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| Product | Description | |
|---|---|---|
| 4arm-PEG20K-Isocyanate | average Mn 20,000. Group: Poly(ethylene glycol) and poly(ethylene oxide). |  |
| 4arm-PEG20K-Isocyanate | Polyethylene glycol (PEG) compounds contain a polyether unit, commonly expressed as R1-(O-CH2-CH2)n-O-R2. They are generally biocompatible, non-toxic and stable in both organic and aqueous solutions, and so are extensively used in biological applications, as well as nanotechnology and materials research. Proteins with PEG chain modifications and compounds encapsulated in PEG liposomes exhibit a longer half-life in vivo than their non-PEGylated counterparts, a phenomenon known as PEG shielding. Functionalised PEG lipids and phospholipids can be used for protein-PEG conjugation. Uses: Activated peg derivatives can be used to modify peptides, proteins, or in other bioconjugation applications. pegylated materials have found broad use in drug delivery systems, virology, and immunology, as the incorporation of peg improves pharmacological properties such as increased water solubility, enhanced resistance to degradation (protein hydrolysis), increased circulation half-life, and reduced antigenicity. in addition to pegylation, activated peg derivatives can also be used to form networks for tissue engineering or drug delivery applications, depending on the architecture and reactivity. Group: Poly(ethylene glycol) and poly(ethylene oxide). Alternative Names: 4arm-PEG-Isocyanate. Molecular formula: average Mn 20000. |  |
| 4arm-PEG20K-Maleimide | Polyethylene glycol (PEG) compounds contain a polyether unit, commonly expressed as R1-(O-CH2-CH2)n-O-R2. They are generally biocompatible, non-toxic and stable in both organic and aqueous solutions, and so are extensively used in biological applications, as well as nanotechnology and materials research. Proteins with PEG chain modifications and compounds encapsulated in PEG liposomes exhibit a longer half-life in vivo than their non-PEGylated counterparts, a phenomenon known as PEG shielding. Functionalised PEG lipids and phospholipids can be used for protein-PEG conjugation. Uses: Activated peg derivatives can be used to modify peptides, proteins, or in other bioconjugation applications. pegylated materials have found broad use in drug delivery systems, virology, and immunology, as the incorporation of peg improves pharmacological properties such as increased water solubility, enhanced resistance to degradation (protein hydrolysis), increased circulation half-life, and reduced antigenicity. in addition to pegylation, activated peg derivatives can also be used to form networks for tissue engineering or drug delivery applications, depending on the architecture and reactivity. Group: Poly(ethylene glycol) and poly(ethylene oxide). Alternative Names: 4arm-PEG-MAL, 4arm-PEG-Maleimide. Molecular formula: average Mn 20000. | |
| 4arm-PEG20K-Maleimide | average Mn 20,000. Group: Poly(ethylene glycol) and poly(ethylene oxide). | |
| 4arm-PEG20K-NH2 | HCl Salt, average Mn 20,000. Group: Poly(ethylene glycol) and poly(ethylene oxide). | |
| 4arm-PEG20K-NH2 | Polyethylene glycol (PEG) compounds contain a polyether unit, commonly expressed as R1-(O-CH2-CH2)n-O-R2. They are generally biocompatible, non-toxic and stable in both organic and aqueous solutions, and so are extensively used in biological applications, as well as nanotechnology and materials research. Proteins with PEG chain modifications and compounds encapsulated in PEG liposomes exhibit a longer half-life in vivo than their non-PEGylated counterparts, a phenomenon known as PEG shielding. Functionalised PEG lipids and phospholipids can be used for protein-PEG conjugation. Uses: Activated peg derivatives can be used to modify peptides, proteins, or in other bioconjugation applications. pegylated materials have found broad use in drug delivery systems, virology, and immunology, as the incorporation of peg improves pharmacological properties such as increased water solubility, enhanced resistance to degradation (protein hydrolysis), increased circulation half-life, and reduced antigenicity. in addition to pegylation, activated peg derivatives can also be used to form networks for tissue engineering or drug delivery applications, depending on the architecture and reactivity. Group: Poly(ethylene glycol) and poly(ethylene oxide). Alternative Names: 4arm-PEG-NH2, 4arm-PEG-amine. Molecular formula: average Mn 20000. | |
| 4arm-PEG20K-SH | Polyethylene glycol (PEG) compounds contain a polyether unit, commonly expressed as R1-(O-CH2-CH2)n-O-R2. They are generally biocompatible, non-toxic and stable in both organic and aqueous solutions, and so are extensively used in biological applications, as well as nanotechnology and materials research. Proteins with PEG chain modifications and compounds encapsulated in PEG liposomes exhibit a longer half-life in vivo than their non-PEGylated counterparts, a phenomenon known as PEG shielding. Functionalised PEG lipids and phospholipids can be used for protein-PEG conjugation. Uses: Activated peg derivatives can be used to modify peptides, proteins, or in other bioconjugation applications. pegylated materials have found broad use in drug delivery systems, virology, and immunology, as the incorporation of peg improves pharmacological properties such as increased water solubility, enhanced resistance to degradation (protein hydrolysis), increased circulation half-life, and reduced antigenicity. in addition to pegylation, activated peg derivatives can also be used to form networks for tissue engineering or drug delivery applications, depending on the architecture and reactivity. Group: Poly(ethylene glycol) and poly(ethylene oxide). Alternative Names: 4arm-PEG-SH. Molecular formula: average Mn 20000. | |
