925055
TissueFab® GelAlg − LAP Bioink
low endotoxin, 0.2 μm filtered, suitable for 3D bioprinting applications
Synonym(s):
GelMA-alginate bioink
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About This Item
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Quality Level
sterility
0.2 μm filtered
form
viscous liquid (gel)
impurities
<5 cfu/mL Bioburden
<50 EU/mL Endotoxin
color
pale yellow to colorless
pH
6.5-7.5
viscosity
10-40 cP
application(s)
3D bioprinting
storage temp.
2-8°C
Related Categories
General description
Gelatin methacryloyl (GelMA) is a polymerizable hydrogel material derived from natural extracellular matrix (ECM) components. Due to its low cost, abundance, and retention of natural cell-binding motifs, gelatin has become a highly sought material for tissue engineering applications.
Alginate is a naturally occurring polymer widely applied for bioprinting applications as its printability can be easily modified by altering the polymer density and crosslinking with the addition of calcium chloride (CaCl2). Alginate is often combined with gelatin to facilitate cell adhesion and differentiation.
Temporal and spatial control of the crosslinking reaction can be obtained by adjusting the degree of functionalization and polymerization conditions, allowing for the fabrication of hydrogels with unique patterns, 3D structures, and morphologies.
Alginate is a naturally occurring polymer widely applied for bioprinting applications as its printability can be easily modified by altering the polymer density and crosslinking with the addition of calcium chloride (CaCl2). Alginate is often combined with gelatin to facilitate cell adhesion and differentiation.
Temporal and spatial control of the crosslinking reaction can be obtained by adjusting the degree of functionalization and polymerization conditions, allowing for the fabrication of hydrogels with unique patterns, 3D structures, and morphologies.
Application
Gelatin methacrylate based bioinks have been used in the following bioprinting applications:
- osteogenic [1],
- chondrogenic [2] [3],
- hepatic [4] [5] [6],
- adipogenic [7],
- vasculogenic [8],
- epithelial [6],
- endothelial [9] [10],
- cardiac valve [11],
- skin [12],
- tumors [10]
Features and Benefits
- Ready-to-use formulation optimized for high printing fidelity and cell viability, eliminating the lengthy bioink formulation development process
- Step-by-step protocols developed and tested by MilliporeSigma 3D Bioprinting Scientists, no prior 3D bioprinting experience needed
- Suitable for different extrusion-based 3D bioprinter model
- Methacrylamide functional group can also be used to control the hydrogel physical parameters such as pore size, degradation rate, and swell ratio.
Legal Information
TISSUEFAB is a registered trademark of Merck KGaA, Darmstadt, Germany
Storage Class Code
10 - Combustible liquids
WGK
WGK 3
Certificates of Analysis (COA)
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Biofabrication, 8(3), 035020-035020 (2016-09-17)
3D cell printing is an emerging technology for fabricating complex cell-laden constructs with precise and pre-designed geometry, structure and composition to overcome the limitations of 2D cell culture and conventional tissue engineering scaffold technology. This technology enables spatial manipulation of
Advanced healthcare materials, 6(12) (2017-05-04)
Bioprinting is an emerging technique for the fabrication of 3D cell-laden constructs. However, the progress for generating a 3D complex physiological microenvironment has been hampered by a lack of advanced cell-responsive bioinks that enable bioprinting with high structural fidelity, particularly
Methacrylated gelatin and mature adipocytes are promising components for adipose tissue engineering.
Journal of biomaterials applications, 30(6), 699-710 (2015-05-29)
In vitro engineering of autologous fatty tissue constructs is still a major challenge for the treatment of congenital deformities, tumor resections or high-graded burns. In this study, we evaluated the suitability of photo-crosslinkable methacrylated gelatin (GM) and mature adipocytes as components
Acta biomaterialia, 10(5), 1836-1846 (2013-12-18)
Tissue engineering has great potential to provide a functional de novo living valve replacement, capable of integration with host tissue and growth. Among various valve conduit fabrication techniques, three-dimensional (3-D) bioprinting enables deposition of cells and hydrogels into 3-D constructs
Biofabrication, 10(2), 024102-024102 (2017-11-28)
Bioinks with shear-thinning/rapid solidification properties and strong mechanics are usually needed for the bioprinting of three-dimensional (3D) cell-laden constructs. As such, it remains challenging to generate soft constructs from bioinks at low concentrations that are favorable for cellular activities. Herein
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