Selected publications

Dau, M., Ganz, C., Zaage, F., Frerich, B., and Gerber, T. (2017). Hydrogel-embedded nanocrystalline hydroxyapatite granules (elastic blocks) based on a cross-linked polyvinylpyrrolidone as bone grafting substitute in a rat tibia model. Int J Nanomedicine 12, 7393–7404.
Öri, F., Dietrich, R., Ganz, C., Dau, M., Wolter, D., Kasten, A., Gerber, T., and Frerich, B. (2017). Silicon-dioxide−polyvinylpyrrolidone as a wound dressing for skin defects in a murine model. Journal of Cranio-Maxillofacial Surgery 45, 99–107.
Weigand, A., Beier, J.P., Hess, A., Gerber, T., Arkudas, A., Horch, R.E., and Boos, A.M. (2015). Acceleration of Vascularized Bone Tissue-Engineered Constructs in a Large Animal Model Combining Intrinsic and Extrinsic Vascularization. Tissue Engineering Part A 21, 1680–1694.
Adam, M., Ganz, C., Xu, W., Sarajian, H.-R., Götz, W., and Gerber, T. (2014). In vivo and in vitro investigations of a nanostructured coating material – a preclinical study. Int J Nanomedicine 9, 975–984.
Boos, A.M., Weigand, A., Deschler, G., Gerber, T., Arkudas, A., Kneser, U., Horch, R.E., and Beier, J.P. (2014). Autologous serum improves bone formation in a primary stable silica-embedded nanohydroxyapatite bone substitute in combination with mesenchymal stem cells and rhBMP-2 in the sheep model. Int J Nanomedicine 9, 5317–5339.
Ganz, C., and Gerber, T. (2014). Bone Substitutes as a Drug Delivery of Antibiotics. Key Engineering Materials 631, 321–325.
Gerber, T., Ganz, C., Götz, W., Helms, K., Harms, C., and Mittlmeier, T. (2014). Nanostructured Bone Grafting Substitutes Versus Autologous Cancellous Bone – An Animal Experiment in Sheep. Key Engineering Materials 631, 202–206.
Wolf, M., Wurm, A., Heinemann, F., Gerber, T., Reichert, C., Jäger, A., and Götz, W. (2014). The effect of patient age on bone formation using a fully synthetic nanocrystalline bone augmentation material in maxillary sinus grafting. International Journal of Oral & Maxillofacial Implants 29.
Zaage, F., Dau, M., Ganz, C., Frerich, B., and Gerber, T. (2014). Elastic Blocks: Hydrogel-Embedded Granules as Bone Grafting Substitutes. Key Engineering Materials 631, 414–419.
Gerber, T., Ganz, C., Xu, W., Maier, F., Frerich, B., and Lenz, S. (2012). Bone Grafting Putty – Animal Experiments and Clinical Applications. Key Engineering Materials 529–530, 285–290.
Harms, C., Helms, K., Taschner, T., Stratos, I., Ignatius, A., Gerber, T., Lenz, S., Rammelt, S., Vollmar, B., and Mittlmeier, T. (2012). Osteogenic capacity of nanocrystalline bone cement in a weight-bearing defect at the ovine tibial metaphysis. Int J Nanomedicine 7, 2883–2889.
Keuer, H., Ganz, C., Xu, W., Schubert, A., Frerich, B., and Gerber, T. (2012). Osteoinductive Coating on PEEK Surfaces by Using Nanocrystalline Biomaterial and In Vivo Test. Key Engineering Materials 529–530, 345–349.
Adam, M., Ganz, C., Xu, W., Frerich, B., and Gerber, T. (2012). Controlled Self-Coating of Implant Surfaces with Autologous Molecules. Key Engineering Materials 529–530, 207–212.
Ganz, C., Xu, W., Holzhüter, G., Götz, W., Vollmar, B., and Gerber, T. (2011). Comparison of Bone Substitutes in a Tibia Defect Model in Wistar-Rats. Key Engineering Materials 493–494, 732–738.
Xu, W., Ganz, C., Weber, U., Adam, M., Holzhüter, G., Wolter, D., Frerich, B., Vollmar, B., and Gerber, T. (2011). Evaluation of injectable silica-embedded nanohydroxyapatite bone substitute in a rat tibia defect model. Int J Nanomedicine 6, 1543–1552.
Abshagen, K., Schrodi, I., Gerber, T., and Vollmar, B. (2009). In vivo analysis of biocompatibility and vascularization of the synthetic bone grafting substitute NanoBone®. Journal of Biomedical Materials Research Part A 91A, 557–566.
Xu, W., Holzhüter, G., Sorg, H., Wolter, D., Lenz, S., Gerber, T., and Vollmar, B. (2009). Early matrix change of a nanostructured bone grafting substitute in the rat. Journal of Biomedical Materials Research Part B: Applied Biomaterials 91B, 692–699.
Harms, C., Helms, K., Taschner, T., Stratos, I., Gerber, T., Lenz, S., Vollmar, B., and Mittlmeier, T. (2008). Histomorphometrische und Mikro-CT-Analyse der Knocheneubildung in der Metaphyse des Schafes nach Einsatz eines nanokristallinen Knochenaufbaumaterials NanoBone®. In Chirurgisches Forum 2008, M.D. Menger, R. Arbogast, H.K. Schackert, and H. Bauer, eds. (Springer Berlin Heidelberg), pp. 253–255.
Gerber, T., Holzhüter, G., Knoblich, B., Dörfling, P., Bienengräber, V., and Henkel, K.-O. (2000). Development of Bioactive Sol-Gel Material Template for In Vitro and In Vivo Synthesis of Bone Material. Journal of Sol-Gel Science and Technology 19, 441–445.