| 4arm-PEG20K-SH | average Mn 20,000. Group: Poly(ethylene glycol) and poly(ethylene oxide). | |
| 4arm-PEG20K-Succinimidyl Carboxymethyl Ester | average Mn 20,000. Group: Poly(ethylene glycol) and poly(ethylene oxide). | |
| 4arm-PEG20K-Succinimidyl Carboxymethyl Ester | Polyethylene glycol (PEG) compounds contain a polyether unit, commonly expressed as R1-(O-CH2-CH2)n-O-R2. They are generally biocompatible, non-toxic and stable in both organic and aqueous solutions, and so are extensively used in biological applications, as well as nanotechnology and materials research. Proteins with PEG chain modifications and compounds encapsulated in PEG liposomes exhibit a longer half-life in vivo than their non-PEGylated counterparts, a phenomenon known as PEG shielding. Functionalised PEG lipids and phospholipids can be used for protein-PEG conjugation. Uses: Activated peg derivatives can be used to modify peptides, proteins, or in other bioconjugation applications. pegylated materials have found broad use in drug delivery systems, virology, and immunology, as the incorporation of peg improves pharmacological properties such as increased water solubility, enhanced resistance to degradation (protein hydrolysis), increased circulation half-life, and reduced antigenicity. in addition to pegylation, activated peg derivatives can also be used to form networks for tissue engineering or drug delivery applications, depending on the architecture and reactivity. Group: Poly(ethylene glycol) and poly(ethylene oxide). Alternative Names: 4arm-PEG-Succinimidyl Carboxymethyl Ester. Molecular formula: average Mn 20000. | |
| 4arm-PEG20K-Succinimidyl Carboxymethyl Glutaramide | Polyethylene glycol (PEG) compounds contain a polyether unit, commonly expressed as R1-(O-CH2-CH2)n-O-R2. They are generally biocompatible, non-toxic and stable in both organic and aqueous solutions, and so are extensively used in biological applications, as well as nanotechnology and materials research. Proteins with PEG chain modifications and compounds encapsulated in PEG liposomes exhibit a longer half-life in vivo than their non-PEGylated counterparts, a phenomenon known as PEG shielding. Functionalised PEG lipids and phospholipids can be used for protein-PEG conjugation. Uses: Activated peg derivatives can be used to modify peptides, proteins, or in other bioconjugation applications. pegylated materials have found broad use in drug delivery systems, virology, and immunology, as the incorporation of peg improves pharmacological properties such as increased water solubility, enhanced resistance to degradation (protein hydrolysis), increased circulation half-life, and reduced antigenicity. in addition to pegylation, activated peg derivatives can also be used to form networks for tissue engineering or drug delivery applications, depending on the architecture and reactivity. Group: Poly(ethylene glycol) and poly(ethylene oxide). Alternative Names: 4arm-PEG-Succinimidyl Carboxymethyl Glutaramide. Molecular formula: average Mn 20000. | |
| 4arm-PEG20K-Succinimidyl Carboxymethyl Glutaramide | average Mn 20,000. Group: Poly(ethylene glycol) and poly(ethylene oxide). | |
| 4arm-PEG20K-Succinimidyl Glutarate | average Mn 20,000. Group: Poly(ethylene glycol) and poly(ethylene oxide). | |
| 4arm-PEG20K-Succinimidyl Glutarate | Polyethylene glycol (PEG) compounds contain a polyether unit, commonly expressed as R1-(O-CH2-CH2)n-O-R2. They are generally biocompatible, non-toxic and stable in both organic and aqueous solutions, and so are extensively used in biological applications, as well as nanotechnology and materials research. Proteins with PEG chain modifications and compounds encapsulated in PEG liposomes exhibit a longer half-life in vivo than their non-PEGylated counterparts, a phenomenon known as PEG shielding. Functionalised PEG lipids and phospholipids can be used for protein-PEG conjugation. Uses: Activated peg derivatives can be used to modify peptides, proteins, or in other bioconjugation applications. pegylated materials have found broad use in drug delivery systems, virology, and immunology, as the incorporation of peg improves pharmacological properties such as increased water solubility, enhanced resistance to degradation (protein hydrolysis), increased circulation half-life, and reduced antigenicity. in addition to pegylation, activated peg derivatives can also be used to form networks for tissue engineering or drug delivery applications, depending on the architecture and reactivity. Group: Poly(ethylene glycol) and poly(ethylene oxide). Alternative Names: 4arm-PEG-Succinimidyl Glutarate. Molecular formula: average Mn 20000. | |
| 4arm-PEG20K-Succinimidyl Succinate | Polyethylene glycol (PEG) compounds contain a polyether unit, commonly expressed as R1-(O-CH2-CH2)n-O-R2. They are generally biocompatible, non-toxic and stable in both organic and aqueous solutions, and so are extensively used in biological applications, as well as nanotechnology and materials research. Proteins with PEG chain modifications and compounds encapsulated in PEG liposomes exhibit a longer half-life in vivo than their non-PEGylated counterparts, a phenomenon known as PEG shielding. Functionalised PEG lipids and phospholipids can be used for protein-PEG conjugation. Uses: Activated peg derivatives can be used to modify peptides, proteins, or in other bioconjugation applications. pegylated materials have found broad use in drug delivery systems, virology, and immunology, as the incorporation of peg improves pharmacological properties such as increased water solubility, enhanced resistance to degradation (protein hydrolysis), increased circulation half-life, and reduced antigenicity. in addition to pegylation, activated peg derivatives can also be used to form networks for tissue engineering or drug delivery applications, depending on the architecture and reactivity. Group: Poly(ethylene glycol) and poly(ethylene oxide). Alternative Names: 4arm-PEG-Succinimidyl Succinate. Molecular formula: average Mn 20000. | |
