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Perfusion Measurement Of A 3d Cultured Human Microvascular Network A

Perfusion Measurement Of A 3d Cultured Human Microvascular Network A

Perfusion Measurement Of A 3d Cultured Human Microvascular Network A

Perfusion Measurement Of A 3d Cultured Human Microvascular Network A
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Perfusion Measurement Of A 3d Cultured Human Microvascular Network A

Perfusion Measurement Of A 3d Cultured Human Microvascular Network A

Perfusion Measurement Of A 3d Cultured Human Microvascular Network A
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Perfusion Measurement Of A 3d Cultured Human Microvascular Network A

Perfusion Measurement Of A 3d Cultured Human Microvascular Network A

Perfusion Measurement Of A 3d Cultured Human Microvascular Network A
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Functional Human 3d Microvascular Networks On A Chip To Study The

Functional Human 3d Microvascular Networks On A Chip To Study The

Functional Human 3d Microvascular Networks On A Chip To Study The
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Human Microvascular Network Formation Based On Microfluidic 3d Huvec

Human Microvascular Network Formation Based On Microfluidic 3d Huvec

Human Microvascular Network Formation Based On Microfluidic 3d Huvec
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Functional Human 3d Microvascular Networks On A Chip To Study The

Functional Human 3d Microvascular Networks On A Chip To Study The

Functional Human 3d Microvascular Networks On A Chip To Study The
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Microvascular Network Formation Based On Microfluidic 3d Huvec Culture

Microvascular Network Formation Based On Microfluidic 3d Huvec Culture

Microvascular Network Formation Based On Microfluidic 3d Huvec Culture
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Functional Human 3d Microvascular Networks On A Chip To Study The

Functional Human 3d Microvascular Networks On A Chip To Study The

Functional Human 3d Microvascular Networks On A Chip To Study The
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Indoor Nanoscale Particulate Matter Induced Coagulation Abnormality

Indoor Nanoscale Particulate Matter Induced Coagulation Abnormality

Indoor Nanoscale Particulate Matter Induced Coagulation Abnormality
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Interstitial Flow Enhances The Formation Connectivity And Function Of

Interstitial Flow Enhances The Formation Connectivity And Function Of

Interstitial Flow Enhances The Formation Connectivity And Function Of
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Schematics Of Odp Of 3d Microvascular Networks Within A Hydrogel Fluid

Schematics Of Odp Of 3d Microvascular Networks Within A Hydrogel Fluid

Schematics Of Odp Of 3d Microvascular Networks Within A Hydrogel Fluid
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Arrays Of 3d Microvascular Networks A Side By Side Layout Of Three

Arrays Of 3d Microvascular Networks A Side By Side Layout Of Three

Arrays Of 3d Microvascular Networks A Side By Side Layout Of Three
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Interstitial Flow Enhances The Formation Connectivity And Function Of

Interstitial Flow Enhances The Formation Connectivity And Function Of

Interstitial Flow Enhances The Formation Connectivity And Function Of
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Figure 1 From Functional Human 3d Microvascular Networks On A Chip To

Figure 1 From Functional Human 3d Microvascular Networks On A Chip To

Figure 1 From Functional Human 3d Microvascular Networks On A Chip To
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Characterization Of Artificial Microvascular Networks A To D 3d

Characterization Of Artificial Microvascular Networks A To D 3d

Characterization Of Artificial Microvascular Networks A To D 3d
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Figure 4 From Engineering Of Functional Perfusable 3d Microvascular

Figure 4 From Engineering Of Functional Perfusable 3d Microvascular

Figure 4 From Engineering Of Functional Perfusable 3d Microvascular
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Engineering Microvascular Networks Through Bioprinting And Light Based

Engineering Microvascular Networks Through Bioprinting And Light Based

Engineering Microvascular Networks Through Bioprinting And Light Based
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Successful Formation Of 3d Microvascular Network Within The

