolic control in patients with diabetes mellitus. This perspective article provides an overview of the studies of breath analysis in diabetes, focusing on the breath metabolites; acetone, isoprene and also methyl nitrate that have previously been reported to be altered in diabetes, highlighting the factors that may potentially confound their interpretation. Specific attention is given to selected ion flow tube mass spectrometry (SIFT-MS) and proton transfer reaction mass spectrometry (PTR-MS), because they are techniques that have been developed specifically for the absolute quantification of breath metabolites in real time, although reference is made to some of the alternative techniques, including sensors and optical devices. Whilst breath analysis, using SIFT-MS, PTR-MS and other sensitive techniques, can potentially be used for the non-invasive monitoring of metabolic conditions that may include diabetes mellitus, further work is required in terms of the clinical and analytical validation. Furthermore, it is unclear at present what breath metabolites should be monitored and what factors may confound their interpretation. Although a non-invasive method of monitoring glycaemic control is clearly desirable, it will be important to demonstrate its analytical comparability with the well-established and validated methods for blood glucose measurement.

[1]  T. Tsuda,et al.  Relationship between skin acetone and blood β-hydroxybutyrate concentrations in diabetes , 2006 .

[2]  X. Zhang,et al.  Determination of acetone in human breath by gas chromatography-mass spectrometry and solid-phase microextraction with on-fiber derivatization. , 2004, Journal of chromatography. B, Analytical technologies in the biomedical and life sciences.

[3]  P. Lirk,et al.  Medical applications of proton transfer reaction-mass spectrometry: ambient air monitoring and breath analysis , 2004 .

[4]  Sotiris E Pratsinis,et al.  Si:WO(3) Sensors for highly selective detection of acetone for easy diagnosis of diabetes by breath analysis. , 2010, Analytical chemistry.

[5]  Simone Meinardi,et al.  Breath ethanol and acetone as indicators of serum glucose levels: an initial report. , 2005, Diabetes technology & therapeutics.

[6]  T. Jones,et al.  Diabetes care, glycemic control, and complications in children with type 1 diabetes from Asia and the Western Pacific Region. , 2007, Journal of diabetes and its complications.

[7]  Shaun W. Lawson,et al.  Canine responses to hypoglycemia in patients with type 1 diabetes. , 2008, Journal of alternative and complementary medicine.

[8]  J G Hamilton,et al.  Needle phobia: a neglected diagnosis. , 1995, The Journal of family practice.

[9]  Christopher Walton,et al.  Breath acetone concentration decreases with blood glucose concentration in type I diabetes mellitus patients during hypoglycaemic clamps , 2009, Journal of breath research.

[10]  F. Leturcq,et al.  Factors Associated With Glycemic Control: A cross-sectional nationwide study in 2,579 French children with type 1 diabetes , 1998, Diabetes Care.

[11]  David Smith,et al.  Progress in SIFT-MS: breath analysis and other applications. , 2011, Mass spectrometry reviews.

[12]  M. J. Henderson,et al.  Acetone in the Breath: A Study of Acetone Exhalation in Diabetic and Nondiabetic Human Subjects , 1952, Diabetes.

[13]  M. O’Hara,et al.  Development of a protocol to measure volatile organic compounds in human breath: a comparison of rebreathing and on-line single exhalations using proton transfer reaction mass spectrometry , 2008, Physiological measurement.

[14]  P. Španěl,et al.  Ionic diffusion and mass discrimination effects in the new generation of short flow tube SIFT-MS instruments , 2009 .

[15]  L. Niskanen,et al.  Interaction between cholesterol and glucose metabolism during dietary carbohydrate modification in subjects with the metabolic syndrome. , 2006, The American journal of clinical nutrition.

[16]  G. Hanna,et al.  Repeatability of the measurement of exhaled volatile metabolites using selected ion flow tube mass spectrometry , 2010, Journal of the American Society for Mass Spectrometry.

[17]  Ralf Zimmermann,et al.  Automated needle trap heart-cut GC/MS and needle trap comprehensive two-dimensional GC/TOF-MS for breath gas analysis in the clinical environment. , 2010, Analytical chemistry.

[18]  T. Clutton-Brock,et al.  Endogenous volatile organic compounds in breath and blood of healthy volunteers: examining breath analysis as a surrogate for blood measurements , 2009, Journal of breath research.

[19]  David Smith,et al.  A general method for the calculation of absolute trace gas concentrations in air and breath from selected ion flow tube mass spectrometry data , 2006 .

[20]  A. Gelperin,et al.  Volatile metabolic monitoring of glycemic status in diabetes using electronic olfaction. , 2004, Diabetes technology & therapeutics.

[21]  R. Peverall,et al.  Trace species detection in the near infrared using Fourier transform broadband cavity enhanced absorption spectroscopy: initial studies on potential breath analytes. , 2011, The Analyst.

[22]  P. Španěl,et al.  Volatile metabolites in the exhaled breath of healthy volunteers: their levels and distributions , 2007, Journal of breath research.

[23]  Chengyin Shen,et al.  Proton Transfer Reaction Mass Spectrometry (PTR‐MS) , 2012 .

[24]  M. Shepherd,et al.  A Study on Breath Acetone in Diabetic Patients Using a Cavity Ringdown Breath Analyzer: Exploring Correlations of Breath Acetone With Blood Glucose and Glycohemoglobin A1C , 2010, IEEE Sensors Journal.

[25]  P. Rolfe,et al.  The Selected Ion Flow Tube Method for Workplace Analyses of Trace Gases in Air and Breath: Its Scope, Validation, and Applications , 1998 .