| 4arm-PEG20K-Succinimidyl Succinate | average Mn 20,000. Group: Poly(ethylene glycol) and poly(ethylene oxide). | |
| 4arm-PEG20K-Vinylsulfone | average Mn 20,000. Group: Poly(ethylene glycol) and poly(ethylene oxide). | |
| 4arm-PEG20K-Vinylsulfone | Polyethylene glycol (PEG) compounds contain a polyether unit, commonly expressed as R1-(O-CH2-CH2)n-O-R2. They are generally biocompatible, non-toxic and stable in both organic and aqueous solutions, and so are extensively used in biological applications, as well as nanotechnology and materials research. Proteins with PEG chain modifications and compounds encapsulated in PEG liposomes exhibit a longer half-life in vivo than their non-PEGylated counterparts, a phenomenon known as PEG shielding. Functionalised PEG lipids and phospholipids can be used for protein-PEG conjugation. Uses: Activated peg derivatives can be used to modify peptides, proteins, or in other bioconjugation applications. pegylated materials have found broad use in drug delivery systems, virology, and immunology, as the incorporation of peg improves pharmacological properties such as increased water solubility, enhanced resistance to degradation (protein hydrolysis), increased circulation half-life, and reduced antigenicity. in addition to pegylation, activated peg derivatives can also be used to form networks for tissue engineering or drug delivery applications, depending on the architecture and reactivity. Group: Poly(ethylene glycol) and poly(ethylene oxide). Alternative Names: 4arm-PEG-VS, 4arm-PEG-Vinylsulfone. Molecular formula: average Mn 20000. | |
| 4arm-PEG2500-PCL2500 | Polyethylene glycol (PEG) compounds contain a polyether unit, commonly expressed as R1-(O-CH2-CH2)n-O-R2. They are generally biocompatible, non-toxic and stable in both organic and aqueous solutions, and so are extensively used in biological applications, as well as nanotechnology and materials research. Proteins with PEG chain modifications and compounds encapsulated in PEG liposomes exhibit a longer half-life in vivo than their non-PEGylated counterparts, a phenomenon known as PEG shielding. Functionalised PEG lipids and phospholipids can be used for protein-PEG conjugation. Uses: Activated peg derivatives can be used to modify peptides, proteins, or in other bioconjugation applications. pegylated materials have found broad use in drug delivery systems, virology, and immunology, as the incorporation of peg improves pharmacological properties such as increased water solubility, enhanced resistance to degradation (protein hydrolysis), increased circulation half-life, and reduced antigenicity. in addition to pegylation, activated peg derivatives can also be used to form networks for tissue engineering or drug delivery applications, depending on the architecture and reactivity. Group: Poly(ethylene glycol) and poly(ethylene oxide). Alternative Names: 4arm-PEG-PCL. Molecular formula: PCL average Mn 2,500 PEG average Mn 2,500. | |
| 4arm-PEG2500-PCL2500 | PEG average Mn 2,500, PCL average Mn 2,500. Group: Poly(ethylene glycol) and poly(ethylene oxide). | |
| 4arm-PEG2500-PLA3500 | PEG average Mn 2,500, PCL average Mn 3,500. Group: Poly(ethylene glycol) and poly(ethylene oxide). | |
| 4arm-PEG2500-PLA3500 | Polyethylene glycol (PEG) compounds contain a polyether unit, commonly expressed as R1-(O-CH2-CH2)n-O-R2. They are generally biocompatible, non-toxic and stable in both organic and aqueous solutions, and so are extensively used in biological applications, as well as nanotechnology and materials research. Proteins with PEG chain modifications and compounds encapsulated in PEG liposomes exhibit a longer half-life in vivo than their non-PEGylated counterparts, a phenomenon known as PEG shielding. Functionalised PEG lipids and phospholipids can be used for protein-PEG conjugation. Uses: Activated peg derivatives can be used to modify peptides, proteins, or in other bioconjugation applications. pegylated materials have found broad use in drug delivery systems, virology, and immunology, as the incorporation of peg improves pharmacological properties such as increased water solubility, enhanced resistance to degradation (protein hydrolysis), increased circulation half-life, and reduced antigenicity. in addition to pegylation, activated peg derivatives can also be used to form networks for tissue engineering or drug delivery applications, depending on the architecture and reactivity. Group: Poly(ethylene glycol) and poly(ethylene oxide). Alternative Names: 4arm-PEG-PLA. Molecular formula: PCL average Mn 3,500 PEG average Mn 2,500. | |
| 4arm-PEG2K-NH2 | Polyethylene glycol (PEG) compounds contain a polyether unit, commonly expressed as R1-(O-CH2-CH2)n-O-R2. They are generally biocompatible, non-toxic and stable in both organic and aqueous solutions, and so are extensively used in biological applications, as well as nanotechnology and materials research. Proteins with PEG chain modifications and compounds encapsulated in PEG liposomes exhibit a longer half-life in vivo than their non-PEGylated counterparts, a phenomenon known as PEG shielding. Functionalised PEG lipids and phospholipids can be used for protein-PEG conjugation. Uses: Activated peg derivatives can be used to modify peptides, proteins, or in other bioconjugation applications. pegylated materials have found broad use in drug delivery systems, virology, and immunology, as the incorporation of peg improves pharmacological properties such as increased water solubility, enhanced resistance to degradation (protein hydrolysis), increased circulation half-life, and reduced antigenicity. in addition to pegylation, activated peg derivatives can also be used to form networks for tissue engineering or drug delivery applications, depending on the architecture and reactivity. Group: Poly(ethylene glycol) and poly(ethylene oxide). Alternative Names: 4arm-PEG-NH2, 4arm-PEG-amine. Molecular formula: average Mn 2000. | |
