730327
Poly(ethylene glycol) methyl ether methacrylate
average Mn 4,000, methacrylate, methoxy, ≤300 ppm MEHQ as inhibitor
Synonym(s):
Polyethylene glycol, Methoxy PEG methacrylate, Methoxy poly(ethylene glycol) monomethacrylate, Poly(ethylene glycol) monomethyl ether monomethacrylate
About This Item
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product name
Poly(ethylene glycol) methyl ether methacrylate, average Mn 4,000, contains ≤300 ppm monomethyl ether hydroquinone as inhibitor
form
powder or crystals
Quality Level
mol wt
average Mn 4,000
contains
≤300 ppm monomethyl ether hydroquinone as inhibitor
reaction suitability
reagent type: chemical modification reagent
reaction type: Polymerization Reactions
transition temp
Tm 56-61 °C
density
1.100 g/cm3
Mw/Mn
<1.1
Ω-end
methacrylate
α-end
methoxy
polymer architecture
shape: linear
functionality: monofunctional
storage temp.
−20°C
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Preparation Note
Signal Word
Warning
Hazard Statements
Precautionary Statements
Hazard Classifications
Eye Irrit. 2 - Skin Irrit. 2 - Skin Sens. 1 - STOT SE 3
Target Organs
Respiratory system
Storage Class Code
11 - Combustible Solids
WGK
WGK 1
Flash Point(F)
>230.0 °F - closed cup
Flash Point(C)
> 110 °C - closed cup
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Progress in biotechnology fields such as tissue engineering and drug delivery is accompanied by an increasing demand for diverse functional biomaterials. One class of biomaterials that has been the subject of intense research interest is hydrogels, because they closely mimic the natural environment of cells, both chemically and physically and therefore can be used as support to grow cells. This article specifically discusses poly(ethylene glycol) (PEG) hydrogels, which are good for biological applications because they do not generally elicit an immune response. PEGs offer a readily available, easy to modify polymer for widespread use in hydrogel fabrication, including 2D and 3D scaffold for tissue culture. The degradable linkages also enable a variety of applications for release of therapeutic agents.
Designing biomaterial scaffolds mimicking complex living tissue structures is crucial for tissue engineering and regenerative medicine advancements.
Designing biomaterial scaffolds mimicking complex living tissue structures is crucial for tissue engineering and regenerative medicine advancements.
Designing biomaterial scaffolds mimicking complex living tissue structures is crucial for tissue engineering and regenerative medicine advancements.
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