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8arm PEG Amine (hexaglycerol), HCl Salt

产品代号:

8ARM-PEG-NH2HCl

产品纯度:

≥ 95%

包装规格:

1g, 10g, 100g等(特殊包装需收取分装费用)

分子量:

10000Da, 20000 Da,40000 Da等

产品咨询:

科研客户小批量一键采购地址(小于5克)

  • 产品描述
  • 参考文献
  •   键凯科技提供高品质8ARM-NH2HCl-20K八臂聚乙二醇胺盐酸盐产品,产品取代率≥ 95%

      键凯科技的8臂胺基产品可交联制备PEG水凝胶产品。PEG水凝胶在医疗器械和再生医学方面尤其是在药物的缓释控释,2维和3维细胞培养以及伤口的缝合和愈合方面有非常广泛的应用。键凯的8臂PEG原料来通过三聚季戊四醇和乙氧基聚合而成,每个PEG链的乙氧基单元数目不是完全相同的。键凯的多臂PEG产品的分子量指的是各臂分子量的总和。

      键凯科技提供8ARM-NH2HCl分子量10000Da, 20000 Da,40000 Da产品 1克和10克包装。

      键凯科技提供分装服务,需要收取分装费用,如果您需要分装为其他规格请与我们联系。

      键凯科技同时提供其他分子量的8ARM-NH2HCl-20K产品,如你需要请与我司sales@jenkem.com联系。

      键凯科技提供大批量生产产品及GMP级别产品,如需报价请与我们联系。

     

  • References:

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    8. Ovadia, E.M., et al., Designing well-defined photopolymerized synthetic matrices for three-dimensional culture and differentiation of induced pluripotent stem cells, Biomaterials science, 2018.
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    13. Aziz, A.H., et al., Mechanical characterization of sequentially layered photo-clickable thiol-ene hydrogels, Journal of the Mechanical Behavior of Biomedical Materials, 2017, V. 65, p. 454-465.
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    17. Chu, S., et al., Understanding the Spatiotemporal Degradation Behavior of Aggrecanase-Sensitive Poly (ethylene glycol) Hydrogels for use in Cartilage Tissue Engineering, Tissue Engineering, 2017.
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    20. Ma, Z., et al., Folate‐Conjugated Polylactic Acid–Silica Hybrid Nanoparticles as Degradable Carriers for Targeted Drug Delivery, On‐Demand Release and Simultaneous Self‐Clearance, ChemPlusChem, 2016.
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    28. Amoozgar, Z., et al., Dual-layer surface coating of PLGA-based nanoparticles provides slow-release drug delivery to achieve metronomic therapy in a paclitaxel-resistant murine ovarian cancer model, Biomacromolecules, 2014, 15(11), 4187-94.
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    31. Cui, J., et al., Super-Soft Hydrogel Particles with Tunable Elasticity in a Microfluidic Blood Capillary Model, Advanced Materials, 2014, 26(43), 7295-7299.
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    39. Zhou, J., et al., Real-time detection of implant-associated neutrophil responses using a formyl peptide receptor-targeting NIR nanoprobe, International Journal of Nanomedicine, 2012, 7 2057–2068.
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    41. Tan, H., et al., Novel Multi-arm PEG-based Hydrogels for Tissue Engineering, Journal of biomedical materials research Part A., 2010, 92(3), 979-987.
    42. Schroeder, M. E., et al., Collagen networks within 3D PEG hydrogels support valvular interstitial cell matrix mineralization, Acta Biomaterialia, 2021, V. 119, P. 197-210.
    43. Schoonraad, SA, et al., The Effects of Stably Tethered BMP-2 on MC3T3-E1 Preosteoblasts Encapsulated in a PEG Hydrogel. Biomacromolecules. 2021, 22(3):1065-79.
    44. Caldwell, AS, et al, Mesenchymal stem cell‐inspired microgel scaffolds to control macrophage polarization. Bioengineering & Translational Medicine. 2021, 6(2):e10217.
    45. Song, J, et al, Influence of Poly (ethylene glycol) Molecular Architecture on Particle Assembly and Ex Vivo Particle–Immune Cell Interactions in Human Blood. ACS nano. 2021.
    46. Batan, D, et al., Hydrogel cultures reveal Transient Receptor Potential Vanilloid 4 regulation of myofibroblast activation and proliferation in valvular interstitial cells. The FASEB Journal. 2022.
    47. Yu, Y, et al., A 3D printed mimetic composite for the treatment of growth plate injuries in a rabbit model. NPJ Regenerative Medicine. 2022;7(1):1-4.
    48. Schroeder, M. E., et al., Osteopontin activity modulates sex‐specific calcification in engineered valve tissue mimics, Bioengineering & translational medicine 2023, 8.1, e10358.
    49. Bhatta, R., et al., T cell-responsive macroporous hydrogels for in situ T cell expansion and enhanced antitumor efficacy, Biomaterials, V. 293, 2023.

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