| 4arm-PEG2K-NH2 | average Mn 2,000. Group: Poly(ethylene glycol) and poly(ethylene oxide). | |
| 4arm-PEG3K 3arm-OH, 1arm-COOH | average Mn 3000. Group: Poly(ethylene glycol) and poly(ethylene oxide). | |
| 4arm-PEG3K 3arm-OH, 1arm-COOH | Polyethylene glycol (PEG) compounds contain a polyether unit, commonly expressed as R1-(O-CH2-CH2)n-O-R2. They are generally biocompatible, non-toxic and stable in both organic and aqueous solutions, and so are extensively used in biological applications, as well as nanotechnology and materials research. Proteins with PEG chain modifications and compounds encapsulated in PEG liposomes exhibit a longer half-life in vivo than their non-PEGylated counterparts, a phenomenon known as PEG shielding. Functionalised PEG lipids and phospholipids can be used for protein-PEG conjugation. Uses: Activated peg derivatives can be used to modify peptides, proteins, or in other bioconjugation applications. pegylated materials have found broad use in drug delivery systems, virology, and immunology, as the incorporation of peg improves pharmacological properties such as increased water solubility, enhanced resistance to degradation (protein hydrolysis), increased circulation half-life, and reduced antigenicity. in addition to pegylation, activated peg derivatives can also be used to form networks for tissue engineering or drug delivery applications, depending on the architecture and reactivity. Group: Poly(ethylene glycol) and poly(ethylene oxide). Molecular formula: average Mn 3000. | |
| 4arm-PEG40K-COOH | Polyethylene glycol (PEG) compounds contain a polyether unit, commonly expressed as R1-(O-CH2-CH2)n-O-R2. They are generally biocompatible, non-toxic and stable in both organic and aqueous solutions, and so are extensively used in biological applications, as well as nanotechnology and materials research. Proteins with PEG chain modifications and compounds encapsulated in PEG liposomes exhibit a longer half-life in vivo than their non-PEGylated counterparts, a phenomenon known as PEG shielding. Functionalised PEG lipids and phospholipids can be used for protein-PEG conjugation. Uses: Activated peg derivatives can be used to modify peptides, proteins, or in other bioconjugation applications. pegylated materials have found broad use in drug delivery systems, virology, and immunology, as the incorporation of peg improves pharmacological properties such as increased water solubility, enhanced resistance to degradation (protein hydrolysis), increased circulation half-life, and reduced antigenicity. in addition to pegylation, activated peg derivatives can also be used to form networks for tissue engineering or drug delivery applications, depending on the architecture and reactivity. Group: Poly(ethylene glycol) and poly(ethylene oxide). Alternative Names: 4arm-PEG-COOH, 4arm-PEG-Carboxyl. Molecular formula: average Mn 40000. | |
| 4arm-PEG40K-COOH | average Mn 40,000. Group: Poly(ethylene glycol) and poly(ethylene oxide). | |
| 4arm-PEG40K-Maleimide | average Mn 40,000. Group: Poly(ethylene glycol) and poly(ethylene oxide). | |
| 4arm-PEG40K-Maleimide | Polyethylene glycol (PEG) compounds contain a polyether unit, commonly expressed as R1-(O-CH2-CH2)n-O-R2. They are generally biocompatible, non-toxic and stable in both organic and aqueous solutions, and so are extensively used in biological applications, as well as nanotechnology and materials research. Proteins with PEG chain modifications and compounds encapsulated in PEG liposomes exhibit a longer half-life in vivo than their non-PEGylated counterparts, a phenomenon known as PEG shielding. Functionalised PEG lipids and phospholipids can be used for protein-PEG conjugation. Uses: Activated peg derivatives can be used to modify peptides, proteins, or in other bioconjugation applications. pegylated materials have found broad use in drug delivery systems, virology, and immunology, as the incorporation of peg improves pharmacological properties such as increased water solubility, enhanced resistance to degradation (protein hydrolysis), increased circulation half-life, and reduced antigenicity. in addition to pegylation, activated peg derivatives can also be used to form networks for tissue engineering or drug delivery applications, depending on the architecture and reactivity. Group: Poly(ethylene glycol) and poly(ethylene oxide). Alternative Names: 4arm-PEG-MAL, 4arm-PEG-Maleimide. Molecular formula: average Mn 40000. | |
| 4arm-PEG40K-NH2 | Polyethylene glycol (PEG) compounds contain a polyether unit, commonly expressed as R1-(O-CH2-CH2)n-O-R2. They are generally biocompatible, non-toxic and stable in both organic and aqueous solutions, and so are extensively used in biological applications, as well as nanotechnology and materials research. Proteins with PEG chain modifications and compounds encapsulated in PEG liposomes exhibit a longer half-life in vivo than their non-PEGylated counterparts, a phenomenon known as PEG shielding. Functionalised PEG lipids and phospholipids can be used for protein-PEG conjugation. Uses: Activated peg derivatives can be used to modify peptides, proteins, or in other bioconjugation applications. pegylated materials have found broad use in drug delivery systems, virology, and immunology, as the incorporation of peg improves pharmacological properties such as increased water solubility, enhanced resistance to degradation (protein hydrolysis), increased circulation half-life, and reduced antigenicity. in addition to pegylation, activated peg derivatives can also be used to form networks for tissue engineering or drug delivery applications, depending on the architecture and reactivity. Group: Poly(ethylene glycol) and poly(ethylene oxide). Alternative Names: 4arm-PEG-NH2, 4arm-PEG-amine. Molecular formula: average Mn 40000. | |
