conductive adhesive tape Search Results


adhesive carbon disks leit-tab  (Plano gmbh)
90
Plano gmbh adhesive carbon disks leit-tab
Adhesive Carbon Disks Leit Tab, supplied by Plano gmbh, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/adhesive carbon disks leit-tab/product/Plano gmbh
Average 90 stars, based on 1 article reviews
adhesive carbon disks leit-tab - by Bioz Stars, 2026-05
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electrically conductive woven silver tape  (Adhesives Research)
90
Adhesives Research electrically conductive woven silver tape
Electrically Conductive Woven Silver Tape, supplied by Adhesives Research, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/electrically conductive woven silver tape/product/Adhesives Research
Average 90 stars, based on 1 article reviews
electrically conductive woven silver tape - by Bioz Stars, 2026-05
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conductive, vacuum-compatible carbon tape  (Plano gmbh)
90
Plano gmbh conductive, vacuum-compatible carbon tape
Conductive, Vacuum Compatible Carbon Tape, supplied by Plano gmbh, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/conductive, vacuum-compatible carbon tape/product/Plano gmbh
Average 90 stars, based on 1 article reviews
conductive, vacuum-compatible carbon tape - by Bioz Stars, 2026-05
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anisotropic conductive film fp2322d  (Sony)
90
Sony anisotropic conductive film fp2322d
Anisotropic Conductive Film Fp2322d, supplied by Sony, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/anisotropic conductive film fp2322d/product/Sony
Average 90 stars, based on 1 article reviews
anisotropic conductive film fp2322d - by Bioz Stars, 2026-05
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compact, conductive graphite tape (thermal interface sheet, graphite, 1600 w m−1·k, 180 × self-adhesive)  (Panasonic Healthcare)
90
Panasonic Healthcare compact, conductive graphite tape (thermal interface sheet, graphite, 1600 w m−1·k, 180 × self-adhesive)
Compact, Conductive Graphite Tape (Thermal Interface Sheet, Graphite, 1600 W M−1·K, 180 × Self Adhesive), supplied by Panasonic Healthcare, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/compact, conductive graphite tape (thermal interface sheet, graphite, 1600 w m−1·k, 180 × self-adhesive)/product/Panasonic Healthcare
Average 90 stars, based on 1 article reviews
compact, conductive graphite tape (thermal interface sheet, graphite, 1600 w m−1·k, 180 × self-adhesive) - by Bioz Stars, 2026-05
90/100 stars
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double-sided conductive adhesive tape  (Plano gmbh)
90
Plano gmbh double-sided conductive adhesive tape
Double Sided Conductive Adhesive Tape, supplied by Plano gmbh, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/double-sided conductive adhesive tape/product/Plano gmbh
Average 90 stars, based on 1 article reviews
double-sided conductive adhesive tape - by Bioz Stars, 2026-05
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double-sided conductive acrylic tape arclad® 8001–77  (Adhesives Research)
90
Adhesives Research double-sided conductive acrylic tape arclad® 8001–77
a DoS electronics drawing process beginning with (i) a tape-based stencil attachment to the skin (scale bar 1 cm), (ii) drawing the device with the stencil, modified ballpoint pen, and inks (scale bar 5 mm), inset is a closeup of the tip (scale bar 1 mm), (iii) removal of the stencil (scale bar 2 cm), and (iv) the completed device after drying (scale bar 1 cm). b An example DoS integrated system including a resistor, transistors, heater, EP (electrophysiological) sensors, temperature sensor, strain sensor, and skin hydration sensor drawn on human skin (scale bar 5 mm). The corresponding stencil for the conductor is shown in the inset (scale bar 1 cm). c Achievable line spacing using stencils and the <t>conductive</t> Ag-PEDOT:PSS ink (scale bar 1 mm). d Non-stretched (left, scale bar 1 mm) and biaxially stretched (right, scale bar 1 cm) states of the drawn structure consisting of Ag-PEDOT:PSS conductive (left square) and P3HT-NF semiconducting (right square) inks on PDMS. e Twisting (left) and poking (right, scale bars 1 cm) deformations of the drawn structure with conductive and semiconducting inks. f SEM images of the Ag-PEDOT:PSS ink showing ultraconformal contact with the grooves and bumps (left, scale bar 250 µm) on top of skin replica and cross-section showing Ag-PEDOT:PSS microstructure (right, scale bar 20 µm). The purple color indicates the skin replica. g Histology image of the Ag-PEDOT:PSS ink on skin of mice after 48 h (scale bar 100 µm). h Histology image of the P3HT-NF ink on skin of mice after 48 h (scale bar 100 µm). i Sheet resistance vs. strain while stretching the Ag-PEDOT:PSS ink up to 30% and releasing. The error bars represent the s.d. j Optical microscope images of the Ag-PEDOT:PSS ink on skin replica stretched up to 30% (scale bars 100 µm). k DoS EP sensor on the wrist of subject in stretched (top) and non-stretched (bottom) states (scale bars 5 mm).
Double Sided Conductive Acrylic Tape Arclad® 8001–77, supplied by Adhesives Research, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/double-sided conductive acrylic tape arclad® 8001–77/product/Adhesives Research
Average 90 stars, based on 1 article reviews
double-sided conductive acrylic tape arclad® 8001–77 - by Bioz Stars, 2026-05
90/100 stars
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thermally conductive adhesive tape  (McMaster-Carr)
90
McMaster-Carr thermally conductive adhesive tape
