Your search keyword '"breathomics"' showing total 3 results

1. Optimized breath analysis: customized analytical methods and enhanced workflow for broader detection of VOCs.

Author

Arulvasan, Wisenave, Greenwood, Julia, Ball, Madeleine L., Chou, Hsuan, Coplowe, Simon, Birch, Owen, Gordon, Patrick, Ratiu, Andreea, Lam, Elizabeth, Tardelli, Matteo, Szkatulska, Monika, Swann, Shane, Levett, Steven, Mead, Ella, van Schooten, Frederik‑Jan, Smolinska, Agnieszka, Boyle, Billy, and Allsworth, Max

Abstract

Introduction: Breath Volatile organic compounds (VOCs) are promising biomarkers for clinical purposes due to their unique properties. Translation of VOC biomarkers into the clinic depends on identification and validation: a challenge requiring collaboration, well-established protocols, and cross-comparison of data. Previously, we developed a breath collection and analysis method, resulting in 148 breath-borne VOCs identified. Objectives: To develop a complementary analytical method for the detection and identification of additional VOCs from breath. To develop and implement upgrades to the methodology for identifying features determined to be “on-breath” by comparing breath samples against paired background samples applying three metrics: standard deviation, paired t-test, and receiver-operating-characteristic (ROC) curve. Methods: A thermal desorption (TD)-gas chromatography (GC)-mass spectrometry (MS)-based analytical method utilizing a PEG phase GC column was developed for the detection of biologically relevant VOCs. The multi-step VOC identification methodology was upgraded through several developments: candidate VOC grouping schema, ion abundance correlation based spectral library creation approach, hybrid alkane-FAMES retention indexing, relative retention time matching, along with additional quality checks. In combination, these updates enable highly accurate identification of breath-borne VOCs, both on spectral and retention axes. Results: A total of 621 features were statistically determined as on-breath by at least one metric (standard deviation, paired t-test, or ROC). A total of 38 on-breath VOCs were able to be confidently identified from comparison to chemical standards. Conclusion: The total confirmed on-breath VOCs is now 186. We present an updated methodology for high-confidence VOC identification, and a new set of VOCs commonly found on-breath. [ABSTRACT FROM AUTHOR]

Published

2025

2. High-quality identification of volatile organic compounds (VOCs) originating from breath.

Author

Arulvasan, Wisenave, Chou, Hsuan, Greenwood, Julia, Ball, Madeleine L., Birch, Owen, Coplowe, Simon, Gordon, Patrick, Ratiu, Andreea, Lam, Elizabeth, Hatch, Ace, Szkatulska, Monika, Levett, Steven, Mead, Ella, Charlton-Peel, Chloe, Nicholson-Scott, Louise, Swann, Shane, van Schooten, Frederik-Jan, Boyle, Billy, and Allsworth, Max

Subjects

*VOLATILE organic compounds, *FEATURE extraction, *POLLUTANTS, *COHORT analysis, *STANDARDIZATION, *BIOMARKERS

Abstract

Introduction: Volatile organic compounds (VOCs) can arise from underlying metabolism and are detectable in exhaled breath, therefore offer a promising route to non-invasive diagnostics. Robust, precise, and repeatable breath measurement platforms able to identify VOCs in breath distinguishable from background contaminants are needed for the confident discovery of breath-based biomarkers. Objectives: To build a reliable breath collection and analysis method that can produce a comprehensive list of known VOCs in the breath of a heterogeneous human population. Methods: The analysis cohort consisted of 90 pairs of breath and background samples collected from a heterogenous population. Owlstone Medical's Breath Biopsy® OMNI® platform, consisting of sample collection, TD-GC-MS analysis and feature extraction was utilized. VOCs were determined to be "on-breath" if they met at least one of three pre-defined metrics compared to paired background samples. On-breath VOCs were identified via comparison against purified chemical standards, using retention indexing and high-resolution accurate mass spectral matching. Results: 1471 VOCs were present in > 80% of samples (breath and background), and 585 were on-breath by at least one metric. Of these, 148 have been identified covering a broad range of chemical classes. Conclusions: A robust breath collection and relative-quantitative analysis method has been developed, producing a list of 148 on-breath VOCs, identified using purified chemical standards in a heterogenous population. Providing confirmed VOC identities that are genuinely breath-borne will facilitate future biomarker discovery and subsequent biomarker validation in clinical studies. Additionally, this list of VOCs can be used to facilitate cross-study data comparisons for improved standardization. [ABSTRACT FROM AUTHOR]

Published

2024

3. Progress and challenges of developing volatile metabolites from exhaled breath as a biomarker platform.

Author

Chou, Hsuan, Godbeer, Lucy, Allsworth, Max, Boyle, Billy, and Ball, Madeleine L.

Subjects

*VOLATILE organic compounds, *BIOMARKERS, *HUMAN body, *DRUG target, *METABOLOMICS

Abstract

Background: The multitude of metabolites generated by physiological processes in the body can serve as valuable biomarkers for many clinical purposes. They can provide a window into relevant metabolic pathways for health and disease, as well as be candidate therapeutic targets. A subset of these metabolites generated in the human body are volatile, known as volatile organic compounds (VOCs), which can be detected in exhaled breath. These can diffuse from their point of origin throughout the body into the bloodstream and exchange into the air in the lungs. For this reason, breath VOC analysis has become a focus of biomedical research hoping to translate new useful biomarkers by taking advantage of the non-invasive nature of breath sampling, as well as the rapid rate of collection over short periods of time that can occur. Despite the promise of breath analysis as an additional platform for metabolomic analysis, no VOC breath biomarkers have successfully been implemented into a clinical setting as of the time of this review. Aim of review: This review aims to summarize the progress made to address the major methodological challenges, including standardization, that have historically limited the translation of breath VOC biomarkers into the clinic. We highlight what steps can be taken to improve these issues within new and ongoing breath research to promote the successful development of the VOCs in breath as a robust source of candidate biomarkers. We also highlight key recent papers across select fields, critically reviewing the progress made in the past few years to advance breath research. Key scientific concepts of review: VOCs are a set of metabolites that can be sampled in exhaled breath to act as advantageous biomarkers in a variety of clinical contexts. [ABSTRACT FROM AUTHOR]

Published

2024