| 4arm-PEG40K-NH2 | HCl Salt, average Mn 40,000. Group: Poly(ethylene glycol) and poly(ethylene oxide). | |
| 4arm-PEG40K-Succinimidyl Carboxymethyl Ester | average Mn 40,000. Group: Poly(ethylene glycol) and poly(ethylene oxide). | |
| 4arm-PEG40K-Succinimidyl Carboxymethyl Ester | Polyethylene glycol (PEG) compounds contain a polyether unit, commonly expressed as R1-(O-CH2-CH2)n-O-R2. They are generally biocompatible, non-toxic and stable in both organic and aqueous solutions, and so are extensively used in biological applications, as well as nanotechnology and materials research. Proteins with PEG chain modifications and compounds encapsulated in PEG liposomes exhibit a longer half-life in vivo than their non-PEGylated counterparts, a phenomenon known as PEG shielding. Functionalised PEG lipids and phospholipids can be used for protein-PEG conjugation. Uses: Activated peg derivatives can be used to modify peptides, proteins, or in other bioconjugation applications. pegylated materials have found broad use in drug delivery systems, virology, and immunology, as the incorporation of peg improves pharmacological properties such as increased water solubility, enhanced resistance to degradation (protein hydrolysis), increased circulation half-life, and reduced antigenicity. in addition to pegylation, activated peg derivatives can also be used to form networks for tissue engineering or drug delivery applications, depending on the architecture and reactivity. Group: Poly(ethylene glycol) and poly(ethylene oxide). Alternative Names: 4arm-PEG-Succinimidyl Carboxymethyl Ester. Molecular formula: average Mn 40000. | |
| 4arm-PEG40K-Succinimidyl Glutarate | Polyethylene glycol (PEG) compounds contain a polyether unit, commonly expressed as R1-(O-CH2-CH2)n-O-R2. They are generally biocompatible, non-toxic and stable in both organic and aqueous solutions, and so are extensively used in biological applications, as well as nanotechnology and materials research. Proteins with PEG chain modifications and compounds encapsulated in PEG liposomes exhibit a longer half-life in vivo than their non-PEGylated counterparts, a phenomenon known as PEG shielding. Functionalised PEG lipids and phospholipids can be used for protein-PEG conjugation. Uses: Activated peg derivatives can be used to modify peptides, proteins, or in other bioconjugation applications. pegylated materials have found broad use in drug delivery systems, virology, and immunology, as the incorporation of peg improves pharmacological properties such as increased water solubility, enhanced resistance to degradation (protein hydrolysis), increased circulation half-life, and reduced antigenicity. in addition to pegylation, activated peg derivatives can also be used to form networks for tissue engineering or drug delivery applications, depending on the architecture and reactivity. Group: Poly(ethylene glycol) and poly(ethylene oxide). Alternative Names: 4arm-PEG-Succinimidyl Glutarate. Molecular formula: average Mn 40000. | |
| 4arm-PEG40K-Succinimidyl Glutarate | average Mn 40,000. Group: Poly(ethylene glycol) and poly(ethylene oxide). | |
| 4arm-PEG40K-Succinimidyl Succinate | average Mn 40,000. Group: Poly(ethylene glycol) and poly(ethylene oxide). | |
| 4arm-PEG40K-Succinimidyl Succinate | Polyethylene glycol (PEG) compounds contain a polyether unit, commonly expressed as R1-(O-CH2-CH2)n-O-R2. They are generally biocompatible, non-toxic and stable in both organic and aqueous solutions, and so are extensively used in biological applications, as well as nanotechnology and materials research. Proteins with PEG chain modifications and compounds encapsulated in PEG liposomes exhibit a longer half-life in vivo than their non-PEGylated counterparts, a phenomenon known as PEG shielding. Functionalised PEG lipids and phospholipids can be used for protein-PEG conjugation. Uses: Activated peg derivatives can be used to modify peptides, proteins, or in other bioconjugation applications. pegylated materials have found broad use in drug delivery systems, virology, and immunology, as the incorporation of peg improves pharmacological properties such as increased water solubility, enhanced resistance to degradation (protein hydrolysis), increased circulation half-life, and reduced antigenicity. in addition to pegylation, activated peg derivatives can also be used to form networks for tissue engineering or drug delivery applications, depending on the architecture and reactivity. Group: Poly(ethylene glycol) and poly(ethylene oxide). Alternative Names: 4arm-PEG-Succinimidyl Succinate. Molecular formula: average Mn 40000. | |
| 4arm-PEG5K 1arm-OH, 3arm-COOH | Polyethylene glycol (PEG) compounds contain a polyether unit, commonly expressed as R1-(O-CH2-CH2)n-O-R2. They are generally biocompatible, non-toxic and stable in both organic and aqueous solutions, and so are extensively used in biological applications, as well as nanotechnology and materials research. Proteins with PEG chain modifications and compounds encapsulated in PEG liposomes exhibit a longer half-life in vivo than their non-PEGylated counterparts, a phenomenon known as PEG shielding. Functionalised PEG lipids and phospholipids can be used for protein-PEG conjugation. Uses: Activated peg derivatives can be used to modify peptides, proteins, or in other bioconjugation applications. pegylated materials have found broad use in drug delivery systems, virology, and immunology, as the incorporation of peg improves pharmacological properties such as increased water solubility, enhanced resistance to degradation (protein hydrolysis), increased circulation half-life, and reduced antigenicity. in addition to pegylation, activated peg derivatives can also be used to form networks for tissue engineering or drug delivery applications, depending on the architecture and reactivity. Group: Poly(ethylene glycol) and poly(ethylene oxide). Molecular formula: average Mn 5000. | |
