A protocol for characterizing chemical composition of exhaled breath in real time by using secondary nanoelectrospray ionization coupled to high resolution mass spectrometry is demonstrated.
Exhaled volatile organic compounds (VOCs) have aroused considerable interest, since they can serve as biomarkers for disease diagnosis and environmental exposure in a non-invasive manner. In this work, we present a protocol to characterize the exhaled VOCs in real time by using secondary nanoelectrospray ionization coupled to high resolution mass spectrometry (Sec-nanoESI-HRMS). The homemade Sec-nanoESI source was readily set up based on a commercial nanoESI source. Hundreds of peaks were observed in the background-subtracted mass spectra of exhaled breath, and the mass accuracy values are -4.0-13.5 ppm and -20.3-1.3 ppm in the positive and negative ion detection modes, respectively. The peaks were assigned with accurate elemental composition according to the accurate mass and isotopic pattern. Less than 30 s is used for one exhalation measurement, and it takes approximately 7 min for six replicated measurements.
With fast development of modern analytical techniques, hundreds of volatile organic compounds (VOCs) have been identified in human exhaled breath1. These VOCs mostly result from alveolar air (~350 mL for a healthy adult) and anatomical dead space air (~150 mL)2, which are affected by body metabolism3,4,5,6,7,8 and environmental pollution9, respectively. As a result, if identified, these VOCs are promising to be used as biomarkers for disease diagnosis and environmental exposure in a non-invasive manner.
Though gas chromatography mass spectrometry (GC-MS) is the most widely used technique for qualitative and quantitative analysis of exhaled VOCs2, direct MS techniques, which have been developed for real-time breath analysis, have the advantages of high time resolution and simple sample pre-preparation. Direct MS techniques, such as proton transfer reaction MS (PTR-MS)10, selected ion flow tube MS (SIFT-MS)11, secondary electrospray ionization MS (SESI-MS)12,13 (also named as extractive electrospray ionization MS, EESI-MS14,15), trace atmospheric gas analyzer (TAGA)16 and plasma ionization MS (PI-MS)17 have been investigated in recent years.
Among all the direct MS techniques, SESI is well-known as a universal soft ionization technique19,20,21; and the source is easy to be customized and coupled to different types of mass spectrometers, e.g., time of flight mass spectrometer8,15, ion trap mass spectrometer14 and orbitrap mass spectrometer12,18. Up to now, SESI-MS has been successfully used in diagnosing respiratory diseases22, gauging circadian rhythm3,6,23, pharmacokinetics7,8, and revealing metabolic pathways4, etc. Most recently, a commercial SESI source has become available.
In this study, a facile and compact secondary nanoelectrospray ionization source (Sec-nanoESI) was set up and coupled to a high-resolution mass spectrometer. Real-time measurements of exhaled VOCs in breath were presented.
Caution: Please consult all relevant material safety data sheets (MSDS) before use. Please use appropriate personal protective equipment, e.g., lab coat, gloves, goggles, full length pants and closed-toe shoes).
1. Set up the Sec-nanoESI source
2. Instrument optimization
3. Measurement of exhaled breath
4. Obtain a breath fingerprint and a time trace of a compound
Figure 3 shows the breath fingerprints in the mass range of m/z 50-750 recorded under both positive and negative ion detection modes. 291 peaks (peak intensity > 5.0×104) and 173 peaks (peak intensity > 3.0×104) have been observed in background-subtracted breath fingerprints in the positive and negative ion detection modes, respectively. To identify peaks in the mass spectra, please refer to prior publications for details12,18,24,29. In brief, both volatile metabolites and VOCs from indoor air have been detected. For example, the peak at m/z 74.0606 (Figure 3a) results from exhaled N,N-dimethylformamide or aminoactone according to the Human Metabolome Database (HMDB); peaks at m/z 462.1447 and m/z 536.1638 (Figure 3a) are from the adducts of exhaled ammonia and polysiloxanes (laboratory contaminants)12. The typical mass accuracy values in positive and negative ion detection modes are -4.0-13.5 ppm and -20.3-1.3 ppm, respectively. Figure 4 presents the time trace of indole, a typical endogenous compound, which is detected by six replicated measurements of exhaled breath from one subject. It takes less than 7 min for all six measurements.
