A. Gómez-Mejia, K. Arnold, J. Bär, K. Dev Singh, T. C. Scheier, S. D. Brugger, A. S. Zinkernagel, P. Sinues

Early detection of pathogenic bacteria is needed for rapid diagnostics allowing adequate and timely treatment of infections.

Lukas Bregy, Constanze Hirsigerb, Stefanie Gartenmann, Tobias Bruderer, Renato Zenobi, Patrick R.Schmidlinb

It has been shown that bacteria in periodontally diseased patients can be recognized by the detection of volatile metabolites in the headspace of saliva by real-time ambient mass spectrometry. The aim of this study was to use this detection method to analyze the oral metabolome in diseased periodontitis patients before and after therapy to monitor disease evolution and healing events.

Haorong Li, Mengyang Xu, and Jiangjiang Zhu

This study aimed to sensitively detect volatile metabolites from the headspace of in vitro gut microbial culture in a human colonic model (HCM). Two SESI-tandem mass spectrometry panels with a comparable number of targeted metabolites/features were established.

Haorong Li and Jiangjiang Zhu

SESIMS/MS was applied to examine the VOC metabolome of a pair of isogenic methicillin-susceptible and resistant Staphylococcus aureus (MSSA and MRSA) strains. Our results indicated that MSSA and MRSA strains can be clearly differentiated Furthermore, we studied the stress response of MSSA and MRSA to antibiotics treatment.

I. A. Ratiu, T. Ligor, Victor B.-Bintintan, B. Buszewski

Bacteria are the main cause of many human diseases. Typical bacterial identification methods, for example culture-based, serological and genetic methods, are time-consuming, delaying the potential for an early and accurate diagnosis and the appropriate subsequent treatment.

L. Bregy, A. R. Müggler, P. M-L Sinues, D. García-Gómez, Y. Suter, G. N. Belibasakis, M. Kohler, P. R. Schmidlin, Renato Zenobi

The detection of bacterial-specific volatile metabolites may be a valuable tool to predict infection. Here we applied a real-time mass spectrometric technique to investigate differences in volatile metabolic profiles of oral bacteria that cause periodontitis. We coupled a secondary electrospray ionization (SESI) source to a commercial high-resolution mass spectrometer …

H. D. Bean, T. R. Mellors, J. Zhu and J. E. Hill

A number of direct injection mass spectrometry methods that can sample foods nondestructively and without sample preparation are being developed with applications ranging from the rapid assessment of food safety to the verification of protected designations of origin. In this pilot study, SESI-MS in positive and negative-ion modes was used to …

C. Ballabio, S. Cristoni, G. Puccio, M. Kohler, M. R. Sala, P. Brambilla, P. M-L Sinues

Blood cultures are routine tests to determine whether micro-organisms have entered the patient’s bloodstream. Automated systems, based on the detection of CO2 increase in the culture media, have considerably improved the screening efficiency for the detection of bacteria. However, further identification of bacteria still requires time consuming culturing procedures.

J. Zhu, J. Jimenez-Díaz, H. D. Bean, N. A. Daphtary, M. I. Aliyeva, L. K. A. Lundblad and J. E. Hill

Before breath-based diagnostics for lung infections can be implemented in the clinic, it is necessary to understand how the breath volatiles change during the course of infection, and ideally, to identify a core set of breath markers that can be used to diagnose the pathogen at any point during the infection …

J. Zhu, H. D. Bean, J. Jiménez-Díaz, and J. E. Hill

Bacterial pneumonia is one of the leading causes of disease-related morbidity and mortality in the world, in part because the diagnostic tools for pneumonia are slow and ineffective. To improve the diagnosis success rates and treatment outcomes for bacterial lung infections, we are exploring the use of SESI-MS breath analysis as a rapid, noninvasive method for determining …

J. Zhu, J. E. Hill

Escherichia coli O157:H7 (EC O157:H7), as well as its recently emerging non-O157 relatives, are a notorious group of pathogenic bacteria associated with foodborne outbreaks. In this study, we demonstrated that secondary electrospray ionization mass spectrometry (SESI-MS) could be a rapid and accurate detection technology for foodborne pathogens …

H. D. Bean, J. Zhu, J. E. Hill

Secondary electrospray ionization mass spectrometry (SESI-MS) is a method developed for the rapid detection of volatile compounds, without the need for sample pretreatment. The method was first described by Fenn and colleagues and has been applied to the detection of illicit drugs and explosives, the characterization of skin volatiles, and the analysis of breath.

J. Zhu, H. D. Bean, Y-M Kuo, and J. E. Hill

We propose a novel application of secondary electrospray ionization-mass spectrometry (SESI-MS) as a real-time clinical diagnostic tool for bacterial infection. It is known that volatile organic compounds (VOCs), produced in different combinations and quantities by bacteria as metabolites, generate characteristic odors for certain bacteria.