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8arm PEG Norbornene (tripentaerythritol)

产品代号:

8ARM(TP)-PEG-NB

产品纯度:

≥ 90%

包装规格:

1g, 10g, 100g等(特殊包装需收取分装用度)

分子量:

20000 Da

产品咨询:

科研客户小批量一键采购地点(小于5克)

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  • 产品描述
  • 参考文献
  •   意大利贵宾会官网科技提供高品质八臂聚乙二醇降龙脑烯(三季戊四醇核))产品,产品取代率≥90% 。

      意大利贵宾会官网科技的盐酸盐8臂PEG降龙脑烯(三季戊四醇)衍生物可以交联成可降解的PEG水凝胶 。以三聚季戊四醇为核聚合而成的8ARM(TP)-PEG原料比以六聚甘油为核聚合而成的8ARM-PEG具有疏散度低,分子量更精确的优势 。PEG水凝胶在医疗设备及再生医学中具有多种应用,尤其适用于药物缓释、2D与3D细胞培养及伤口的密封与愈合等领域 。

    产品编码

    产品代号

    A10046

    8ARM(TP)-NB-10K

    A10037

    8ARM(TP)-NB-20K

      意大利贵宾会官网科技提供8ARM(TP)-NB-20K产品 1克和10克包装 。

      意大利贵宾会官网科技提供分装效劳,需要收取分装用度,如果您需要分装为其他规格请与我们联系 。

      意大利贵宾会官网科技同时提供其他分子量的8ARM(TP)-NB产品,如你需要请与我司sales@jenkem.com联系 。

      意大利贵宾会官网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:

      1. Dietrich, M., et al., Guiding 3D cell migration in deformed synthetic hydrogel microstructures, Soft matter, 2018, 14(15), pp.2816-2826.

      2. Shukla, V., et al., Cellular Mechanics of Primary Human Cervical Fibroblasts: Influence of Progesterone and a Pro-inflammatory Cytokine, Annals of biomedical engineering, 2018, 46(1), pp.197-207.

      3. Dorsey, T.B., et al., Evaluation of photochemistry reaction kinetics to pattern bioactive proteins on hydrogels for biological applications, Bioactive Materials, 2017.

      4. Zhang, J., et al., A Genome-wide Analysis of Human Pluripotent Stem Cell-Derived Endothelial Cells in 2D or 3D Culture, Stem Cell Reports, 2017, 8:4, p. 907-918.

      5. Holmes, R., et al., Thiol-ene photo-click collagen-PEG hydrogels: impact of water-soluble photoinitiators on cell viability, gelation kinetics and rheological properties, Polymers, 2017, 9(6):226.

      6. Valdez, J., et al., On-demand dissolution of modular, synthetic extracellular matrix reveals local epithelial-stromal communication networks, Biomaterials, 2017, v. 130, p. 90-103.

      7. Regier, M.C., et al., The Influence of Biomaterials on Cytokine Production in 3D Cultures. Biomacromolecules. 2017, 18(3):709-18.

      8. Zanotelli, M.R., et al., Stable engineered vascular networks from human induced pluripotent stem cell-derived endothelial cells cultured in synthetic hydrogels, Acta biomaterialia, 2016.

      9. Darling, N.J., et al., Thiol-Maleimide Reaction Speed Effects on Hydrogel Homogeneity, Biomaterials, 2015.

      10. Le, N.N.T., et al., Hydrogel arrays formed via differential wettability patterning enable combinatorial screening of stem cell behavior, Acta Biomaterialia, 2015.

      11. Pellett, S., et al., Human Induced Pluripotent Stem Cell Derived Neuronal Cells Cultured on Chemically-Defined Hydrogels for Sensitive In Vitro Detection of Botulinum Neurotoxin, Scientific Reports, 2015, 5:14566.

           12. Luo, Y., et al., Light-induced dynamic RGD pattern for sequential modulation of macrophage phenotypes, Bioactive Materials, 2021, V. 6(11), P. 4065-4072.

      13.Sofman, M., et al., A modular polymer microbead angiogenesis scaffold to characterize the effects of adhesion ligand density on angiogenic sprouting, Biomaterials, 2021, 264, 120231

           14.Wilson, RL, et al, Protein-functionalized poly (ethylene glycol) hydrogels as scaffolds for monolayer organoid culture. Tissue Engineering Part C: Methods. 2021, 27(1):12-23.

           15.Khang, A, et al., On the Three-Dimensional Correlation Between Myofibroblast Shape and Contraction. Journal of Biomechanical Engineering. 2021, 143(9):094503.

           16.Grewal, MG, et al., User-defined, temporal presentation of bioactive molecules on hydrogel substrates using supramolecular coiled coil complexes. Biomaterials Science. 2021.

           17.Grigoryan, B, et al., Development, characterization, and applications of multi-material stereolithography bioprinting. Scientific reports. 2021, 11(1):1-3.

           18.Anandakrishnan, N, et al., Fast Stereolithography Printing of Large‐Scale Biocompatible Hydrogel Models. Advanced Healthcare Materials. 2021, 10(10):2002103.

           19.Ortiz-Cárdenas, J.E., et al., Towards spatially-organized organs-on-chip: Photopatterning cell-laden thiol-ene and methacryloyl hydrogels in a microfluidic device. Organs-on-a-Chip, 2022, 100018.

           20.Khang, A., et al., Three-dimensional analysis of hydrogel-imbedded aortic valve interstitial cell shape and its relation to contractile behavior. Acta Biomaterialia, 2022.

           21.Kim MH, et al., Poly (ethylene glycol)–Norbornene as a Photoclick Bioink for Digital Light Processing 3D Bioprinting. ACS Applied Materials & Interfaces. 2023.

           22.Mulero-Russe, A., et al., Synthetic Hydrogel Substrate for Human Induced Pluripotent Stem Cell Definitive Endoderm Differentiation, Biomaterials, 2024.

           23.Sohrabi, A., et al., Protocol for in vitro evaluation of effects of stiffness on patient-derived glioblastoma, STAR Protocols, 5(3), 2024.

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