Publications – (2014)

  1. The effect of Matrix stiffness of injectable hydrogels on the preservation of cardiac function after a heart attack
    Plotkin, M., Vaibavi, S.R., Rufaihah, A.J., Venkateswaran, N., Wang, J., Shachaf, Y., Kofidis, T., Seliktar, D.
    Biomaterials, 35(5):1429-38, 2014.
  2. Influence of soluble PEG-OH incorporation in a 3-D cell-laden PEG-fibrinogen (PF) hydrogel on smooth muscle cell morphology and growth
    Lee, B.H., Tin, SP., Chaw, SY., Cao, Y., Xia, Y., Steele, TW., Seliktar, D., Bianco-Peled, H., Venkatraman, S.S.
    Journal of Biomaterials Science, Polymer Edition, 25(4):394-409, 2014.
  3. A novel method for hydrogel nanostructuring
    Yom-Tov, O., Frisman, I., Seliktar, D., Bianco-Peled, H.
    European Polymer Journal, 52:137-45, 2014.
  4. PlGF–MMP9-engineered cardiomyocyte-derived iPS cells supported by PEG–fibrinogen hydrogel possess an enhanced capacity to repair the damaged myocardium
    Bearzi, C., Gargioli, C., Baci, D., Fortunato, O., Shapira-Schweitzer, K., Kossover, O., Latronico, M.L., Seliktar, D., Condorelli, G., Rizzi, R.
    Cell Death and Disease, 5:e1053, 2014.
  5. Cell Morphology in Injectable Nanostructured Biosynthetic Hydrogels
    Yom-Tov, O., Seliktar, D., Bianco-Peled, H.
    Journal of Biomedical Materials Research A, 102(12):4371-9, 2014.
  6. Reversible Ag+ Crosslinked DNA Hydrogels
    Guo, W.W., Qi, X.J., Orbach, R., Lu, C.H., Freage, L., Mironi-Harpaz, I., Seliktar, , Yang, H.H., Willner, I.
    Chemical Communications, 50(31):4065-8, 2014.
  7. 3D Hydrogel Environment Rejuvenates Aged Pericytes for Skeletal Muscle Tissue Engineering
    Fuoco, C., Sangalli, E., Vono, R., Testa, S., Sacchetti, B., Latronico, M.V.G., Bernardini, S., Madeddu, P., Cesareni, G., Seliktar, D., Rizzi, R., Bearzi, C., Cannata, S.M., Spinetti, G., and Gargioli, C.
    Frontiers in Physiology, 5:203, 2014.
  8. Bioinspired Functional Nanostructures Based on DOPA-DOPA Peptide Motif Fichman, G., Adler-Abramovich, L., Manohar, S., Mironi-Harpaz, I., Guterman, T., Seliktar, D., Messersmith, P.B., Gazit, E.
    ACS Nano, 8(7):7220-8, 2014.
  9. A Novel Design of Injectable Porous Hydrogels with in situ Pore Formation Yom-Tov, O., Yosef, L., Seliktar, D., Bianco-Peled, H.
    Acta Biomaterialia, 10(10):4236-46, 2014.
  10. Cellularized Biosynthetic Microhydrogel Polymers for Intravascular Liver Tissue Regeneration Therapy
    Saadi, T., Nayshool, N., Carmel, J., Arish, A., Bramnik, Z., Mironi-Harpaz, I., Seliktar, D., Baruch, Y.
    Tissue Engineering A, 20(21-22):2850-9, 2014.
  11. Fibrin-based Hydrogel Scaffold for Controlling Cell-Matrix Interaction in Vascular Tissue Engineering
    Mironi-Harpaz, I., Zigerson, S., Seliktar, D.
    Advanced Biomaterials and Devices in Medicine, 1(1): 28-37, 2014.
  12. Fabrication of PEGylated Fibrinogen – A Versatile Injectable Hydrogel Biomaterial in Cardiac Tissue Engineering: Methods and Protocols
    Miron-Harpaz, I., Berdichevski, A., Seliktar, D.
    (eds M. Radisic and L. Black), Springer, vol. 1181, PP 61-68, 2014.