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An epifluidic electronic patch with spiking sweat clearance for event-driven perspiration monitoring

Sangha Kim, Seongjin Park, Jina Choi, Wonseop Hwang, Sun-Ho Kim, In‐Suk Choi, Hyunjung Yi, Rhokyun Kwak

2022Nature Communications37 citationsDOIOpen Access PDF

Abstract

Sensory neurons generate spike patterns upon receiving external stimuli and encode key information to the spike patterns, enabling energy-efficient external information processing. Herein, we report an epifluidic electronic patch with spiking sweat clearance using a sensor containing a vertical sweat-collecting channel for event-driven, energy-efficient, long-term wireless monitoring of epidermal perspiration dynamics. Our sweat sensor contains nanomesh electrodes on its inner wall of the channel and unique sweat-clearing structures. During perspiration, repeated filling and abrupt emptying of the vertical sweat-collecting channel generate electrical spike patterns with the sweat rate and ionic conductivity proportional to the spike frequency and amplitude over a wide dynamic range and long time (> 8 h). With such 'spiking' sweat clearance and corresponding electronic spike patterns, the epifluidic wireless patch successfully decodes epidermal perspiration dynamics in an event-driven manner at different skin locations during exercise, consuming less than 0.6% of the energy required for continuous data transmission. Our patch could integrate various on-skin sensors and emerging edge computing technologies for energy-efficient, intelligent digital healthcare.

Topics & Concepts

PerspirationSWEATComputer scienceSpike (software development)Energy (signal processing)Real-time computingMaterials scienceMedicinePhysicsSoftware engineeringQuantum mechanicsInternal medicineComposite materialAdvanced Sensor and Energy Harvesting MaterialsTactile and Sensory InteractionsAdvanced Memory and Neural Computing
An epifluidic electronic patch with spiking sweat clearance for event-driven perspiration monitoring | Litcius