sensor array Search Results


electronic sensor array icm aqua checktm  (Perstorp Chemicals GmbH)
90
Perstorp Chemicals GmbH electronic sensor array icm aqua checktm
Electronic Sensor Array Icm Aqua Checktm, supplied by Perstorp Chemicals 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/electronic sensor array icm aqua checktm/product/Perstorp Chemicals GmbH
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cross-reactive sensor arrays  (BioMimetic Therapeutics)
90
BioMimetic Therapeutics cross-reactive sensor arrays
Cross Reactive Sensor Arrays, supplied by BioMimetic Therapeutics, 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/cross-reactive sensor arrays/product/BioMimetic Therapeutics
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cantilever sensor array and readout systems scentris  (Veeco)
90
Veeco cantilever sensor array and readout systems scentris
Cantilever Sensor Array And Readout Systems Scentris, supplied by Veeco, 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/cantilever sensor array and readout systems scentris/product/Veeco
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micam ultima cmos based camera  (Brainvision Inc)
90
Brainvision Inc micam ultima cmos based camera
Micam Ultima Cmos Based Camera, supplied by Brainvision Inc, 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/micam ultima cmos based camera/product/Brainvision Inc
Average 90 stars, based on 1 article reviews
micam ultima cmos based camera - by Bioz Stars, 2026-04
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cross-reactive chemical sensor arrays  (Schauer Agrotronic)
90
Schauer Agrotronic cross-reactive chemical sensor arrays
Cross Reactive Chemical Sensor Arrays, supplied by Schauer Agrotronic, 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/cross-reactive chemical sensor arrays/product/Schauer Agrotronic
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cross-reactive chemical sensor arrays - by Bioz Stars, 2026-04
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sensor array  (KRUSS GmbH)
90
KRUSS GmbH sensor array
Sensor Array, supplied by KRUSS 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/sensor array/product/KRUSS GmbH
Average 90 stars, based on 1 article reviews
sensor array - by Bioz Stars, 2026-04
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microneedle array sensor  (Eppendorf AG)
90
Eppendorf AG microneedle array sensor
Fabrication and characterization of the SiNW-FET-based <t>microneedle</t> array sensor. (a) Schematic illustration of the top-down fabrication process. (b) SEM images of the fabricated needles; the needles are 150 μm in width and ca. 250 μm in thickness (scale bar: 125 μm). The green inset shows the opening of the SU-8 layer that forms the device window (scale bar: 25 μm). The blue inset shows a close-up image on one of the two devices inside the device window. The source-drain pads lie on pads fabricated from the device layer for better contact and surface area. The nanowires are a part of the device layer, laying on the buried oxide, and are 125 nm in width and 75 nm high (scale bar: 5 μm). (c) Electrical characterization of a representative device. The source-drain voltage was swept between −0.4 and 0.15 V, and the gate was kept constant at −0.3 V (black curve), −0.2 V (red curve), −0.1 V (green curve), 0 V (blue curve), and 0.1 V (light blue curve). Inset illustrates how the measurement was made, mimicking the ex vivo experiments as close as possible. (d) Transconductance measurements of five individual devices on the same microneedle FET. Vsd was kept constant on 0.1 V while the gate was swept between (−0.3) V to 0.4 V.
Microneedle Array Sensor, supplied by Eppendorf AG, 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/microneedle array sensor/product/Eppendorf AG
Average 90 stars, based on 1 article reviews
microneedle array sensor - by Bioz Stars, 2026-04
90/100 stars
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eddy current array system jentek 8000  (Jentek Sensors Inc)
90
Jentek Sensors Inc eddy current array system jentek 8000
Fabrication and characterization of the SiNW-FET-based <t>microneedle</t> array sensor. (a) Schematic illustration of the top-down fabrication process. (b) SEM images of the fabricated needles; the needles are 150 μm in width and ca. 250 μm in thickness (scale bar: 125 μm). The green inset shows the opening of the SU-8 layer that forms the device window (scale bar: 25 μm). The blue inset shows a close-up image on one of the two devices inside the device window. The source-drain pads lie on pads fabricated from the device layer for better contact and surface area. The nanowires are a part of the device layer, laying on the buried oxide, and are 125 nm in width and 75 nm high (scale bar: 5 μm). (c) Electrical characterization of a representative device. The source-drain voltage was swept between −0.4 and 0.15 V, and the gate was kept constant at −0.3 V (black curve), −0.2 V (red curve), −0.1 V (green curve), 0 V (blue curve), and 0.1 V (light blue curve). Inset illustrates how the measurement was made, mimicking the ex vivo experiments as close as possible. (d) Transconductance measurements of five individual devices on the same microneedle FET. Vsd was kept constant on 0.1 V while the gate was swept between (−0.3) V to 0.4 V.
