Breath test identifies bacteria's fingerprint
Scientists have identified the chemical 'fingerprints' given off by specific bacteria when present in the lungs, potentially allowing for a quick and simple breath test to diagnose infections such as tuberculosis. Publishing their study January 11, in IOP Publishing's Journal of Breath Research, the researchers have successfully distinguished between different types of bacteria, as well as different strains of the same bacteria, in the lungs of mice by analysing the volatile organic compounds (VOCs) present in exhaled breath.
It is hoped that a simple breath test could reduce the diagnosis time of lung infections from days and weeks to just minutes.
Co-author of the paper, Jane Hill, from the University of Vermont, said: "Traditional methods employed to diagnose bacterial infections of the lung require the collection of a sample that is then used to grow bacteria. The isolated colony of bacteria is then biochemically tested to classify it and to see how resistant it is to antibiotics.
"This whole process can take days for some of the common bacteria and even weeks for the causative agent for tuberculosis. Breath analysis would reduce the time-to-diagnosis to just minutes"
Clinicians see breath-testing as an attractive method for diagnosing disease due to its ease of use and non-invasiveness. Scientists have already investigated breath-based diagnostics for multiple cancers, asthma and diabetes.
In this study, the researchers, from the University of Vermont, analysed the VOCs given off by Pseudomonas aeruginosa and Staphylococcus aureus, both of which are common in acute and chronic lung infections.
They infected mice with the two bacteria and sampled their breath after 24 hours. The VOCs were analysed using a technique called secondary electrospray ionization mass spectrometry (SESI-MS), which is capable of detecting VOCs down to parts per trillion.
They found a statistically significant difference between the breath profiles of the mice infected with the bacteria and the mice that were uninfected. The two different species of bacteria could also be distinguished to a statistically significant level, as could the two different strains of the P. aeruginosa that were used.
They hypothesise that bacteria in the lungs produce unique VOCs that are not found in regular human breath due to their differing metabolism.
"We have strong evidence that we can distinguish between bacterial infections of the lung in mice very effectively using the breathprint SESI-MS approach and I suspect that we will also be able to distinguish between bacterial, viral and fungal infections of the lung.
"To that end, we are now collaborating with colleagues to sample patients in order to demonstrate the strengths, as well as limitations, of breath analysis more comprehensively," continued Hill.
Source: Institute of Physics (IOP)
Latest Science NewsletterGet the latest and most popular science news articles of the week in your Inbox! It's free!
Check out our next project, Biology.Net
From other science news sites
Popular science news articles
- Li-ion batteries contain toxic halogens, but environmentally friendly alternatives exist
- Decrease of genetic diversity in the endangered Saimaa ringed seal continues
- Molecular beacons shine light on how cells 'crawl'
- Liquid helium offers a fascinating new way to make charged molecules
- Cutting the ties that bind
- POLARBEAR seeks cosmic answers in microwave polarization
- Big black holes can block new stars
- Thermal paper cash register receipts account for high bisphenol A (BPA) levels in humans
- UNH scientist: Cosmic rays threaten future deep-space astronaut missions
- Exploring X-Ray phase tomography with synchrotron radiation
- Laser-guided sea monkeys show how zooplankton migrations may affect global ocean currents
- Earth's water is older than the sun
- Preference for built-up habitats could explain rapid spread of the tree bumblebee in UK
- Tooth buried in bone shows prehistoric predators tangled across land, sea
- Simulations reveal an unusual death for ancient stars