Trajectory-Informed Breathomics for Dynamic Mapping of Health and Disease: Toward a Health Navigation Framework

Most diagnostic frameworks treat disease as static, overlooking its inherently dynamic and continuous progression. Noninvasive biomarkers capable of capturing physiological trajectories are critically needed for proactive health management. We developed a breath-based health navigation framework using exhaled volatile organic compounds (VOCs) as integrative, real-time indicators of systemic metabolism and immunity. Breath profiles were collected from healthy individuals and patients with nonalcoholic steatohepatitis (NASH, recently redefined as metabolic dysfunction–associated steatohepatitis, MASH), hepatocellular carcinoma (HCC), and periodontitis (PD). Multidimensional analysis and trajectory-informed mapping were applied to project individual health states into a low-dimensional physiological space. Ratio-normalized VOC profiles revealed disease-specific metabolic signatures across P450-derived and microbiota-derived compounds. Machine learning achieved high diagnostic accuracy for distinguishing health, NASH, HCC, and PD, while dimensionality reduction and topological analysis visualized a continuous progression from health to advanced liver disease. This approach captured preclinical shifts and transitional states often missed by static diagnostics. Exhaled VOCs can serve as dynamic biomarkers for mapping health–disease transitions. By offering clinicians an intuitive map to locate patients within the health–disease continuum and anticipate their trajectories, this framework enables proactive decision-making and personalized intervention strategies. Collectively, our work points toward a paradigm shift in disease monitoring, with future integration into portable sensing technologies for noninvasive, continuous health-state assessment.