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Photocrosslinking Bioinks Customization Services
Thermal Crosslinking Bioinks Customization Services
Enzymatic Reaction Crosslinking Bioinks Customization Services
3D Bioprinting Micro-model Services
Solid Tumour Micro-model 3D Printing Service
Tumour Metastasis Micro-model 3D Printing Service
Complex Vascular Micro-model 3D Printing Service
NASH Micro-model 3D Printing Service
Skin Aging Micro-model 3D Printing Service
Melanoma Micro-model 3D Printing Service
Alzheimer's Disease Micro-model 3D Printing Service
Parkinson's Disease Micro-model 3D Printing Service
Lymphatic System Micro-model 3D Printing Service
Diabetes Model Micro-model 3D Printing Service
Bone Cancer Micro-model 3D Printing Service
Cartilage Micro-model 3D Printing Service
Pneumonia Micro-model 3D Printing Service
Drug Toxicology Testing Micro-model 3D Printing Service
3D Printing Technologies
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Applications of 3Dmicroflu™
Basic Physiological Mechanism Research Based on 3Dmicroflu™
Tissue Cell Growth Mechanism Research Based on 3Dmicroflu™
Organ Metabolic Mechanism Study Based on 3Dmicroflu™
Tissue Response Mechanism to External Stresses Research Based on 3Dmicroflu™
Disease Mechanism Research Based on 3Dmicroflu™
Tumour Mechanism Research Based on 3Dmicroflu™
Cardiovascular Disease Mechanism Research Based on 3Dmicroflu™
Fibrotic Disease Mechanism Research Based on 3Dmicroflu™
Dermatological Disease Mechanism Research Based on 3Dmicroflu™
Neurological Disease Mechanism Research Based on 3Dmicroflu™
Immune System Disease Mechanism Research Based on 3Dmicroflu™
Metabolic Disease Mechanism Research Based on 3Dmicroflu™
Osteoarticular Disease Mechanism Research Based on 3Dmicroflu™
Infectious Disease Mechanism Research Based on 3Dmicroflu™
Drug Development Based on 3Dmicroflu™
Drug Action Mechanism Research Based on 3Dmicroflu™
Pharmacokinetic Mechanism Study Based on 3Dmicroflu™
Pharmacodynamic Mechanism Study Based on 3Dmicroflu™
Drug Tolerance Analysis Based on 3Dmicroflu™
Drug Toxicology Study Based on 3Dmicroflu™
High Throughput Screening of Drugs Based on 3Dmicroflu™
High Throughput Screening of Vaccine Based on 3Dmicroflu™
High Throughput Screening of Small Molecule Drug Based on 3Dmicroflu™
High Throughput Screening of Antibody Drug Based on 3Dmicroflu™
High Throughput Screening of Cellular Drug Based on 3Dmicroflu™
Organ Repair Mechanism Research Based on 3Dmicroflu™
Skin Repair Study Based on 3Dmicroflu™
Bone Repair Study Based on 3Dmicroflu™
Organ Transplantation Feasibility Study Based on 3Dmicroflu™
Cosmetics Industry Quality Assessment Based on 3Dmicroflu™
Cosmetics Efficacy Evaluation Based on 3Dmicroflu™
Cosmetics Safety Testing Based on 3Dmicroflu™
Applications & Industries
Applications of 3D Printing
Manufacturing
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Resources
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
Advancements in Metal 3D Printing
Advancements in Plastic Materials for 3D Printing
ABS-like in 3D Printing
Nylon in 3D Printing
Polypropylene in 3D Printing
Thermoplastic Urethane in 3D Printing
Poly ether ether ketone in 3D Printing
Polycarbonate in 3D Printing
Composite in 3D Printing
Ceramics in 3D Printing
Alumina in 3D Printing
Aluminum Nitride in 3D Printing
Silicon Carbide in 3D Printing
Silicon Nitride in 3D Printing
Zirconia in 3D Printing
Boron Carbide in 3D Printing
Wood in 3D Printing
Wood-PLA in 3D Printing
3D Bioprinted Disease Models
3D Bioprinted Solid Tumor Models
3D Bioprinted Tumor Metastasis Models
3D Bioprinted Complex Vascular Models
3D Bioprinted NASH Models
3D Bioprinted Skin Aging Models
3D Bioprinted Melanoma Models
3D Bioprinted Alzheimer's Disease Models
3D Bioprinted Parkinson's Disease Models
3D Bioprinted Lymphatic System Disease Models
3D Bioprinted Diabetes Model
3D Bioprinted Bone Cancer Model
3D Bioprinted Cartilage Model
3D Bioprinted Pneumonia Model
3D Bioprinted Drug Toxicology Testing Micro-model
Advanced 3D Bioprinting Technology
FDM Bioprinting Technology
SLA Bioprinting Technology
SLS Bioprinting Technology
PolyJet Bioprinting Technology
SLM Bioprinting Technology
DMLS Bioprinting Technology
EBM Bioprinting Technology
DLP Bioprinting Technology
3DP Bioprinting Technology
Biological Applications Based on 3D Bioprinting
Research on Tissue Cell Growth Based on 3D Bioprinting
Research on Organ Metabolism Based on 3D Bioprinting
Research on Tissue Response to External Stress Based on 3D Bioprinting
Research on Skin Repair based on 3D Bioprinting
Research on Bone Repair Based on 3D Bioprinting
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
3D Printing in Lymphatic System Micro-model
3D Printing in Diabetes Model Micro-model
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ABS-M30
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Bio-ink Products
Gelatin-based Bioinks
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Alginate-based Bioinks
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Other Bioinks and Photoinitiators
Materials
Metal Materials
Titanium
Stainless Steel
Copper
Nickel Super Alloy
Cobalt-Chrome Alloy
Aluminum Alloy
Maraging Steel
Plastic Materials
ABS-like
Nylon
PP
TPU
PEEK
PC
Composite
Ceramics
Alumina
Aluminum Nitride
Silicon Carbide
Silicon Nitride
Zirconia
Boron Carbide
Wood
Wood-PLA
Materials on Demand
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ABS-M30
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Product Overview
Catalog No:
ABS0002
Inventory:
In-stock
Tensile Strength, MPa:
31
Elongation, %:
7
Hardness:
109.5 Rockwell
HDT, ℃:
82
Glass Transition, ℃:
108
Description:
ABS M30 material is significantly stronger than ordinary ABS and has enhanced interlayer bond strength, and its applications include tool clips and low-volume production parts.
For research use only, not intended for any clinical use.
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PC
Composite
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