Soft, skin-interfaced microfluidic systems with integrated enzymatic assays for measuring the concentration of ammonia and ethanol in sweat.
Sung Bong KimJahyun KooJangryeol YoonAurélie Hourlier-FargetteBoram LeeShulin ChenSeongbin JoJungil ChoiYong Suk OhGeumbee LeeSang Min WonAlexander J AranyosiStephen P LeeJeffrey B ModelPaul V BraunRoozbeh GhaffariChulwhan ParkJohn A RogersPublished in: Lab on a chip (2019)
Eccrine sweat is a rich and largely unexplored biofluid that contains a range of important biomarkers, from electrolytes, metabolites, micronutrients and hormones to exogenous agents, each of which can change in concentration with diet, stress level, hydration status and physiologic or metabolic state. Traditionally, clinicians and researchers have used absorbent pads and benchtop analyzers to collect and analyze the biochemical constituents of sweat in controlled, laboratory settings. Recently reported wearable microfluidic and electrochemical sensing devices represent significant advances in this context, with capabilities for rapid, in situ evaluations, in many cases with improved repeatability and accuracy. A limitation is that assays performed in these platforms offer limited control of reaction kinetics and mixing of different reagents and samples. Here, we present a multi-layered microfluidic device platform with designs that eliminate these constraints, to enable integrated enzymatic assays with demonstrations of in situ analysis of the concentrations of ammonia and ethanol in microliter volumes of sweat. Careful characterization of the reaction kinetics and their optimization using statistical techniques yield robust analysis protocols. Human subject studies with sweat initiated by warm-water bathing highlight the operational features of these systems.
Keyphrases
- high throughput
- single cell
- circulating tumor cells
- label free
- hydrogen peroxide
- ionic liquid
- physical activity
- gold nanoparticles
- palliative care
- soft tissue
- anaerobic digestion
- ms ms
- weight loss
- wound healing
- nitric oxide
- electron transfer
- induced pluripotent stem cells
- pluripotent stem cells
- heat stress
- highly efficient
- heart rate
- finite element
- solid state