| 4arm-PEG5K 1arm-OH, 3arm-COOH | average Mn 5000. Group: Poly(ethylene glycol) and poly(ethylene oxide). | |
| 4arm-PEG5K 3arm-OH, 1arm-COOH | average Mn 5000. Group: Poly(ethylene glycol) and poly(ethylene oxide). | |
| 4arm-PEG5K 3arm-OH, 1arm-COOH | Polyethylene glycol (PEG) compounds contain a polyether unit, commonly expressed as R1-(O-CH2-CH2)n-O-R2. They are generally biocompatible, non-toxic and stable in both organic and aqueous solutions, and so are extensively used in biological applications, as well as nanotechnology and materials research. Proteins with PEG chain modifications and compounds encapsulated in PEG liposomes exhibit a longer half-life in vivo than their non-PEGylated counterparts, a phenomenon known as PEG shielding. Functionalised PEG lipids and phospholipids can be used for protein-PEG conjugation. Uses: Activated peg derivatives can be used to modify peptides, proteins, or in other bioconjugation applications. pegylated materials have found broad use in drug delivery systems, virology, and immunology, as the incorporation of peg improves pharmacological properties such as increased water solubility, enhanced resistance to degradation (protein hydrolysis), increased circulation half-life, and reduced antigenicity. in addition to pegylation, activated peg derivatives can also be used to form networks for tissue engineering or drug delivery applications, depending on the architecture and reactivity. Group: Poly(ethylene glycol) and poly(ethylene oxide). Molecular formula: average Mn 5000. | |
| 4arm-PEG5K-COOH | Polyethylene glycol (PEG) compounds contain a polyether unit, commonly expressed as R1-(O-CH2-CH2)n-O-R2. They are generally biocompatible, non-toxic and stable in both organic and aqueous solutions, and so are extensively used in biological applications, as well as nanotechnology and materials research. Proteins with PEG chain modifications and compounds encapsulated in PEG liposomes exhibit a longer half-life in vivo than their non-PEGylated counterparts, a phenomenon known as PEG shielding. Functionalised PEG lipids and phospholipids can be used for protein-PEG conjugation. Uses: Activated peg derivatives can be used to modify peptides, proteins, or in other bioconjugation applications. pegylated materials have found broad use in drug delivery systems, virology, and immunology, as the incorporation of peg improves pharmacological properties such as increased water solubility, enhanced resistance to degradation (protein hydrolysis), increased circulation half-life, and reduced antigenicity. in addition to pegylation, activated peg derivatives can also be used to form networks for tissue engineering or drug delivery applications, depending on the architecture and reactivity. Group: Poly(ethylene glycol) and poly(ethylene oxide). Alternative Names: 4arm-PEG-COOH, 4arm-PEG-Carboxyl. Molecular formula: average Mn 5000. | |
| 4arm-PEG5K-COOH | average Mn 5,000. Group: Poly(ethylene glycol) and poly(ethylene oxide). | |
| 4arm-PEG5K-NH2 | HCl Salt, average Mn 5,000. Group: Poly(ethylene glycol) and poly(ethylene oxide). | |
| 4arm-PEG5K-NH2 | Polyethylene glycol (PEG) compounds contain a polyether unit, commonly expressed as R1-(O-CH2-CH2)n-O-R2. They are generally biocompatible, non-toxic and stable in both organic and aqueous solutions, and so are extensively used in biological applications, as well as nanotechnology and materials research. Proteins with PEG chain modifications and compounds encapsulated in PEG liposomes exhibit a longer half-life in vivo than their non-PEGylated counterparts, a phenomenon known as PEG shielding. Functionalised PEG lipids and phospholipids can be used for protein-PEG conjugation. Uses: Activated peg derivatives can be used to modify peptides, proteins, or in other bioconjugation applications. pegylated materials have found broad use in drug delivery systems, virology, and immunology, as the incorporation of peg improves pharmacological properties such as increased water solubility, enhanced resistance to degradation (protein hydrolysis), increased circulation half-life, and reduced antigenicity. in addition to pegylation, activated peg derivatives can also be used to form networks for tissue engineering or drug delivery applications, depending on the architecture and reactivity. Group: Poly(ethylene glycol) and poly(ethylene oxide). Alternative Names: 4arm-PEG-NH2, 4arm-PEG-amine. Molecular formula: average Mn 5000. | |
| 4arm-PEG5K-SH | Polyethylene glycol (PEG) compounds contain a polyether unit, commonly expressed as R1-(O-CH2-CH2)n-O-R2. They are generally biocompatible, non-toxic and stable in both organic and aqueous solutions, and so are extensively used in biological applications, as well as nanotechnology and materials research. Proteins with PEG chain modifications and compounds encapsulated in PEG liposomes exhibit a longer half-life in vivo than their non-PEGylated counterparts, a phenomenon known as PEG shielding. Functionalised PEG lipids and phospholipids can be used for protein-PEG conjugation. Uses: Activated peg derivatives can be used to modify peptides, proteins, or in other bioconjugation applications. pegylated materials have found broad use in drug delivery systems, virology, and immunology, as the incorporation of peg improves pharmacological properties such as increased water solubility, enhanced resistance to degradation (protein hydrolysis), increased circulation half-life, and reduced antigenicity. in addition to pegylation, activated peg derivatives can also be used to form networks for tissue engineering or drug delivery applications, depending on the architecture and reactivity. Group: Poly(ethylene glycol) and poly(ethylene oxide). Alternative Names: 4arm-PEG-SH. Molecular formula: average Mn 5000. | |