Successful Formation Of 3d Microvascular Network Within The

Successful Formation Of 3d Microvascular Network Within The
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Functional Human 3d Microvascular Networks On A Chip To Study The

Functional Human 3d Microvascular Networks On A Chip To Study The

Functional Human 3d Microvascular Networks On A Chip To Study The
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Figure 2 From Engineering Of Functional Perfusable 3d Microvascular

Figure 2 From Engineering Of Functional Perfusable 3d Microvascular

Figure 2 From Engineering Of Functional Perfusable 3d Microvascular
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Perfusion Cultured Human Cells Were Directly Involved In The Formation

Perfusion Cultured Human Cells Were Directly Involved In The Formation

Perfusion Cultured Human Cells Were Directly Involved In The Formation
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In Vitro Extravasation Model Of Microvascular Network System A

In Vitro Extravasation Model Of Microvascular Network System A

In Vitro Extravasation Model Of Microvascular Network System A
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Omnidirectional Printing Of 3d Microvascular Networks A Deposition

Omnidirectional Printing Of 3d Microvascular Networks A Deposition

Omnidirectional Printing Of 3d Microvascular Networks A Deposition
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Figure 5 From Generation Of 3d Functional Microvascular Networks With

Figure 5 From Generation Of 3d Functional Microvascular Networks With

Figure 5 From Generation Of 3d Functional Microvascular Networks With
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Morphology Of The Microvascular Networks Formed By Ec Bmsc And Ec Asc

Morphology Of The Microvascular Networks Formed By Ec Bmsc And Ec Asc

Morphology Of The Microvascular Networks Formed By Ec Bmsc And Ec Asc
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Morphologies And Characteristics Of Co Cultured Microvascular Network

Morphologies And Characteristics Of Co Cultured Microvascular Network

Morphologies And Characteristics Of Co Cultured Microvascular Network
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Figure 1 From Microvascular Perfusion Based On Arterial Spin Labeled

Figure 1 From Microvascular Perfusion Based On Arterial Spin Labeled

Figure 1 From Microvascular Perfusion Based On Arterial Spin Labeled
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Engineering Microvascular Networks Through Vasculogenesis And

Engineering Microvascular Networks Through Vasculogenesis And

Engineering Microvascular Networks Through Vasculogenesis And
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Schematic Illustration Of A 3d Microvascular System Formed By

Schematic Illustration Of A 3d Microvascular System Formed By

Schematic Illustration Of A 3d Microvascular System Formed By
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3d Printing Of Vascularized Perfusable Thick Tissues A Schematic Of

3d Printing Of Vascularized Perfusable Thick Tissues A Schematic Of

3d Printing Of Vascularized Perfusable Thick Tissues A Schematic Of
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A 3d Preexisting Microvascular Network With Typical Pattern Of A

A 3d Preexisting Microvascular Network With Typical Pattern Of A

A 3d Preexisting Microvascular Network With Typical Pattern Of A
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Patterned Human Microvascular Grafts Enable Rapid Vascularization And

Patterned Human Microvascular Grafts Enable Rapid Vascularization And

Patterned Human Microvascular Grafts Enable Rapid Vascularization And
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Microfluidic In Vitro 3d Angiogenesis Assay Human Microvascular

Microfluidic In Vitro 3d Angiogenesis Assay Human Microvascular

Microfluidic In Vitro 3d Angiogenesis Assay Human Microvascular
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Microvascular Perfusion As Measured With Laser Doppler Flowmetry Ldf

Microvascular Perfusion As Measured With Laser Doppler Flowmetry Ldf

Microvascular Perfusion As Measured With Laser Doppler Flowmetry Ldf
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The Spatiotemporal Dynamic Growth Of 3d Microvascular Networks Inside

The Spatiotemporal Dynamic Growth Of 3d Microvascular Networks Inside

The Spatiotemporal Dynamic Growth Of 3d Microvascular Networks Inside
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