a DoS electronics drawing process beginning with (i) a tape-based stencil attachment to the skin (scale bar 1 cm), (ii) drawing the device with the stencil, modified ballpoint pen, and inks (scale bar 5 mm), inset is a closeup of the tip (scale bar 1 mm), (iii) removal of the stencil (scale bar 2 cm), and (iv) the completed device after drying (scale bar 1 cm). b An example DoS integrated system including a resistor, transistors, heater, EP (electrophysiological) sensors, temperature sensor, strain sensor, and skin hydration sensor drawn on human skin (scale bar 5 mm). The corresponding stencil for the conductor is shown in the inset (scale bar 1 cm). c Achievable line spacing using stencils and the <t>conductive</t> Ag-PEDOT:PSS ink (scale bar 1 mm). d Non-stretched (left, scale bar 1 mm) and biaxially stretched (right, scale bar 1 cm) states of the drawn structure consisting of Ag-PEDOT:PSS conductive (left square) and P3HT-NF semiconducting (right square) inks on PDMS. e Twisting (left) and poking (right, scale bars 1 cm) deformations of the drawn structure with conductive and semiconducting inks. f SEM images of the Ag-PEDOT:PSS ink showing ultraconformal contact with the grooves and bumps (left, scale bar 250 µm) on top of skin replica and cross-section showing Ag-PEDOT:PSS microstructure (right, scale bar 20 µm). The purple color indicates the skin replica. g Histology image of the Ag-PEDOT:PSS ink on skin of mice after 48 h (scale bar 100 µm). h Histology image of the P3HT-NF ink on skin of mice after 48 h (scale bar 100 µm). i Sheet resistance vs. strain while stretching the Ag-PEDOT:PSS ink up to 30% and releasing. The error bars represent the s.d. j Optical microscope images of the Ag-PEDOT:PSS ink on skin replica stretched up to 30% (scale bars 100 µm). k DoS EP sensor on the wrist of subject in stretched (top) and non-stretched (bottom) states (scale bars 5 mm).
Thermally Conductive Adhesive Tape, supplied by McMaster-Carr, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/thermally conductive adhesive tape/product/McMaster-Carr
Average 90 stars, based on 1 article reviews
thermally conductive adhesive tape - by Bioz Stars, 2026-05
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adhesive tape 2 mm-wide containing dispersed conductive particles  (Sekisui Diagnostics)
90
Sekisui Diagnostics adhesive tape 2 mm-wide containing dispersed conductive particles
a DoS electronics drawing process beginning with (i) a tape-based stencil attachment to the skin (scale bar 1 cm), (ii) drawing the device with the stencil, modified ballpoint pen, and inks (scale bar 5 mm), inset is a closeup of the tip (scale bar 1 mm), (iii) removal of the stencil (scale bar 2 cm), and (iv) the completed device after drying (scale bar 1 cm). b An example DoS integrated system including a resistor, transistors, heater, EP (electrophysiological) sensors, temperature sensor, strain sensor, and skin hydration sensor drawn on human skin (scale bar 5 mm). The corresponding stencil for the conductor is shown in the inset (scale bar 1 cm). c Achievable line spacing using stencils and the <t>conductive</t> Ag-PEDOT:PSS ink (scale bar 1 mm). d Non-stretched (left, scale bar 1 mm) and biaxially stretched (right, scale bar 1 cm) states of the drawn structure consisting of Ag-PEDOT:PSS conductive (left square) and P3HT-NF semiconducting (right square) inks on PDMS. e Twisting (left) and poking (right, scale bars 1 cm) deformations of the drawn structure with conductive and semiconducting inks. f SEM images of the Ag-PEDOT:PSS ink showing ultraconformal contact with the grooves and bumps (left, scale bar 250 µm) on top of skin replica and cross-section showing Ag-PEDOT:PSS microstructure (right, scale bar 20 µm). The purple color indicates the skin replica. g Histology image of the Ag-PEDOT:PSS ink on skin of mice after 48 h (scale bar 100 µm). h Histology image of the P3HT-NF ink on skin of mice after 48 h (scale bar 100 µm). i Sheet resistance vs. strain while stretching the Ag-PEDOT:PSS ink up to 30% and releasing. The error bars represent the s.d. j Optical microscope images of the Ag-PEDOT:PSS ink on skin replica stretched up to 30% (scale bars 100 µm). k DoS EP sensor on the wrist of subject in stretched (top) and non-stretched (bottom) states (scale bars 5 mm).
Adhesive Tape 2 Mm Wide Containing Dispersed Conductive Particles, supplied by Sekisui Diagnostics, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/adhesive tape 2 mm-wide containing dispersed conductive particles/product/Sekisui Diagnostics
Average 90 stars, based on 1 article reviews
adhesive tape 2 mm-wide containing dispersed conductive particles - by Bioz Stars, 2026-05
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conductive double-faced pressure sensitive tape with a conductive carrier which can be used for the mat is a thin pressure sensitive bonding tape  (Adhesives Research)
90
Adhesives Research conductive double-faced pressure sensitive tape with a conductive carrier which can be used for the mat is a thin pressure sensitive bonding tape
a DoS electronics drawing process beginning with (i) a tape-based stencil attachment to the skin (scale bar 1 cm), (ii) drawing the device with the stencil, modified ballpoint pen, and inks (scale bar 5 mm), inset is a closeup of the tip (scale bar 1 mm), (iii) removal of the stencil (scale bar 2 cm), and (iv) the completed device after drying (scale bar 1 cm). b An example DoS integrated system including a resistor, transistors, heater, EP (electrophysiological) sensors, temperature sensor, strain sensor, and skin hydration sensor drawn on human skin (scale bar 5 mm). The corresponding stencil for the conductor is shown in the inset (scale bar 1 cm). c Achievable line spacing using stencils and the <t>conductive</t> Ag-PEDOT:PSS ink (scale bar 1 mm). d Non-stretched (left, scale bar 1 mm) and biaxially stretched (right, scale bar 1 cm) states of the drawn structure consisting of Ag-PEDOT:PSS conductive (left square) and P3HT-NF semiconducting (right square) inks on PDMS. e Twisting (left) and poking (right, scale bars 1 cm) deformations of the drawn structure with conductive and semiconducting inks. f SEM images of the Ag-PEDOT:PSS ink showing ultraconformal contact with the grooves and bumps (left, scale bar 250 µm) on top of skin replica and cross-section showing Ag-PEDOT:PSS microstructure (right, scale bar 20 µm). The purple color indicates the skin replica. g Histology image of the Ag-PEDOT:PSS ink on skin of mice after 48 h (scale bar 100 µm). h Histology image of the P3HT-NF ink on skin of mice after 48 h (scale bar 100 µm). i Sheet resistance vs. strain while stretching the Ag-PEDOT:PSS ink up to 30% and releasing. The error bars represent the s.d. j Optical microscope images of the Ag-PEDOT:PSS ink on skin replica stretched up to 30% (scale bars 100 µm). k DoS EP sensor on the wrist of subject in stretched (top) and non-stretched (bottom) states (scale bars 5 mm).