| 4arm-PEG5K-SH | average Mn 5,000. Group: Poly(ethylene glycol) and poly(ethylene oxide). | |
| 4arm-PEG5K-Succinimidyl Carboxymethyl Ester | average Mn 5,000. Group: Poly(ethylene glycol) and poly(ethylene oxide). | |
| 4arm-PEG5K-Succinimidyl Carboxymethyl Ester | Polyethylene glycol (PEG) compounds contain a polyether unit, commonly expressed as R1-(O-CH2-CH2)n-O-R2. They are generally biocompatible, non-toxic and stable in both organic and aqueous solutions, and so are extensively used in biological applications, as well as nanotechnology and materials research. Proteins with PEG chain modifications and compounds encapsulated in PEG liposomes exhibit a longer half-life in vivo than their non-PEGylated counterparts, a phenomenon known as PEG shielding. Functionalised PEG lipids and phospholipids can be used for protein-PEG conjugation. Uses: Activated peg derivatives can be used to modify peptides, proteins, or in other bioconjugation applications. pegylated materials have found broad use in drug delivery systems, virology, and immunology, as the incorporation of peg improves pharmacological properties such as increased water solubility, enhanced resistance to degradation (protein hydrolysis), increased circulation half-life, and reduced antigenicity. in addition to pegylation, activated peg derivatives can also be used to form networks for tissue engineering or drug delivery applications, depending on the architecture and reactivity. Group: Poly(ethylene glycol) and poly(ethylene oxide). Alternative Names: 4arm-PEG-Succinimidyl Carboxymethyl Ester. Molecular formula: average Mn 5000. | |
| 4-Arm PEG-Biotin, MW 2k-20K | The 4-arm PEG derivative belongs to a branched PEG. It has larger molecular weight due to increased number of active terminal groups, therefore it can carry more drug molecules. Multi-arm PEG derivatives are commonly used in drug delivery systems. The molecular weight of the modified drug is increased that is not easily eliminated by metabolism in the body. In addition, the dispersity and solubility of the modified drug in the body will be improved. Multi-arm PEG derivatives can also modify the surface of biological materials or form new biomedical materials. Mole weight: Customizable. |  |
| 4arm-PEG GPC Standards | Polyethylene glycol (PEG) compounds contain a polyether unit, commonly expressed as R1-(O-CH2-CH2)n-O-R2. They are generally biocompatible, non-toxic and stable in both organic and aqueous solutions, and so are extensively used in biological applications, as well as nanotechnology and materials research. Proteins with PEG chain modifications and compounds encapsulated in PEG liposomes exhibit a longer half-life in vivo than their non-PEGylated counterparts, a phenomenon known as PEG shielding. Functionalised PEG lipids and phospholipids can be used for protein-PEG conjugation. Uses: Activated peg derivatives can be used to modify peptides, proteins, or in other bioconjugation applications. pegylated materials have found broad use in drug delivery systems, virology, and immunology, as the incorporation of peg improves pharmacological properties such as increased water solubility, enhanced resistance to degradation (protein hydrolysis), increased circulation half-life, and reduced antigenicity. in addition to pegylation, activated peg derivatives can also be used to form networks for tissue engineering or drug delivery applications, depending on the architecture and reactivity. Group: Poly(ethylene glycol) and poly(ethylene oxide). | |
| 4-arm Poly(ethylene glycol) norbornene terminated | Polyethylene glycol (PEG) compounds contain a polyether unit, commonly expressed as R1-(O-CH2-CH2)n-O-R2. They are generally biocompatible, non-toxic and stable in both organic and aqueous solutions, and so are extensively used in biological applications, as well as nanotechnology and materials research. Proteins with PEG chain modifications and compounds encapsulated in PEG liposomes exhibit a longer half-life in vivo than their non-PEGylated counterparts, a phenomenon known as PEG shielding. Functionalised PEG lipids and phospholipids can be used for protein-PEG conjugation. Uses: Activated peg derivatives can be used to modify peptides, proteins, or in other bioconjugation applications. pegylated materials have found broad use in drug delivery systems, virology, and immunology, as the incorporation of peg improves pharmacological properties such as increased water solubility, enhanced resistance to degradation (protein hydrolysis), increased circulation half-life, and reduced antigenicity. in addition to pegylation, activated peg derivatives can also be used to form networks for tissue engineering or drug delivery applications, depending on the architecture and reactivity. Group: Poly(ethylene glycol) and poly(ethylene oxide). Alternative Names: PEG-norbornene, PEG-nb. CAS No. 1191287-92-9. Pack Sizes: Packaging 1 g in glass bottle. Molecular formula: average Mn 10000. | |
| 4arm-Poly(lactide-co-glycolide) | 4arm-Poly(lactide-co-glycolide). Synonyms: 4 arm PLGA. Product ID: MSMN-066. Category: Raw Materials. |  |
| 4-Aza-3-chromanone | 4-Aza-3-chromanone. Group: Biochemicals. Alternative Names: 2H-1,4-Benzoxazine-3(4H)-one; 2H-Benzo[b][1,4]oxazin-3(4H)-one. Grades: Highly Purified. CAS No. 5466-88-6. Pack Sizes: 25g, 50g, 100g, 250g. Molecular Formula: C8H7NO2. US Biological Life Sciences. |  Worldwide |
| 4-Aza-3-chromanone 98+% (HPLC) | 4-Aza-3-chromanone 98+% (HPLC). Group: Biochemicals. Grades: Reagent Grade. Pack Sizes: 5g, 25g, 100g, 250g. US Biological Life Sciences. | Worldwide |
