Fig. 2 Optimization of the sweat control and characterization of individual sensors. Optimization of the sweat control and characterization of individual.

Slides:

Advertisements

Similar presentations

Fig. 4 Pupil shape and image quality in the model sheep eye.

Advertisements

Fig. 5 In vivo MIP imaging of lipid and protein in C. elegans.

Fig. 1 Upward emission functions used to compute the maps.

Fig. 4 3D reconfiguration of liquid metals for electronics.

Fig. 2 Electronically conducting xylem wires.

Fig. 2 The arrangements of metal core and ligands.

Fig. 5 Time evolution results of the MIROC climate model simulation with freshwater hosing. Time evolution results of the MIROC climate model simulation.

Fig. 4 Electrical properties and patterning of the stretchable PEDOT/STEC (STEC content is 45.5 wt % for all). Electrical properties and patterning of.

Fig. 3 Faculty placement distributions.

Fig. 5 Analytical performance of the wearable cortisol sensor.

Fig. 3 Piezoresistive e-skin with interlocked microdome arrays for simultaneous detection of static pressure and temperature. Piezoresistive e-skin with.

Fig. 2 Materials and designs for bioresorbable PC microcavity-based pressure and temperature sensors. Materials and designs for bioresorbable PC microcavity-based.

Fig. 4 Transfer characteristics of the carristor.

Fig. 2 Mechanical and antibacterial properties of AAD.

Fig. 4 Skin test response to peptide cocktails in field reactors.

Fig. 1 Bioinspired design of AAD for promoting wound contraction.

Fig. 6 External drivers and model response.

Fig. 5 Wearable closed-loop HMI.

Fig. 3 Characteristics of UV and temperature sensors.

Battery-free, skin-interfaced microfluidic/electronic systems for simultaneous electrochemical, colorimetric, and volumetric analysis of sweat by Amay.

Fig. 2 Images of complex structures formed via sequential folding.

Wearable/disposable sweat-based glucose monitoring device with multistage transdermal drug delivery module by Hyunjae Lee, Changyeong Song, Yong Seok Hong,

Fig. 5 Recruitment of a downstream polarity complex triggered by the MT arrival. Recruitment of a downstream polarity complex triggered by the MT arrival.

Ultraflexible organic photonic skin

Fig. 4 Real-time optical and thermal response during the reversible phase transition. Real-time optical and thermal response during the reversible phase.

The prototype and working mechanism.

Dynamically self-assembled patterns formed by up to 40 micro-rafts

Fig. 3 Transport characterization of dry-assembled devices.

Fig. 3 Evolutions of freshwater transport and salinity.

Fig. 1 Crystal structure and superconductivity in fcc fullerides.

Fig. 4 Evolution of fraction of sickled RBCs under hypoxia.

Fig. 3 In vivo monitoring of vitamin E distribution on mouse skin.

Illustration of MIS-C and the characterization of the device structure

Fig. 2 Large-area and high-density assembly of AuNPs.

Fig. 1 In vitro calibration plots and pH maps using iopamidol in human blood serum. In vitro calibration plots and pH maps using iopamidol in human blood.

Fig. 4 Piezoresistive e-skin with interlocked microdome array for simultaneous monitoring of artery pulse pressure and temperature. Piezoresistive e-skin.

Fig. 1 Optical and STEM characterization of vdW heterostructures.

Fig. 1 Deficient CD73 and CD39 expressions and extracellular adenosine concentration in BM of OVX animals. Deficient CD73 and CD39 expressions and extracellular.

Fig. 1 Schematics of R2R fabricated sweat sensing patches for regional and correlative sweat analysis. Schematics of R2R fabricated sweat sensing patches.

Fig. 1 Schematic view and characterizations of FGT/Pt bilayer.

Fig. 3 The bacteria loading capacity and biocompatibility of GA/Pt.

Fig. 3 Characterization of PCNs and PCN-loaded microneedles.

Fig. 2 Characterizing the performance of msTENG.