Eddy Current Array System Jentek 8000, supplied by Jentek Sensors Inc, 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/eddy current array system jentek 8000/product/Jentek Sensors Inc
Average 90 stars, based on 1 article reviews
eddy current array system jentek 8000 - by Bioz Stars, 2026-04
90/100 stars
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mini mca (multiple camera array) 11 plus incident light sensor (ils) camera  (Tetracam Inc)
90
Tetracam Inc mini mca (multiple camera array) 11 plus incident light sensor (ils) camera
Fabrication and characterization of the SiNW-FET-based <t>microneedle</t> array sensor. (a) Schematic illustration of the top-down fabrication process. (b) SEM images of the fabricated needles; the needles are 150 μm in width and ca. 250 μm in thickness (scale bar: 125 μm). The green inset shows the opening of the SU-8 layer that forms the device window (scale bar: 25 μm). The blue inset shows a close-up image on one of the two devices inside the device window. The source-drain pads lie on pads fabricated from the device layer for better contact and surface area. The nanowires are a part of the device layer, laying on the buried oxide, and are 125 nm in width and 75 nm high (scale bar: 5 μm). (c) Electrical characterization of a representative device. The source-drain voltage was swept between −0.4 and 0.15 V, and the gate was kept constant at −0.3 V (black curve), −0.2 V (red curve), −0.1 V (green curve), 0 V (blue curve), and 0.1 V (light blue curve). Inset illustrates how the measurement was made, mimicking the ex vivo experiments as close as possible. (d) Transconductance measurements of five individual devices on the same microneedle FET. Vsd was kept constant on 0.1 V while the gate was swept between (−0.3) V to 0.4 V.
Mini Mca (Multiple Camera Array) 11 Plus Incident Light Sensor (Ils) Camera, supplied by Tetracam Inc, 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/mini mca (multiple camera array) 11 plus incident light sensor (ils) camera/product/Tetracam Inc
Average 90 stars, based on 1 article reviews
mini mca (multiple camera array) 11 plus incident light sensor (ils) camera - by Bioz Stars, 2026-04
90/100 stars
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wgm sensor/sensor array  (Genalyte Inc)
90
Genalyte Inc wgm sensor/sensor array
Fabrication and characterization of the SiNW-FET-based <t>microneedle</t> array sensor. (a) Schematic illustration of the top-down fabrication process. (b) SEM images of the fabricated needles; the needles are 150 μm in width and ca. 250 μm in thickness (scale bar: 125 μm). The green inset shows the opening of the SU-8 layer that forms the device window (scale bar: 25 μm). The blue inset shows a close-up image on one of the two devices inside the device window. The source-drain pads lie on pads fabricated from the device layer for better contact and surface area. The nanowires are a part of the device layer, laying on the buried oxide, and are 125 nm in width and 75 nm high (scale bar: 5 μm). (c) Electrical characterization of a representative device. The source-drain voltage was swept between −0.4 and 0.15 V, and the gate was kept constant at −0.3 V (black curve), −0.2 V (red curve), −0.1 V (green curve), 0 V (blue curve), and 0.1 V (light blue curve). Inset illustrates how the measurement was made, mimicking the ex vivo experiments as close as possible. (d) Transconductance measurements of five individual devices on the same microneedle FET. Vsd was kept constant on 0.1 V while the gate was swept between (−0.3) V to 0.4 V.
Wgm Sensor/Sensor Array, supplied by Genalyte Inc, 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/wgm sensor/sensor array/product/Genalyte Inc
Average 90 stars, based on 1 article reviews
wgm sensor/sensor array - by Bioz Stars, 2026-04
90/100 stars
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graphene sensor arrays  (Graphene Platform)
90
Graphene Platform graphene sensor arrays
(A) Design of the flexible microfluidic three-working electrode (3WE) sensor array for cortisol detection and photograph of the printed circuit board (PCB) with the <t>graphene</t> sensor patch for signal processing and wireless communication. WE, working electrode; CE, counter electrode; RE, reference electrode.
Graphene Sensor Arrays, supplied by Graphene Platform, 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/graphene sensor arrays/product/Graphene Platform
Average 90 stars, based on 1 article reviews
graphene sensor arrays - by Bioz Stars, 2026-04
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tactile sensor array  (BioMimetic Therapeutics)
90
BioMimetic Therapeutics tactile sensor array
(A) Design of the flexible microfluidic three-working electrode (3WE) sensor array for cortisol detection and photograph of the printed circuit board (PCB) with the <t>graphene</t> sensor patch for signal processing and wireless communication. WE, working electrode; CE, counter electrode; RE, reference electrode.
Tactile Sensor Array, supplied by BioMimetic Therapeutics, 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/tactile sensor array/product/BioMimetic Therapeutics
Average 90 stars, based on 1 article reviews
tactile sensor array - by Bioz Stars, 2026-04
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Image Search Results