Conductive Double Faced Pressure Sensitive Tape With A Conductive Carrier Which Can Be Used For The Mat Is A Thin Pressure Sensitive Bonding Tape, supplied by Adhesives Research, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/conductive double-faced pressure sensitive tape with a conductive carrier which can be used for the mat is a thin pressure sensitive bonding tape/product/Adhesives Research
Average 90 stars, based on 1 article reviews
conductive double-faced pressure sensitive tape with a conductive carrier which can be used for the mat is a thin pressure sensitive bonding tape - by Bioz Stars, 2026-05
90/100 stars
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conductive double-faced pressure sensitive tape  (Adhesives Research)
90
Adhesives Research conductive double-faced pressure sensitive tape
a DoS electronics drawing process beginning with (i) a tape-based stencil attachment to the skin (scale bar 1 cm), (ii) drawing the device with the stencil, modified ballpoint pen, and inks (scale bar 5 mm), inset is a closeup of the tip (scale bar 1 mm), (iii) removal of the stencil (scale bar 2 cm), and (iv) the completed device after drying (scale bar 1 cm). b An example DoS integrated system including a resistor, transistors, heater, EP (electrophysiological) sensors, temperature sensor, strain sensor, and skin hydration sensor drawn on human skin (scale bar 5 mm). The corresponding stencil for the conductor is shown in the inset (scale bar 1 cm). c Achievable line spacing using stencils and the <t>conductive</t> Ag-PEDOT:PSS ink (scale bar 1 mm). d Non-stretched (left, scale bar 1 mm) and biaxially stretched (right, scale bar 1 cm) states of the drawn structure consisting of Ag-PEDOT:PSS conductive (left square) and P3HT-NF semiconducting (right square) inks on PDMS. e Twisting (left) and poking (right, scale bars 1 cm) deformations of the drawn structure with conductive and semiconducting inks. f SEM images of the Ag-PEDOT:PSS ink showing ultraconformal contact with the grooves and bumps (left, scale bar 250 µm) on top of skin replica and cross-section showing Ag-PEDOT:PSS microstructure (right, scale bar 20 µm). The purple color indicates the skin replica. g Histology image of the Ag-PEDOT:PSS ink on skin of mice after 48 h (scale bar 100 µm). h Histology image of the P3HT-NF ink on skin of mice after 48 h (scale bar 100 µm). i Sheet resistance vs. strain while stretching the Ag-PEDOT:PSS ink up to 30% and releasing. The error bars represent the s.d. j Optical microscope images of the Ag-PEDOT:PSS ink on skin replica stretched up to 30% (scale bars 100 µm). k DoS EP sensor on the wrist of subject in stretched (top) and non-stretched (bottom) states (scale bars 5 mm).
Conductive Double Faced Pressure Sensitive Tape, supplied by Adhesives Research, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/conductive double-faced pressure sensitive tape/product/Adhesives Research
Average 90 stars, based on 1 article reviews
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electrically conductive double-sided adhesive tape  (Tousimis Research Corporation)
90
Tousimis Research Corporation electrically conductive double-sided adhesive tape
a DoS electronics drawing process beginning with (i) a tape-based stencil attachment to the skin (scale bar 1 cm), (ii) drawing the device with the stencil, modified ballpoint pen, and inks (scale bar 5 mm), inset is a closeup of the tip (scale bar 1 mm), (iii) removal of the stencil (scale bar 2 cm), and (iv) the completed device after drying (scale bar 1 cm). b An example DoS integrated system including a resistor, transistors, heater, EP (electrophysiological) sensors, temperature sensor, strain sensor, and skin hydration sensor drawn on human skin (scale bar 5 mm). The corresponding stencil for the conductor is shown in the inset (scale bar 1 cm). c Achievable line spacing using stencils and the <t>conductive</t> Ag-PEDOT:PSS ink (scale bar 1 mm). d Non-stretched (left, scale bar 1 mm) and biaxially stretched (right, scale bar 1 cm) states of the drawn structure consisting of Ag-PEDOT:PSS conductive (left square) and P3HT-NF semiconducting (right square) inks on PDMS. e Twisting (left) and poking (right, scale bars 1 cm) deformations of the drawn structure with conductive and semiconducting inks. f SEM images of the Ag-PEDOT:PSS ink showing ultraconformal contact with the grooves and bumps (left, scale bar 250 µm) on top of skin replica and cross-section showing Ag-PEDOT:PSS microstructure (right, scale bar 20 µm). The purple color indicates the skin replica. g Histology image of the Ag-PEDOT:PSS ink on skin of mice after 48 h (scale bar 100 µm). h Histology image of the P3HT-NF ink on skin of mice after 48 h (scale bar 100 µm). i Sheet resistance vs. strain while stretching the Ag-PEDOT:PSS ink up to 30% and releasing. The error bars represent the s.d. j Optical microscope images of the Ag-PEDOT:PSS ink on skin replica stretched up to 30% (scale bars 100 µm). k DoS EP sensor on the wrist of subject in stretched (top) and non-stretched (bottom) states (scale bars 5 mm).
Electrically Conductive Double Sided Adhesive Tape, supplied by Tousimis Research Corporation, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/electrically conductive double-sided adhesive tape/product/Tousimis Research Corporation
Average 90 stars, based on 1 article reviews
electrically conductive double-sided adhesive tape - by Bioz Stars, 2026-05
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Image Search Results