Figure 1. Schematic for SESI-MS analysis of VOCs in exhaled breath. Please click here to view a larger version of this figure.
Figure 2. (a) A schematic diagram and (b) a photo of the Sec-nanoESI source used in this experiment. Please click here to view a larger version of this figure.
Figure 3. Background-subtracted breath fingerprints obtained in (a) positive and (b) negative ion detection modes in the mass range of m/z 50-750. Please click here to view a larger version of this figure.
Figure 4. Time trace of indole detected by six replicated measurements of exhaled breath from one subject. Please click here to view a larger version of this figure.
Constructing the Sec-nanoESI source based on a commercial nanoESI source, the ionization efficiency is higher than that of using an ESI source30. In addition, the ionization efficiency is further improved in a closed chamber, as it isolates the process from the ambient background air, and at the same time facilitates the mixing between the gas sample and the spray plume. By using a Sec-nanoESI, less parameters need to be optimized compared to an ESI source, making it easier for installation, application and maintenance.
If no signal is observed or sensitivity decreases significantly when performing breath analysis by Sec-nanoESI-MS, one should check the position of the spray capillary tip and also the formation of droplets at the tip of the capillary. Align the tip with the orifice of the mass spectrometer. Change the spray capillary to a new one if the spray capillary is blocked or the tip is contaminated. Otherwise, check whether the ITT of the instrument is blocked or contaminated. Replace or clean the ITT if necessary. Turn off ESI voltage before checking the spray capillary. Set the temperature of ITT at room temperature and wait until the temperature drops down.
SESI-HRMS has been demonstrated to be a sensitive and selective technique for real-time breath analysis4,6,12. In the past few years, this technique has been successfully applied to gauging circadian variation3,6, monitoring pharmacokinetics7,8, identifying metabolic pathways5, etc. Lately, amino acids in human breath have been successfully quantified by SESI-MS for the first time, which is remarkable progress in quantitative analysis5. With further investigations, SESI-HRMS could establish itself as a useful and efficient noninvasive clinical method.
The authors have nothing to disclose.
This work has been financially supported by National Natural Science Foundation of China (No. 91543117).
Ultrapure water | Merck Millipore, USA | MPGP04001 | Resistance >18.2 MΩ·cm |
Formic acid | Sigma-Aldrich, USA | F0507 | Corrosive to the respiratory tract. |
Nitrogen gas | Guangzhou Shiyuan Gas Co. Ltd., China | N.A.a | Purity >99.99% |
Q Exactive hybrid quadrupole-orbitrap mass spectrometer | Thermo Scientific, USA | 02634L(S/N) | Beware of high voltage and high temperature |
NanoESI source | Thermo Scientific, USA | ES002373(S/N); ES071(P/N) | Beware of high voltage and high temperature |
Nano LC pump | Thermo Scientific, USA | 5041.0010A(P/N) | / |
Xcalibur software (Version 3.0) | Thermo Scientific, USA | BRE0008596 | / |
Dino-Lite Digital Microscope | Tech Video System (SuZhou) Co.Ltd., China | CQ401833R(S/N) | / |
Nafion tubing | Perma Pure LLC, USA | ME60 | / |
PTFE tubing (I.D. 4 mm) | Dongguan Hongfu Insulating Material Co. Ltd., China | N.A. | Beware of the possible loss of polar compounds |
Mass flow controller | Line-Tech, Korea | M15122007 (S/N) | / |
Flow meter | Yuyao Industrial Automation Meter Factory, China | 40784 | / |
aN.A.: not available. |