Fig. 1 Photoluminescence characteristics of the exciplex system.

Fig. 1 Synthesis and characterization of PE-E/Pt.

Fig. 5 Piezoelectric e-skin with interlocked microdome array for dynamic touch and acoustic sound detection. Piezoelectric e-skin with interlocked microdome.

Fig. 4 Sweat-based glucose monitoring and feedback therapy in vivo.

Fig. 1 Topology of places and city block complexity.

Fig. 1 Fractional coverage of the mapping method used in this study.

Fig. 2 XRD spectra and molecular structures of tetragonal and monoclinic crystal phase KDP samples. XRD spectra and molecular structures of tetragonal.

Fig. 2 Number of years that would have been required for the observed vertebrate species extinctions in the last 114 years to occur under a background.

Fig. 5 Simulation of the mechanical properties of the 3DGraphene foam in a wide temperature range down to the cryogenic region. Simulation of the mechanical.

Fig. 2 Temperature-sensing properties of the flexible rGO/PVDF nanocomposite film. Temperature-sensing properties of the flexible rGO/PVDF nanocomposite.

Fig. 2 XRD, SEM-EDX, and three-dimensional optical characterization.

Interpreted seismic reflection image across reactivated fracture zones

Fig. 3 Device architecture, photovoltaic performance, and operational stability of 3D/2D bilayer PSCs. Device architecture, photovoltaic performance, and.

Fig. 1 Ultrathin, stretchable, mechanically imperceptible, multifunctional HMI device for human and robotics. Ultrathin, stretchable, mechanically imperceptible,

Fig. 2 Uniaxial in situ microcompression tests on the conventional and flash-sintered TiO2 at different temperatures, RT versus 400°C, at a constant strain.

Fig. 2 Supraballs and films from binary SPs.

Fig. 1 Structure and basic properties of EuTiO3 (ETO) films.

SEM and TEM images and photoluminescence properties of composites

Fig. 1 Simplified sketch of the experimental design.

Fig. 3 Voltage-driven phase switching in a 1T-TaS2 nano-thick crystal.

Fig. 2 The working principle and electrical output modulating of BD-TENG by changing the materials of friction layers. The working principle and electrical.

Fig. 3 Rubbery strain, pressure, and temperature sensors.

Fig. 4 In situ mapping of human patient breast cancer and stroma.

Fig. 2 Wavelength tuning with temperature.

Fig. 5 Spatial resolution of the optogenetic activation achieved with OLED microarrays. Spatial resolution of the optogenetic activation achieved with.

Imχ(3)(−ω; 0, 0, ω) spectra and their analyses in undoped cuprates

Fig. 2 Printed three-axis acceleration sensor.

Presentation transcript:

Fig. 2 Optimization of the sweat control and characterization of individual sensors. Optimization of the sweat control and characterization of individual sensors. (A) Optical image of the wearable sweat analysis patch with a sweat-uptake layer and a waterproof band. The inset shows the magnified view of the porous sweat-uptake layer. (B) Optical image of the sweat analysis patch under deformation. (C) Optical image of the disposable sweat analysis strip on human skin with perspiration. (D) Glucose (glu.) concentration measurement at different sweat volumes (0.3 mM glucose in artificial sweat). (E) Optical image (top) and calibration curve (bottom) of the humidity sensor. Inset shows the image before and after wetting of the sensor. (F) Optical image (top) and calibration curve (bottom) of the glucose sensor. (G) Optical image (top) and calibration curve (bottom) of the pH sensor. (H) Optical image (top) and calibration curve (bottom) of the temperature sensor. (I) Changes of the relative sensitivity of the uncorrected glucose sensor at different pH levels. The relative sensitivity (S/So) is defined as measured sensitivity divided by sensitivity at pH 5. (J) In vitro monitoring of glucose changes with (green) and without (red) correction using simultaneous pH measurements (blue). (K) Calibration curves of the glucose sensor at different temperatures. Hyunjae Lee et al. Sci Adv 2017;3:e1601314 Copyright © 2017, The Authors