SBIR-STTR Award

Makel Engineering, Inc. and Sandia National Laboratories propose to demonstrate an advanced multi-modal sensor system suitable for in-situ analysis of exhaled VOCs for pilots, divers and field patients. Our proposed system will combine a micro-gas chromatograph (GC) and miniature ion mobility spectrometer (IMS) for detection of trace amounts of exhaled breath VOCs with miniature solid state sensors for inorganic compounds found in breath such as oxygen, carbon dioxide, moisture, nitrogen, argon and helium. High concentrations of supplemental oxygen are used routinely by pilots and divers prior to and during missions to prevent and treat decompression sickness, avoid detection during covert operations, and to support oxygenation following pulmonary injury. However, due to PO2T, exposure limits are imposed to prevent damage to pulmonary tissues. Current policy focuses on preventing PO2T in an operational environment by adhering to exposure limits that were developed based on empirical evidence of PO2T. In reality, individuals will have variable tolerance, and imposed generalized limits often leads to more stringent operational restrictions that required for a given individual, impacting mission readiness. Our system will enable breath analysis on the field in real-time, providing a tool to monitor physiological condition and enable adjusting operational conditions to preventPO2T.

High concentrations of supplemental oxygen are used routinely by pilots and divers prior to and during missions to prevent and treat decompression sickness, avoid detection during covert operations, and to support oxygenation following pulmonary injury. Due to pulmonary oxygen toxicity (PO2T), exposure limits are imposed to prevent damage to pulmonary tissues. Current policy focuses on preventing PO2T in an operational environment by adhering to exposure limits that were developed based on empirical evidence of PO2T. However, individuals have variable tolerance and imposed generalized limits often lead to more stringent operational restrictions than required for a given individual, which in turn significantly impacts mission readiness. Breath analysis of VOCs provides a non-invasive monitoring and diagnose tool that helps identify the onset of diseases and physiological distress [1-4]. Analysis via gas chromatography-mass spectrometry (GC-MS) is the current gold standard. However, since GC-MS is not fieldable in typical operational environments, the current method relies on collecting samples by absorption in a tube with a binding matrix which is then sent to a laboratory for thermal desorption. The product being developed in this STTR program (with Sandia National Laboratories as the research institution partner) is an advanced multi-modal sensor system suitable for in-situ analysis of exhaled volatile organic compounds (VOCs) for pilots, divers, and field patients, along with relevant inorganic compounds. The In-Mask Sensors for Physiological Investigation of Respiratory Exhalation – INSPIRE combines a micro-preconcentrator (PC), a micro-gas chromatograph (GC) and miniature ion mobility spectrometer (IMS) based on low temperature cofired ceramic (LTCC) for detection of trace amounts of exhaled breath VOCs with miniature solid state sensors for inorganic compounds found in breath such as oxygen, carbon dioxide, and moisture. The battery operated, dive mask integrated sensor system will enable to monitor inorganics compounds and volatile organic compounds (VOCs) in divers’ exhaled breath during deep diving.