| 4-azabenzimidazole | 4-azabenzimidazole. Uses: Designed for use in research and industrial production. Product Category: Imidazoles. Appearance: Yellow to light brown powder. CAS No. 273-21-2. Molecular formula: C6H5N3. Mole weight: 119.12. Purity: 0.99. Density: 1.38 g/cm³. Product ID: ACM273212. Alfa Chemistry ISO 9001:2015 Certified. |  |
| 4-Aza-dl-leucine dihydrochloride | 4-Aza-dl-leucine dihydrochloride. Uses: Designed for use in research and industrial production. Appearance: White to off white powder. CAS No. 102029-69-6. Molecular formula: C5H12N2O2·2HCl. Mole weight: 205.08. Purity: 0.96. IUPACName: 2-amino-3-(dimethylamino)propanoicacid;dihydrochloride. Canonical SMILES: CN(C)CC(C(=O)O)N.Cl.Cl. Product ID: ACM102029696. Alfa Chemistry ISO 9001:2015 Certified. Categories: 34064-27-2. | |
| 4-Azaindole | 1g Pack Size. Group: Building Blocks, Indoles, Organics, Stains & Indicators. Formula: C7H6N2. CAS No. 272-49-1. Prepack ID 26737614-1g. Molecular Weight 118.14. See USA prepack pricing. |  |
| 4-Azaindole | 1H-Pyrrolo[3,2-b]pyridine is a biochemical reagent that can be used as a biological material or organic compound for life science related research. Uses: Scientific research. Group: Biochemical assay reagents. CAS No. 272-49-1. Pack Sizes: 5 g; 10 g. Product ID: HY-20362. |  |
| 4-Azaindole | 4-Azaindole. Group: Biochemicals. Grades: Highly Purified. CAS No. 272-49-1. Pack Sizes: 1g, 2g, 5g, 10g, 25g. Molecular Formula: C7H6N2. US Biological Life Sciences. | Worldwide |
| 4-Azaindole 98+% (HPLC) | 4-Azaindole 98+% (HPLC). Group: Biochemicals. Grades: Reagent Grade. Pack Sizes: 1g, 5g, 25g. US Biological Life Sciences. | Worldwide |
| 4-Azaphthalide | 4-Azaphthalide. CAS No: 5657-51-2 |  Sarchem Laboratories New Jersey NJ |
| 4'-Azetidinomethyl-2-thiomethylbenzophenone | 4'-Azetidinomethyl-2-thiomethylbenzophenone. Uses: Designed for use in research and industrial production. Additional or Alternative Names: 4'-AZETIDINOMETHYL-2-THIOMETHYLBENZOPHENONE. Product Category: Heterocyclic Organic Compound. CAS No. 898756-34-8. Molecular formula: C18H19NOS. Mole weight: 297.41. Purity: 0.96. IUPACName: [4-(azetidin-1-ylmethyl)phenyl]-(2-methylsulfanylphenyl)methanone. Canonical SMILES: CSC1=CC=CC=C1C(=O)C2=CC=C(C=C2)CN3CCC3. Density: 1.2g/cm³. Product ID: ACM898756348. Alfa Chemistry ISO 9001:2015 Certified. | |
| 4'-Azetidinomethyl-3,4-dichlorobenzophenone | 4'-Azetidinomethyl-3,4-dichlorobenzophenone. Uses: Designed for use in research and industrial production. Additional or Alternative Names: 4'-AZETIDINOMETHYL-3,4-DICHLOROBENZOPHENONE. Product Category: Heterocyclic Organic Compound. CAS No. 898757-00-1. Molecular formula: C17H15Cl2NO. Mole weight: 320.21. Purity: 0.96. IUPACName: [4-(azetidin-1-ylmethyl)phenyl]-(3,4-dichlorophenyl)methanone. Canonical SMILES: C1CN(C1)CC2=CC=C(C=C2)C(=O)C3=CC(=C(C=C3)Cl)Cl. Density: 1.321g/cm³. Product ID: ACM898757001. Alfa Chemistry ISO 9001:2015 Certified. | |
| 4'-Azetidinomethyl-3-trifluoromethylbenzophenone | 4'-Azetidinomethyl-3-trifluoromethylbenzophenone. Uses: Designed for use in research and industrial production. Additional or Alternative Names: 4'-AZETIDINOMETHYL-3-TRIFLUOROMETHYLBENZOPHENONE. Product Category: Heterocyclic Organic Compound. CAS No. 898756-84-8. Molecular formula: C18H16F3NO. Mole weight: 319.32. Purity: 0.96. IUPACName: [4-(azetidin-1-ylmethyl)phenyl]-[3-(trifluoromethyl)phenyl]methanone. Canonical SMILES: C1CN(C1)CC2=CC=C(C=C2)C(=O)C3=CC(=CC=C3)C(F)(F)F. Density: 1.267g/cm³. Product ID: ACM898756848. Alfa Chemistry ISO 9001:2015 Certified. | |
| 4'-Azetidinomethyl-4-bromo-3-fluorobenzophenone | 4'-Azetidinomethyl-4-bromo-3-fluorobenzophenone. Uses: Designed for use in research and industrial production. Additional or Alternative Names: 4'-AZETIDINOMETHYL-4-BROMO-3-FLUOROBENZOPHENONE. Product Category: Heterocyclic Organic Compound. CAS No. 898756-73-5. Molecular formula: C17H15BrFNO. Mole weight: 348.21. Purity: 0.96. IUPACName: [4-(azetidin-1-ylmethyl)phenyl]-(4-bromo-3-fluorophenyl)methanone. Canonical SMILES: C1CN(C1)CC2=CC=C(C=C2)C(=O)C3=CC(=C(C=C3)Br)F. Density: 1.457g/cm³. Product ID: ACM898756735. Alfa Chemistry ISO 9001:2015 Certified. | |
| 4'-Azetidinomethyl-4-chloro-3-fluorobenzophenone | 4'-Azetidinomethyl-4-chloro-3-fluorobenzophenone. Uses: Designed for use in research and industrial production. Additional or Alternative Names: 4'-AZETIDINOMETHYL-4-CHLORO-3-FLUOROBENZOPHENONE. Product Category: Heterocyclic Organic Compound. CAS No. 898756-75-7. Molecular formula: C17H15ClFNO. Mole weight: 303.76. Purity: 0.96. IUPACName: [4-(azetidin-1-ylmethyl)phenyl]-(4-chloro-3-fluorophenyl)methanone. Canonical SMILES: C1CN(C1)CC2=CC=C(C=C2)C(=O)C3=CC(=C(C=C3)Cl)F. Density: 1.294g/cm³. Product ID: ACM898756757. Alfa Chemistry ISO 9001:2015 Certified. | |
| 4-Azetidinomethyl-4'-thiomethylbenzophenone | 4-Azetidinomethyl-4'-thiomethylbenzophenone. Uses: Designed for use in research and industrial production. Additional or Alternative Names: 4-AZETIDINOMETHYL-4'-THIOMETHYLBENZOPHENONE. Product Category: Heterocyclic Organic Compound. CAS No. 898756-37-1. Molecular formula: C18H19NOS. Mole weight: 297.41. Purity: 0.96. IUPACName: [4-(azetidin-1-ylmethyl)phenyl]-(4-methylsulfanylphenyl)methanone. Canonical SMILES: CSC1=CC=C(C=C1)C(=O)C2=CC=C(C=C2)CN3CCC3. Density: 1.2g/cm³. Product ID: ACM898756371. Alfa Chemistry ISO 9001:2015 Certified. | |
| 4-(Azetidinomethyl)benzophenone | 4-(Azetidinomethyl)benzophenone. Uses: Designed for use in research and industrial production. Additional or Alternative Names: 4-(AZETIDINOMETHYL) BENZOPHENONE. Product Category: Heterocyclic Organic Compound. CAS No. 898777-22-5. Molecular formula: C17H17NO. Mole weight: 251.32. Purity: 0.96. IUPACName: [4-(azetidin-1-ylmethyl)phenyl]-phenylmethanone. Canonical SMILES: C1CN(C1)CC2=CC=C(C=C2)C(=O)C3=CC=CC=C3. Density: 1.15g/cm³. Product ID: ACM898777225. Alfa Chemistry ISO 9001:2015 Certified. | |
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