a DoS electronics drawing process beginning with (i) a tape-based stencil attachment to the skin (scale bar 1 cm), (ii) drawing the device with the stencil, modified ballpoint pen, and inks (scale bar 5 mm), inset is a closeup of the tip (scale bar 1 mm), (iii) removal of the stencil (scale bar 2 cm), and (iv) the completed device after drying (scale bar 1 cm). b An example DoS integrated system including a resistor, transistors, heater, EP (electrophysiological) sensors, temperature sensor, strain sensor, and skin hydration sensor drawn on human skin (scale bar 5 mm). The corresponding stencil for the conductor is shown in the inset (scale bar 1 cm). c Achievable line spacing using stencils and the conductive Ag-PEDOT:PSS ink (scale bar 1 mm). d Non-stretched (left, scale bar 1 mm) and biaxially stretched (right, scale bar 1 cm) states of the drawn structure consisting of Ag-PEDOT:PSS conductive (left square) and P3HT-NF semiconducting (right square) inks on PDMS. e Twisting (left) and poking (right, scale bars 1 cm) deformations of the drawn structure with conductive and semiconducting inks. f SEM images of the Ag-PEDOT:PSS ink showing ultraconformal contact with the grooves and bumps (left, scale bar 250 µm) on top of skin replica and cross-section showing Ag-PEDOT:PSS microstructure (right, scale bar 20 µm). The purple color indicates the skin replica. g Histology image of the Ag-PEDOT:PSS ink on skin of mice after 48 h (scale bar 100 µm). h Histology image of the P3HT-NF ink on skin of mice after 48 h (scale bar 100 µm). i Sheet resistance vs. strain while stretching the Ag-PEDOT:PSS ink up to 30% and releasing. The error bars represent the s.d. j Optical microscope images of the Ag-PEDOT:PSS ink on skin replica stretched up to 30% (scale bars 100 µm). k DoS EP sensor on the wrist of subject in stretched (top) and non-stretched (bottom) states (scale bars 5 mm).

