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What are Bioinks
What is Gelatin-based Bioinks
How to Use Gelatin-Based Bioinks
When to Use Gelatin-based Bioinks
What is Hyaluronic Acid-based Bioinks
How to Use Hyaluronic Acid-based Bioinks
When to Use Hyaluronic Acid-based Bioinks
What is Alginate-based Bioinks
How to Use Alginate-based Bioinks
When to Use Alginate-based Bioinks
What is Protein-based Bioinks?
How to Use Protein-based Bioinks
When to Use Protein-based Bioinks
What is Polymer-based Bioinks
How to Use Polymer-Based Bioinks
What are the Characteristics of Polymer-Based Bioinks
What is Agarose Bioinks?
How to Use Agarose Bioinks?
What are the Characteristics of Agarose Bioinks?
What is Physical Crosslinking Bioinks?
How to Use Physical Crosslinking Bioinks?
What are the Characteristics of Physical Crosslinking Bioinks
What is Ionic Crosslinking Bioinks
How to Use Ionic Crosslinking Bioinks
What are the Characteristics of Ionic Crosslinking Bioinks
What is Hydrogen Bonding Crosslinking Bioinks
How to Use Hydrogen Bonding Crosslinking Bioinks
What is Host-Guest Interaction Crosslinking Bioinks?
What are the Characteristics of Hydrogen Bonding Crosslinking Bioinks?
How to Use Host-guest Interaction Crosslinking Bioinks?
What is Chemical Crosslinking Bioinks
How to Use Chemical Crosslinking Bioinks?
What are the Characteristics of Chemical Crosslinking Bioinks
What is Photocrosslinking Bioinks?
What are the Photo-Crosslinked Bioink Materials
What Materials are Suitable for Printing with Photo-crosslinked Bioinks?
What is Thermal Crosslinking Bioinks?
How to Use Thermal Crosslinking Bioinks?
What Materials are Suitable for Printing with Thermal Crosslinking Bioinks?
What is Enzymatic Reaction Crosslinking Bioinks?
Application of Bioinks
New application of bioink GelMA—Corneal Stroma Regeneration
Methacrylic Anhydride Gelatin Bio-3D Printing Operation Tutorial
What is Gelatin-based Bioinks?
Progress of 3D Bioprinting in Organ Manufacturing
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3D Bioprinted Disease Models
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Organ Transplantation Feasibility Based on 3D Bioprinting
Application of 3D Bioprinting Technology in Tumor Research
Application of 3D Bioprinting Technology in Cardiovascular Disease
Solid Tumor Micro-model 3D Printing Revolutionizing Cancer Research
3D Printing Opens Up New Frontiers in Tumor Metastasis Micromodel Research
What is 3D Printing Technology for Complex Vascular Micromodels?
3D Printed NASH Micromodels Help NASH Research
3D Printed Skin Aging Micro-model Help Skin Aging Research
Advantages of 3D Printed Melanoma Micromodels
3D Printing in Alzheimer's Disease Modeling
3D Printing in Parkinson's Disease Micro-model
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3D Printing in Diabetes Model Micro-model
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Nylon 11
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TPU
PEEK
PC
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Silicon Nitride
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Product Overview
Catalog No:
PA0002
Inventory:
In-stock
Color:
White
Density, g/cm
3
:
1.04
Tensile Strength, MPa:
47
Tensile Modulus, MPa:
1647
Elongation, %:
21
Impact, J:
Notched: 70
Unnotched: 1370
Electrical Resistivity:
Volume resistivity: 1.00x10
15
Ω.m-cm
Flexural Strength, MPa:
44
Flexural Modulus, MPa:
869
HDT, ℃:
157
Description:
Nylon 11 material has excellent elongation at break, impact resistance and an excellent surface finish. The material is commonly used in the aerospace, racing and consumer goods industries.
For research use only, not intended for any clinical use.
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