News from the Breath Analysis Summit 2011.

This special section highlights some of the important work presented at the Breath Analysis Summit 2011, which was held in Parma (Italy) from 11 to 14 September 2011. The meeting, which was jointly organized by the International Association for Breath Research and the University of Parma, was attended by more than 250 delegates from 33 countries, and offered 34 invited lectures and 64 unsolicited scientific contributions. The summit was organized to provide a forum to scientists, engineers and clinicians to present their latest findings and to meet industry executives and entrepreneurs to discuss key trends, future directions and technologies available for breath analysis. A major focus was on nitric oxide, exhaled breath condensate, electronic nose, mass spectrometry and newer sensor technologies. Medical applications ranged from asthma and other respiratory diseases to gastrointestinal disease, occupational diseases, critical care and cancer. Most people identify breath tests with breathalysers used by police to estimate ethanol concentration in blood. However, breath testing has far more sophisticated applications. Breath analysis is rapidly evolving as a new frontier in medical testing for disease states in the lung and beyond. Every individual has a breath fingerprint-or 'breathprint'-that can provide useful information about his or her state of health. This breathprint comprises the many thousands of molecules that are expelled with each breath we exhale. Breath research in the past few years has uncovered the scientific and molecular basis for such clinical observations. Relying on mass spectrometry, we have been able to identify many such unique substances in exhaled breath, including gases, such as nitric oxide (NO) and carbon monoxide (CO), and a wide array of volatile organic compounds. Exhaled breath also carries aerosolized droplets that can be collected as an exhaled breath condensate that contains endogenously produced non-volatile compounds. Breath analysis is now used to diagnose and monitor asthma, check for transplant organ rejection, detect lung cancer and test for Helicobacter pyloriinfection-and the list is growing. A major milestone in the scientific study of breath was marked in the 1970s when Linus Pauling demonstrated that there is more to exhaled breath than the classic gases of nitrogen, oxygen, carbon dioxide and water vapour-a lot more. Based on the gas-liquid partition chromatography analysis, Pauling reported the presence of 250 substances in exhaled breath. We now have the technology to test for any and all of these components. The field of breath analysis has made considerable advances in the 21st century and the utility of breath analysis in health care is advancing quickly. The science is rapidly expanding, the technology is improving and several new applications have been developed or are under commercial development. Breath analysis may rely on both direct (on line) and indirect (off line) reading methods: in the on-line method, breath analysis is immediately available, whereas the use of indirect methods generally involves collecting and trapping the breath sample and subsequently transferring it to an analytical instrument for analysis. Various kinds of breath samples have been used in biological monitoring, including mixed expired air and end expired air: end exhaled air represents the alveolar air concentration and mixed exhaled air represents the gas mixture coming from the dead space of the bronchial tree and the alveolar gas-exchange space. Exhaled breath analysis is an area where the modern day advances in technology and engineering meet the ever expanding need in medicine for more sensitive, specific and non-invasive tests which makes this area a major front in the interface between medicine and engineering. A major breakthrough over the past decade has been the increase in breath-based tests approved by the US Food and Drug Administration (FDA). Devices measuring common breath gases (oxygen, nitrogen, water vapour and CO(2)) in patient respiratory monitoring have served as a platform for technological growth in clinical breath-testing applications. A few exhaled breath tests have demonstrated clinical utility and are in widespread use, and several FDA-approved devices are available. These widely used exhaled breath tests include detection of blood alcohol concentration and exhaled CO(2). Other clinical applications of exhaled breath analysis include testing for H. pylori infection, lactose intolerance, heart transplant rejection and, more recently, monitoring of airway inflammation by means of exhaled NO. Examination of exhaled breath has the potential to change the existing routine approaches in human medicine. The rapidly developing new analytical and computer technologies along with novel, unorthodox ideas are prerequisites for future advances in this field. Scientists who participated in the Breath Analysis Summit 2011 were invited to submit a full length paper to the Journal of Breath Research and this issue includes eight articles which describe the different applications of breath analysis. We thank all the authors for their valuable contribution and we trust that this collection will provide useful information and an update to this rapidly evolving field, giving an example of integration among scientists who address the same topic-breath analysis-from different and complementary perspectives, from basic to clinical research.