Fabrication and characterization of the SiNW-FET-based microneedle array sensor. (a) Schematic illustration of the top-down fabrication process. (b) SEM images of the fabricated needles; the needles are 150 μm in width and ca. 250 μm in thickness (scale bar: 125 μm). The green inset shows the opening of the SU-8 layer that forms the device window (scale bar: 25 μm). The blue inset shows a close-up image on one of the two devices inside the device window. The source-drain pads lie on pads fabricated from the device layer for better contact and surface area. The nanowires are a part of the device layer, laying on the buried oxide, and are 125 nm in width and 75 nm high (scale bar: 5 μm). (c) Electrical characterization of a representative device. The source-drain voltage was swept between −0.4 and 0.15 V, and the gate was kept constant at −0.3 V (black curve), −0.2 V (red curve), −0.1 V (green curve), 0 V (blue curve), and 0.1 V (light blue curve). Inset illustrates how the measurement was made, mimicking the ex vivo experiments as close as possible. (d) Transconductance measurements of five individual devices on the same microneedle FET. Vsd was kept constant on 0.1 V while the gate was swept between (−0.3) V to 0.4 V.

Journal: ACS Nano

Article Title: The “Bloodless” Blood Test: Intradermal Prick Nanoelectronics for the Blood Extraction-Free Multiplex Detection of Protein Biomarkers

doi: 10.1021/acsnano.2c01793

Figure Lengend Snippet: Fabrication and characterization of the SiNW-FET-based microneedle array sensor. (a) Schematic illustration of the top-down fabrication process. (b) SEM images of the fabricated needles; the needles are 150 μm in width and ca. 250 μm in thickness (scale bar: 125 μm). The green inset shows the opening of the SU-8 layer that forms the device window (scale bar: 25 μm). The blue inset shows a close-up image on one of the two devices inside the device window. The source-drain pads lie on pads fabricated from the device layer for better contact and surface area. The nanowires are a part of the device layer, laying on the buried oxide, and are 125 nm in width and 75 nm high (scale bar: 5 μm). (c) Electrical characterization of a representative device. The source-drain voltage was swept between −0.4 and 0.15 V, and the gate was kept constant at −0.3 V (black curve), −0.2 V (red curve), −0.1 V (green curve), 0 V (blue curve), and 0.1 V (light blue curve). Inset illustrates how the measurement was made, mimicking the ex vivo experiments as close as possible. (d) Transconductance measurements of five individual devices on the same microneedle FET. Vsd was kept constant on 0.1 V while the gate was swept between (−0.3) V to 0.4 V.

Article Snippet: The microneedle array sensor was placed inside an Eppendorf containing a 2 mL solution of either unspiked (“clean”) or PSA-spiked solutions in different concentrations until stabilization (approximately 8 min).

Techniques: Ex Vivo

Microneedle array dimensions and blood contact. (a) Optical image of comparison in size between common 27G needle for venous blood extraction and the proposed microneedle array sensors. Two types of fabricated microneedles length are shown −400 μm and 1 mm. Scale bar: 5 mm. (b) Schematic illustration of microneedle insertion to the forearm. 1 mm microneedle should reach the blood capillaries in the dermis, while 400 μm needles will not reach as effectively. (c) Optical images showing the microneedle before (top) and after (bottom) a blood droplet was placed on the microneedle. Orange inset shows blood is clearly able to enter the SU-8 window. (d) Optical image showing the microneedle after insertion to the skin. (e) Schematic illustration of a different possible location for protein detection in the blood. The microneedle array can be used in the finger without or with prior pricking.

Journal: ACS Nano

Article Title: The “Bloodless” Blood Test: Intradermal Prick Nanoelectronics for the Blood Extraction-Free Multiplex Detection of Protein Biomarkers

doi: 10.1021/acsnano.2c01793

Figure Lengend Snippet: Microneedle array dimensions and blood contact. (a) Optical image of comparison in size between common 27G needle for venous blood extraction and the proposed microneedle array sensors. Two types of fabricated microneedles length are shown −400 μm and 1 mm. Scale bar: 5 mm. (b) Schematic illustration of microneedle insertion to the forearm. 1 mm microneedle should reach the blood capillaries in the dermis, while 400 μm needles will not reach as effectively. (c) Optical images showing the microneedle before (top) and after (bottom) a blood droplet was placed on the microneedle. Orange inset shows blood is clearly able to enter the SU-8 window. (d) Optical image showing the microneedle after insertion to the skin. (e) Schematic illustration of a different possible location for protein detection in the blood. The microneedle array can be used in the finger without or with prior pricking.

Article Snippet: The microneedle array sensor was placed inside an Eppendorf containing a 2 mL solution of either unspiked (“clean”) or PSA-spiked solutions in different concentrations until stabilization (approximately 8 min).

Techniques: Comparison, Extraction

Skin insertion and contact with blood vessels. (a) Images of the insertion process of the microneedle array sensors into the forearm. (b) Images showing several insertion experiments of 1 mm microneedle array (left) and 0.4 mm microneedle array (right) to the forearm. (c) Summarized results of blood drawing from insertion experiments of 1 mm microneedle array (red) and 0.4 mm microneedle array (green) to the forearm. (d) Statistical distribution of blood drawing success percentage from 50 insertion experiments of 1 mm microneedle array (black) and 0.4 mm microneedle array (red) to the forearm.

Journal: ACS Nano

Article Title: The “Bloodless” Blood Test: Intradermal Prick Nanoelectronics for the Blood Extraction-Free Multiplex Detection of Protein Biomarkers

doi: 10.1021/acsnano.2c01793

Figure Lengend Snippet: Skin insertion and contact with blood vessels. (a) Images of the insertion process of the microneedle array sensors into the forearm. (b) Images showing several insertion experiments of 1 mm microneedle array (left) and 0.4 mm microneedle array (right) to the forearm. (c) Summarized results of blood drawing from insertion experiments of 1 mm microneedle array (red) and 0.4 mm microneedle array (green) to the forearm. (d) Statistical distribution of blood drawing success percentage from 50 insertion experiments of 1 mm microneedle array (black) and 0.4 mm microneedle array (red) to the forearm.

Article Snippet: The microneedle array sensor was placed inside an Eppendorf containing a 2 mL solution of either unspiked (“clean”) or PSA-spiked solutions in different concentrations until stabilization (approximately 8 min).

Techniques:

In vivo results of different measurements using the microneedle array. (a) Stabilization curves of PSA association at 10 pM (red curve) and 100 pM (blue curve) spiked-PBS solutions. The results indicate that the sensor requires approximately 60 s to achieve a differentiable signal. (b) One cycle close-up view taken once dissociation stabilization is achieved for PSA-spiked PBS buffer. (c) One cycle close-up view taken once dissociation stabilization is achieved for PSA-spiked serum. (d) Normalized response linear curves derived from (a) and (b). The dissociation phase was conducted in 5% EG in 100 μM phosphate buffer solution. Normalized reaction is in comparison to nonspiked buffer or serum, respectively. Pink data relates to nonspecific normalized response to 22 ng/mL cTnI and 21 ng/mL GFP. (e) In vivo intradermal capillary PSA concentrations were measured in four subjects using the microneedle array (green bars) compared to ELISA measurements of PSA concentration in venous blood (blue dots). (f) Multiplex experiment results of normalized response to PSA-spiked buffer from a device modified with PSA-specific antibody (αPSA, black curve) and a device modified with cTnI-specific antibody (αcTnI, red curve). (g) Multiplex experiment results of normalized response to cTnI-spiked buffer from a device modified with PSA-specific antibody (αPSA, black curve) and a device modified with cTnI-specific antibody (αcTnI, red curve). (i) Top: Deviation measurements performed on a single device via multiple entries to (100 pM spiked serum solution). Bottom: Variance measurements were performed between different devices via normalized response against a 100 pM spiked serum.

Journal: ACS Nano

Article Title: The “Bloodless” Blood Test: Intradermal Prick Nanoelectronics for the Blood Extraction-Free Multiplex Detection of Protein Biomarkers

doi: 10.1021/acsnano.2c01793

Figure Lengend Snippet: In vivo results of different measurements using the microneedle array. (a) Stabilization curves of PSA association at 10 pM (red curve) and 100 pM (blue curve) spiked-PBS solutions. The results indicate that the sensor requires approximately 60 s to achieve a differentiable signal. (b) One cycle close-up view taken once dissociation stabilization is achieved for PSA-spiked PBS buffer. (c) One cycle close-up view taken once dissociation stabilization is achieved for PSA-spiked serum. (d) Normalized response linear curves derived from (a) and (b). The dissociation phase was conducted in 5% EG in 100 μM phosphate buffer solution. Normalized reaction is in comparison to nonspiked buffer or serum, respectively. Pink data relates to nonspecific normalized response to 22 ng/mL cTnI and 21 ng/mL GFP. (e) In vivo intradermal capillary PSA concentrations were measured in four subjects using the microneedle array (green bars) compared to ELISA measurements of PSA concentration in venous blood (blue dots). (f) Multiplex experiment results of normalized response to PSA-spiked buffer from a device modified with PSA-specific antibody (αPSA, black curve) and a device modified with cTnI-specific antibody (αcTnI, red curve). (g) Multiplex experiment results of normalized response to cTnI-spiked buffer from a device modified with PSA-specific antibody (αPSA, black curve) and a device modified with cTnI-specific antibody (αcTnI, red curve). (i) Top: Deviation measurements performed on a single device via multiple entries to (100 pM spiked serum solution). Bottom: Variance measurements were performed between different devices via normalized response against a 100 pM spiked serum.

Article Snippet: The microneedle array sensor was placed inside an Eppendorf containing a 2 mL solution of either unspiked (“clean”) or PSA-spiked solutions in different concentrations until stabilization (approximately 8 min).

Techniques: In Vivo, Derivative Assay, Comparison, Enzyme-linked Immunosorbent Assay, Concentration Assay, Multiplex Assay, Modification

Laboratory-scale 3D-printed mount. (a) Illustration of the mount that enables the microneedle-based sensor operation. The mount chip is held for the user to prick his finger using the microneedles, followed by capping of the mount and consecutive washing in the appropriate buffer solution. (b) Optical images show the 3D-printed mount and the laboratory-scale system. (c) Optical image illustrating finger pricking using the 3D-printed mount.

Journal: ACS Nano

Article Title: The “Bloodless” Blood Test: Intradermal Prick Nanoelectronics for the Blood Extraction-Free Multiplex Detection of Protein Biomarkers

doi: 10.1021/acsnano.2c01793

Figure Lengend Snippet: Laboratory-scale 3D-printed mount. (a) Illustration of the mount that enables the microneedle-based sensor operation. The mount chip is held for the user to prick his finger using the microneedles, followed by capping of the mount and consecutive washing in the appropriate buffer solution. (b) Optical images show the 3D-printed mount and the laboratory-scale system. (c) Optical image illustrating finger pricking using the 3D-printed mount.

Article Snippet: The microneedle array sensor was placed inside an Eppendorf containing a 2 mL solution of either unspiked (“clean”) or PSA-spiked solutions in different concentrations until stabilization (approximately 8 min).

Techniques:

(A) Design of the flexible microfluidic three-working electrode (3WE) sensor array for cortisol detection and photograph of the printed circuit board (PCB) with the graphene sensor patch for signal processing and wireless communication. WE, working electrode; CE, counter electrode; RE, reference electrode.

Journal: Matter

Article Title: Investigation of cortisol dynamics in human sweat using a graphene-based wireless mHealth system

doi: 10.1016/j.matt.2020.01.021

Figure Lengend Snippet: (A) Design of the flexible microfluidic three-working electrode (3WE) sensor array for cortisol detection and photograph of the printed circuit board (PCB) with the graphene sensor patch for signal processing and wireless communication. WE, working electrode; CE, counter electrode; RE, reference electrode.

Article Snippet: CRH, corticotrophin-releasing hormone; ACTH, adrenocorticotropic hormone. (B and C) Conceptual illustration of cortisol dynamics regulated by circadian rhythm (B) and triggered by physiological and psychological stress (C). (D) Illustration of the laser engraving process of a graphene platform. (E) Graphene sensor arrays mass-produced on a polyimide (PI) substrate. (F) Image of a disposable flexible graphene sensor array. (G) Transmission electron microscopy (TEM) image of the graphene electrode surface.

Techniques: