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Autodesk Inc microfluidic device components
Design and workflow of the modular <t>microfluidic</t> platform. A. Schematic of the device and platform assembly illustrating the multilayer <t>components.</t> The complete assembly is designed to fit within an atmospheric control box for cell culture. B . Picture of a fully assembled device loaded with food dye. Red indicates control channels, while blue indicates fluid channels and cell chambers. C. Flowchart comparing the proposed modular assembly method (red arrows) with the conventional approach (black arrows). For multilayer chip fabrication, mandatory steps include (i) mixing/degassing PDMS for control layer, (ii) PDMS spin coating for fluid layer, (iii) overnight baking, (iv) surface plasma treatment; (v) aligning and bonding; (vi) hole punching. Our modular design mitigates assembly-related failures and enables rapid reuse of the chip within 2 h, thereby substantially increasing experimental success rates and effective throughput.
Microfluidic Device Components, supplied by Autodesk Inc, used in various techniques. Bioz Stars score: 86/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/product/microfluidic+device+components/bio_rxiv__64898__2026__01__12__699088-177-1-7?v=Autodesk+Inc
Average 86 stars, based on 1 article reviews
microfluidic device components - by Bioz Stars, 2026-07
86/100 stars

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1) Product Images from "Rapid and reusable high-throughput microfluidics through modular assembly"

Article Title: Rapid and reusable high-throughput microfluidics through modular assembly

Journal: bioRxiv

doi: 10.64898/2026.01.12.699088

Design and workflow of the modular microfluidic platform. A. Schematic of the device and platform assembly illustrating the multilayer components. The complete assembly is designed to fit within an atmospheric control box for cell culture. B . Picture of a fully assembled device loaded with food dye. Red indicates control channels, while blue indicates fluid channels and cell chambers. C. Flowchart comparing the proposed modular assembly method (red arrows) with the conventional approach (black arrows). For multilayer chip fabrication, mandatory steps include (i) mixing/degassing PDMS for control layer, (ii) PDMS spin coating for fluid layer, (iii) overnight baking, (iv) surface plasma treatment; (v) aligning and bonding; (vi) hole punching. Our modular design mitigates assembly-related failures and enables rapid reuse of the chip within 2 h, thereby substantially increasing experimental success rates and effective throughput.
Figure Legend Snippet: Design and workflow of the modular microfluidic platform. A. Schematic of the device and platform assembly illustrating the multilayer components. The complete assembly is designed to fit within an atmospheric control box for cell culture. B . Picture of a fully assembled device loaded with food dye. Red indicates control channels, while blue indicates fluid channels and cell chambers. C. Flowchart comparing the proposed modular assembly method (red arrows) with the conventional approach (black arrows). For multilayer chip fabrication, mandatory steps include (i) mixing/degassing PDMS for control layer, (ii) PDMS spin coating for fluid layer, (iii) overnight baking, (iv) surface plasma treatment; (v) aligning and bonding; (vi) hole punching. Our modular design mitigates assembly-related failures and enables rapid reuse of the chip within 2 h, thereby substantially increasing experimental success rates and effective throughput.

Techniques Used: Control, Cell Culture, Clinical Proteomics

Fabrication and assembly of the modular microfluidic platform. A. Schematic workflow for fabricating the reusable PDMS fluid-control module. Control holes are punched prior to alignment. B. Workflow for the thin-substrate. A hybrid adhesive polymer (mixture of adhesive silicone and PDMS) is spin-coated onto a glass slide and cured to create a reversible sealing interface. C. Workflow for the deep-well substrate for 3D culture. Using a 3D-printed master, 1 mm deep chambers are molded in PDMS with a glass slide on top. D. Cross-sectional diagrams of the final device assembly. The fluid-control module and deep-well substrate are manually aligned using outlines incorporated into the design and the corresponding inset in the aluminum tray, then mechanically clamped. Negative pressure can be applied to further increase flow rate.
Figure Legend Snippet: Fabrication and assembly of the modular microfluidic platform. A. Schematic workflow for fabricating the reusable PDMS fluid-control module. Control holes are punched prior to alignment. B. Workflow for the thin-substrate. A hybrid adhesive polymer (mixture of adhesive silicone and PDMS) is spin-coated onto a glass slide and cured to create a reversible sealing interface. C. Workflow for the deep-well substrate for 3D culture. Using a 3D-printed master, 1 mm deep chambers are molded in PDMS with a glass slide on top. D. Cross-sectional diagrams of the final device assembly. The fluid-control module and deep-well substrate are manually aligned using outlines incorporated into the design and the corresponding inset in the aluminum tray, then mechanically clamped. Negative pressure can be applied to further increase flow rate.

Techniques Used: Control, Adhesive, Polymer



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Design and workflow of the modular <t>microfluidic</t> platform. A. Schematic of the device and platform assembly illustrating the multilayer <t>components.</t> The complete assembly is designed to fit within an atmospheric control box for cell culture. B . Picture of a fully assembled device loaded with food dye. Red indicates control channels, while blue indicates fluid channels and cell chambers. C. Flowchart comparing the proposed modular assembly method (red arrows) with the conventional approach (black arrows). For multilayer chip fabrication, mandatory steps include (i) mixing/degassing PDMS for control layer, (ii) PDMS spin coating for fluid layer, (iii) overnight baking, (iv) surface plasma treatment; (v) aligning and bonding; (vi) hole punching. Our modular design mitigates assembly-related failures and enables rapid reuse of the chip within 2 h, thereby substantially increasing experimental success rates and effective throughput.
Microfluidic Device Components, supplied by Autodesk Inc, used in various techniques. Bioz Stars score: 86/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/product/microfluidic+device+components/bio_rxiv__64898__2026__01__12__699088-177-1-7?v=Autodesk+Inc
Average 86 stars, based on 1 article reviews
microfluidic device components - by Bioz Stars, 2026-07
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Design and workflow of the modular <t>microfluidic</t> platform. A. Schematic of the device and platform assembly illustrating the multilayer <t>components.</t> The complete assembly is designed to fit within an atmospheric control box for cell culture. B . Picture of a fully assembled device loaded with food dye. Red indicates control channels, while blue indicates fluid channels and cell chambers. C. Flowchart comparing the proposed modular assembly method (red arrows) with the conventional approach (black arrows). For multilayer chip fabrication, mandatory steps include (i) mixing/degassing PDMS for control layer, (ii) PDMS spin coating for fluid layer, (iii) overnight baking, (iv) surface plasma treatment; (v) aligning and bonding; (vi) hole punching. Our modular design mitigates assembly-related failures and enables rapid reuse of the chip within 2 h, thereby substantially increasing experimental success rates and effective throughput.
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Design and workflow of the modular microfluidic platform. A. Schematic of the device and platform assembly illustrating the multilayer components. The complete assembly is designed to fit within an atmospheric control box for cell culture. B . Picture of a fully assembled device loaded with food dye. Red indicates control channels, while blue indicates fluid channels and cell chambers. C. Flowchart comparing the proposed modular assembly method (red arrows) with the conventional approach (black arrows). For multilayer chip fabrication, mandatory steps include (i) mixing/degassing PDMS for control layer, (ii) PDMS spin coating for fluid layer, (iii) overnight baking, (iv) surface plasma treatment; (v) aligning and bonding; (vi) hole punching. Our modular design mitigates assembly-related failures and enables rapid reuse of the chip within 2 h, thereby substantially increasing experimental success rates and effective throughput.

Journal: bioRxiv

Article Title: Rapid and reusable high-throughput microfluidics through modular assembly

doi: 10.64898/2026.01.12.699088

Figure Lengend Snippet: Design and workflow of the modular microfluidic platform. A. Schematic of the device and platform assembly illustrating the multilayer components. The complete assembly is designed to fit within an atmospheric control box for cell culture. B . Picture of a fully assembled device loaded with food dye. Red indicates control channels, while blue indicates fluid channels and cell chambers. C. Flowchart comparing the proposed modular assembly method (red arrows) with the conventional approach (black arrows). For multilayer chip fabrication, mandatory steps include (i) mixing/degassing PDMS for control layer, (ii) PDMS spin coating for fluid layer, (iii) overnight baking, (iv) surface plasma treatment; (v) aligning and bonding; (vi) hole punching. Our modular design mitigates assembly-related failures and enables rapid reuse of the chip within 2 h, thereby substantially increasing experimental success rates and effective throughput.

Article Snippet: All microfluidic device components were designed using Autodesk 2025, Onshape, AutoCAD (Autodesk Inc.), or KLayout.

Techniques: Control, Cell Culture, Clinical Proteomics

Fabrication and assembly of the modular microfluidic platform. A. Schematic workflow for fabricating the reusable PDMS fluid-control module. Control holes are punched prior to alignment. B. Workflow for the thin-substrate. A hybrid adhesive polymer (mixture of adhesive silicone and PDMS) is spin-coated onto a glass slide and cured to create a reversible sealing interface. C. Workflow for the deep-well substrate for 3D culture. Using a 3D-printed master, 1 mm deep chambers are molded in PDMS with a glass slide on top. D. Cross-sectional diagrams of the final device assembly. The fluid-control module and deep-well substrate are manually aligned using outlines incorporated into the design and the corresponding inset in the aluminum tray, then mechanically clamped. Negative pressure can be applied to further increase flow rate.

Journal: bioRxiv

Article Title: Rapid and reusable high-throughput microfluidics through modular assembly

doi: 10.64898/2026.01.12.699088

Figure Lengend Snippet: Fabrication and assembly of the modular microfluidic platform. A. Schematic workflow for fabricating the reusable PDMS fluid-control module. Control holes are punched prior to alignment. B. Workflow for the thin-substrate. A hybrid adhesive polymer (mixture of adhesive silicone and PDMS) is spin-coated onto a glass slide and cured to create a reversible sealing interface. C. Workflow for the deep-well substrate for 3D culture. Using a 3D-printed master, 1 mm deep chambers are molded in PDMS with a glass slide on top. D. Cross-sectional diagrams of the final device assembly. The fluid-control module and deep-well substrate are manually aligned using outlines incorporated into the design and the corresponding inset in the aluminum tray, then mechanically clamped. Negative pressure can be applied to further increase flow rate.

Article Snippet: All microfluidic device components were designed using Autodesk 2025, Onshape, AutoCAD (Autodesk Inc.), or KLayout.

Techniques: Control, Adhesive, Polymer