Abstract
Immobilization of biologically active proteins and enzymes on surfaces is very important for the production of biofunctionalized surfaces for applications in medicine such as biosensors and in the diagnostics field. There are various approaches to immobilize and control the release of peptides/proteins from different surfaces. The identification of successful techniques to functionalize a particular material is a challenge. On the other hand, biomaterials are at the moment of great benefit for medicinal purposes and a lot of knowledge from different fields is required in order to design biomimetic scaffolds or biomimetic materials. The used methodologies are different for different materials and are mainly based on the special chemistry of the surfaces. Peptides with distinct properties are desired instead of entire proteins. However, in some cases, proteins cannot be replaced by peptide segments and therefore biochemical knowledge, such as in protein and/or genetic engineering is required.
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Katranidis, A., Choli-Papadopoulou, T. (2012). Biofunctionalization of Surfaces with Peptides, Proteins, or Subcellular Organelles: Single-Molecule Studies and Nanomedical Approach. In: Logothetidis, S. (eds) Nanomedicine and Nanobiotechnology. NanoScience and Technology. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-24181-9_3
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