[26]  M. Kalapos,et al.  On the mammalian acetone metabolism: from chemistry to clinical implications. , 2003, Biochimica et biophysica acta.

[27]  D. Blake,et al.  Exhaled methyl nitrate as a noninvasive marker of hyperglycemia in type 1 diabetes , 2007, Proceedings of the National Academy of Sciences.

[28]  D. Niederseer,et al.  Gender and age specific differences in exhaled isoprene levels , 2006, Respiratory Physiology & Neurobiology.

[29]  Tianshu Wang,et al.  Selected ion flow tube mass spectrometry of 3-hydroxybutyric acid, acetone and other ketones in the headspace of aqueous solution and urine , 2008 .

[30]  Boyd,et al.  Guidelines and recommendations for laboratory analysis in the diagnosis and management of diabetes mellitus. , 2002, Clinical chemistry.

[31]  Tianshu Wang,et al.  Analysis of breath, exhaled via the mouth and nose, and the air in the oral cavity , 2008, Journal of breath research.

[32]  M. Evans,et al.  An exploratory comparative study of volatile compounds in exhaled breath and emitted by skin using selected ion flow tube mass spectrometry. , 2008, Rapid communications in mass spectrometry : RCM.

[33]  A. Hansel,et al.  On-line monitoring of volatile organic compounds at pptv levels by means of proton-transfer-reaction mass spectrometry (PTR-MS) medical applications, food control and environmental research , 1998 .

[34]  Rossana Salerno-Kennedy,et al.  Potential applications of breath isoprene as a biomarker in modern medicine: a concise overview , 2005, Wiener klinische Wochenschrift.

[35]  M. Hlastala,et al.  Measuring airway exchange of endogenous acetone using a single-exhalation breathing maneuver. , 2006, Journal of applied physiology.

[36]  George Dailey,et al.  Effectiveness of sensor-augmented insulin-pump therapy in type 1 diabetes. , 2010, The New England journal of medicine.

[37]  M. Burge,et al.  Effect of short-term glucose control on glycemic thresholds for epinephrine and hypoglycemic symptoms. , 2001, The Journal of clinical endocrinology and metabolism.

[38]  K. Unterkofler,et al.  Breath isoprene – aspects of normal physiology related to age, gender and cholesterol profile as determined in a proton transfer reaction mass spectrometry study , 2008, Clinical chemistry and laboratory medicine.

[39]  Roger S. Hubbard,et al.  DETERMINATION OF ACETONE IN EXPIRED AIR , 1920 .

[40]  David Zhang,et al.  Diabetes Identification and Classification by Means of a Breath Analysis System , 2010, ICMB.

[41]  D. Blake,et al.  Improved predictive models for plasma glucose estimation from multi-linear regression analysis of exhaled volatile organic compounds. , 2009, Journal of applied physiology.

[42]  P. Španěl,et al.  A longitudinal study of breath isoprene in healthy volunteers using selected ion flow tube mass spectrometry (SIFT-MS) , 2006, Physiological measurement.

[43]  K. Unterkofler,et al.  Breath acetone—aspects of normal physiology related to age and gender as determined in a PTR-MS study , 2009, Journal of breath research.

[44]  R. Fall,et al.  Human breath isoprene and its relation to blood cholesterol levels: new measurements and modeling. , 2001, Journal of applied physiology.

[45]  H. Nagasawa,et al.  Isoprene, an endogenous constituent of human alveolar air with a diurnal pattern of excretion. , 1978, Life sciences.

[46]  David Smith,et al.  Acetone, ammonia and hydrogen cyanide in exhaled breath of several volunteers aged 4–83 years , 2007, Journal of breath research.

[47]  Khosrow Namjou,et al.  Measurement of acetaldehyde in exhaled breath using a laser absorption spectrometer. , 2007, Applied optics.

[48]  David Smith,et al.  Isoprene levels in the exhaled breath of 200 healthy pupils within the age range 7–18 years studied using SIFT-MS , 2010, Journal of breath research.

[49]  T. Jones,et al.  Type 2 diabetes in youth from the Western Pacific region: glycaemic control, diabetes care and complications , 2006, Current medical research and opinion.

[50]  H. Paretzke,et al.  Differences in exhaled gas profiles between patients with type 2 diabetes and healthy controls. , 2010, Diabetes technology & therapeutics.

[51]  L. Laffel Ketone bodies: a review of physiology, pathophysiology and application of monitoring to diabetes , 1999, Diabetes/metabolism research and reviews.

[52]  Malina K. Storer,et al.  Accurate, reproducible measurement of acetone concentration in breath using selected ion flow tube-mass spectrometry , 2010, Journal of breath research.

[53]  B. Zinman,et al.  Modern-day clinical course of type 1 diabetes mellitus after 30 years' duration: the diabetes control and complications trial/epidemiology of diabetes interventions and complications and Pittsburgh epidemiology of diabetes complications experience (1983-2005). , 2009, Archives of internal medicine.

[54]  David Smith,et al.  Selected ion flow tube mass spectrometry (SIFT-MS) for on-line trace gas analysis. , 2005, Mass spectrometry reviews.

[55]  H. Hinterhuber,et al.  Dynamic profiles of volatile organic compounds in exhaled breath as determined by a coupled PTR-MS/GC-MS study , 2010, Physiological measurement.

[56]  Johnny Ludvigsson,et al.  Exhaled Isoprene and Acetone in Newborn Infants and in Children with Diabetes Mellitus , 1998, Pediatric Research.