Journal: Nature Communications

Article Title: Ultra-conformal drawn-on-skin electronics for multifunctional motion artifact-free sensing and point-of-care treatment

doi: 10.1038/s41467-020-17619-1

Figure Lengend Snippet: a DoS electronics drawing process beginning with (i) a tape-based stencil attachment to the skin (scale bar 1 cm), (ii) drawing the device with the stencil, modified ballpoint pen, and inks (scale bar 5 mm), inset is a closeup of the tip (scale bar 1 mm), (iii) removal of the stencil (scale bar 2 cm), and (iv) the completed device after drying (scale bar 1 cm). b An example DoS integrated system including a resistor, transistors, heater, EP (electrophysiological) sensors, temperature sensor, strain sensor, and skin hydration sensor drawn on human skin (scale bar 5 mm). The corresponding stencil for the conductor is shown in the inset (scale bar 1 cm). c Achievable line spacing using stencils and the conductive Ag-PEDOT:PSS ink (scale bar 1 mm). d Non-stretched (left, scale bar 1 mm) and biaxially stretched (right, scale bar 1 cm) states of the drawn structure consisting of Ag-PEDOT:PSS conductive (left square) and P3HT-NF semiconducting (right square) inks on PDMS. e Twisting (left) and poking (right, scale bars 1 cm) deformations of the drawn structure with conductive and semiconducting inks. f SEM images of the Ag-PEDOT:PSS ink showing ultraconformal contact with the grooves and bumps (left, scale bar 250 µm) on top of skin replica and cross-section showing Ag-PEDOT:PSS microstructure (right, scale bar 20 µm). The purple color indicates the skin replica. g Histology image of the Ag-PEDOT:PSS ink on skin of mice after 48 h (scale bar 100 µm). h Histology image of the P3HT-NF ink on skin of mice after 48 h (scale bar 100 µm). i Sheet resistance vs. strain while stretching the Ag-PEDOT:PSS ink up to 30% and releasing. The error bars represent the s.d. j Optical microscope images of the Ag-PEDOT:PSS ink on skin replica stretched up to 30% (scale bars 100 µm). k DoS EP sensor on the wrist of subject in stretched (top) and non-stretched (bottom) states (scale bars 5 mm).

Article Snippet: Double-sided conductive acrylic tape (ARclad® 8001–77, Adhesives Research), cut to approximately the same dimensions as the DoS EP sensor, was laminated onto the sensors, and electrical leads were attached to the conductive tape.

Techniques: Modification, Microscopy

a Schematic of the DoS transistor based on the Ag-PEDOT:PSS ink as the conductor, P3HT-NF ink as the semiconductor, and ionic gel ink as the dielectric. b DoS transistor on skin replica under no strain (top) and 30% strain (bottom, scale bars 5 mm). c SEM image of the drawn source (S) and drain (D) electrodes and the channel (scale bar 100 µm). d I-V curve of DoS transistor without applied strain. e , f Transfer curves of DoS transistor without and 30% strain along the transistor channel length direction. g Electrical resistance of the DoS strain sensor under applied mechanical strain up to 30% and the corresponding gauge factors. Inset shows a schematic of the DoS strain sensor. The error bars represent the s.d. h Relative resistance change of the DoS strain sensor under cyclic stretching and releasing at 10% and 25% strain. i Relative resistance change of the DoS temperature sensor under different temperature conditions. j Schematic of the DoS heater based on the conductive ink. k Temperature profiles under different applied voltage on the DoS heater. l Calibration curve of the DoS heater. The error bars represent the s.d.

Journal: Nature Communications

Article Title: Ultra-conformal drawn-on-skin electronics for multifunctional motion artifact-free sensing and point-of-care treatment

doi: 10.1038/s41467-020-17619-1

Figure Lengend Snippet: a Schematic of the DoS transistor based on the Ag-PEDOT:PSS ink as the conductor, P3HT-NF ink as the semiconductor, and ionic gel ink as the dielectric. b DoS transistor on skin replica under no strain (top) and 30% strain (bottom, scale bars 5 mm). c SEM image of the drawn source (S) and drain (D) electrodes and the channel (scale bar 100 µm). d I-V curve of DoS transistor without applied strain. e , f Transfer curves of DoS transistor without and 30% strain along the transistor channel length direction. g Electrical resistance of the DoS strain sensor under applied mechanical strain up to 30% and the corresponding gauge factors. Inset shows a schematic of the DoS strain sensor. The error bars represent the s.d. h Relative resistance change of the DoS strain sensor under cyclic stretching and releasing at 10% and 25% strain. i Relative resistance change of the DoS temperature sensor under different temperature conditions. j Schematic of the DoS heater based on the conductive ink. k Temperature profiles under different applied voltage on the DoS heater. l Calibration curve of the DoS heater. The error bars represent the s.d.

Article Snippet: Double-sided conductive acrylic tape (ARclad® 8001–77, Adhesives Research), cut to approximately the same dimensions as the DoS EP sensor, was laminated onto the sensors, and electrical leads were attached to the conductive tape.

Techniques:

a Experimental setup showing DoS electrodes around a skin wound on the back of mice ( N = 3). The DoS electrodes served as conductive paths for electrical stimulation (scale bar 2 cm). b Photos of the wound healing on day 1 (left), day 3 (middle) and day 5 (right). Top half of the wound was treated with electrical stimulation while the bottom half was left untreated and healed naturally (scale bar 1 cm). c Histology images of the treated (top, scale bar 100 µm) and untreated (bottom, scale bar 250 µm) halves of the wound on day 5. The black arrows indicate the width of the wound. d Scab width over time for the treated (black) and untreated (red) halves of the wound.

Journal: Nature Communications

Article Title: Ultra-conformal drawn-on-skin electronics for multifunctional motion artifact-free sensing and point-of-care treatment

doi: 10.1038/s41467-020-17619-1

Figure Lengend Snippet: a Experimental setup showing DoS electrodes around a skin wound on the back of mice ( N = 3). The DoS electrodes served as conductive paths for electrical stimulation (scale bar 2 cm). b Photos of the wound healing on day 1 (left), day 3 (middle) and day 5 (right). Top half of the wound was treated with electrical stimulation while the bottom half was left untreated and healed naturally (scale bar 1 cm). c Histology images of the treated (top, scale bar 100 µm) and untreated (bottom, scale bar 250 µm) halves of the wound on day 5. The black arrows indicate the width of the wound. d Scab width over time for the treated (black) and untreated (red) halves of the wound.

Article Snippet: Double-sided conductive acrylic tape (ARclad® 8001–77, Adhesives Research), cut to approximately the same dimensions as the DoS EP sensor, was laminated onto the sensors, and electrical leads were attached to the conductive tape.

Techniques: