Review



3d printed instrumented cardiac microphysiological devices  (BioMimetic Therapeutics)

 
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  • 90

    Structured Review

    BioMimetic Therapeutics 3d printed instrumented cardiac microphysiological devices
    ( A ) <t>3D</t> printed Polycaprolactone (PCL) scaffold with fibers spacing 0.2 mm; ( B ) 3D printed PCL scaffold with fibers spacing 1.0 mm; ( C ) detailed image of scaffold with fibers spacing 1.0 mm; ( D ) hydrogel without PCL scaffold; ( E ) hydrogel reinforced with a PCL scaffold; and ( F ) DAPI staining demonstrated the homogenous distribution of the cells throughout the construct; ( A – F ) are reprinted from with permission of Nature Publishing Group, Copyright 2015. ( G ) 3D printed instrumented cardiac <t>microphysiological</t> devices for on-line monitoring, reprinted from with permission of Nature Publishing Group, Copyright 2016.
    3d Printed Instrumented Cardiac Microphysiological Devices, 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/product/3d+printed+instrumented+cardiac+microphysiological+devices/pmc06190223-227-23-4?v=BioMimetic+Therapeutics
    Average 90 stars, based on 1 article reviews
    3d printed instrumented cardiac microphysiological devices - by Bioz Stars, 2026-07
    90/100 stars

    Images

    1) Product Images from "The Emerging Frontiers and Applications of High-Resolution 3D Printing"

    Article Title: The Emerging Frontiers and Applications of High-Resolution 3D Printing

    Journal: Micromachines

    doi: 10.3390/mi8040113

    ( A ) 3D printed Polycaprolactone (PCL) scaffold with fibers spacing 0.2 mm; ( B ) 3D printed PCL scaffold with fibers spacing 1.0 mm; ( C ) detailed image of scaffold with fibers spacing 1.0 mm; ( D ) hydrogel without PCL scaffold; ( E ) hydrogel reinforced with a PCL scaffold; and ( F ) DAPI staining demonstrated the homogenous distribution of the cells throughout the construct; ( A – F ) are reprinted from with permission of Nature Publishing Group, Copyright 2015. ( G ) 3D printed instrumented cardiac microphysiological devices for on-line monitoring, reprinted from with permission of Nature Publishing Group, Copyright 2016.
    Figure Legend Snippet: ( A ) 3D printed Polycaprolactone (PCL) scaffold with fibers spacing 0.2 mm; ( B ) 3D printed PCL scaffold with fibers spacing 1.0 mm; ( C ) detailed image of scaffold with fibers spacing 1.0 mm; ( D ) hydrogel without PCL scaffold; ( E ) hydrogel reinforced with a PCL scaffold; and ( F ) DAPI staining demonstrated the homogenous distribution of the cells throughout the construct; ( A – F ) are reprinted from with permission of Nature Publishing Group, Copyright 2015. ( G ) 3D printed instrumented cardiac microphysiological devices for on-line monitoring, reprinted from with permission of Nature Publishing Group, Copyright 2016.

    Techniques Used: Staining, Construct, On-line Monitoring



    Similar Products

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    BioMimetic Therapeutics 3d printed instrumented cardiac microphysiological devices
    ( A ) <t>3D</t> printed Polycaprolactone (PCL) scaffold with fibers spacing 0.2 mm; ( B ) 3D printed PCL scaffold with fibers spacing 1.0 mm; ( C ) detailed image of scaffold with fibers spacing 1.0 mm; ( D ) hydrogel without PCL scaffold; ( E ) hydrogel reinforced with a PCL scaffold; and ( F ) DAPI staining demonstrated the homogenous distribution of the cells throughout the construct; ( A – F ) are reprinted from with permission of Nature Publishing Group, Copyright 2015. ( G ) 3D printed instrumented cardiac <t>microphysiological</t> devices for on-line monitoring, reprinted from with permission of Nature Publishing Group, Copyright 2016.
    3d Printed Instrumented Cardiac Microphysiological Devices, 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/product/3d+printed+instrumented+cardiac+microphysiological+devices/pmc06190223-227-23-4?v=BioMimetic+Therapeutics
    Average 90 stars, based on 1 article reviews
    3d printed instrumented cardiac microphysiological devices - by Bioz Stars, 2026-07
    90/100 stars
      Buy from Supplier

    Image Search Results


    ( A ) 3D printed Polycaprolactone (PCL) scaffold with fibers spacing 0.2 mm; ( B ) 3D printed PCL scaffold with fibers spacing 1.0 mm; ( C ) detailed image of scaffold with fibers spacing 1.0 mm; ( D ) hydrogel without PCL scaffold; ( E ) hydrogel reinforced with a PCL scaffold; and ( F ) DAPI staining demonstrated the homogenous distribution of the cells throughout the construct; ( A – F ) are reprinted from with permission of Nature Publishing Group, Copyright 2015. ( G ) 3D printed instrumented cardiac microphysiological devices for on-line monitoring, reprinted from with permission of Nature Publishing Group, Copyright 2016.

    Journal: Micromachines

    Article Title: The Emerging Frontiers and Applications of High-Resolution 3D Printing

    doi: 10.3390/mi8040113

    Figure Lengend Snippet: ( A ) 3D printed Polycaprolactone (PCL) scaffold with fibers spacing 0.2 mm; ( B ) 3D printed PCL scaffold with fibers spacing 1.0 mm; ( C ) detailed image of scaffold with fibers spacing 1.0 mm; ( D ) hydrogel without PCL scaffold; ( E ) hydrogel reinforced with a PCL scaffold; and ( F ) DAPI staining demonstrated the homogenous distribution of the cells throughout the construct; ( A – F ) are reprinted from with permission of Nature Publishing Group, Copyright 2015. ( G ) 3D printed instrumented cardiac microphysiological devices for on-line monitoring, reprinted from with permission of Nature Publishing Group, Copyright 2016.

    Article Snippet: Compared with the previous biomimetic microsystems which were not well suitable for higher-throughput or longer-term studies [ , ], the novel system of 3D printed instrumented cardiac microphysiological devices would drastically simplify data acquisition and leverage the ability to track the temporal development in tissue mechanics, enabling new insights into tissue development and drug-induced structural and functional remodeling.

    Techniques: Staining, Construct, On-line Monitoring