Open Access

First milestone of this Ph.D. thesis was the successful extension of conventional NTA/His-tag technique to self-assembling, multivalent chelator thiols for high-affinity recognition as well as stable and uniform immobilization of His-tagged proteins on chip surfaces. Bis-NTA was linked via an oligoethylene glycol to alkyl thiols by an efficient modular synthesis strategy yielding a novel, multivalent compound for formation of mixed SAMs with anti-adsorptive matrix thiols on gold. Multivalent chelator chips allow a specific, high-affinity, reversible, long-term immobilization of His-tagged proteins. In AFM studies reversibility of the specific protein immobilization process was visualized at single molecule level. The entire control over the orientation of the immobilized protein promotes this chip surface to an optimal platform for studies focusing on research targets at single molecule level and nanobiotechnology. Based on the constructed protein chip platform above and a novel AFM mode (contact oscillation mode, COM) – developed during the current Ph.D. work – protein nanolithography under physiological conditions enabling fabrication of active biomolecular patterns in countless variety has been established. Reversible COM-mediated nanostructuring is exceptionally suitable for multiplexed patterning of protein assemblies in situ. The first selfassembled protein layer acts as a biocompatible and ductile patterning material. Immobilized proteins can be replaced by the AFM tip applying COM, and the generated structures can be erased and refilled with different proteins, which are immobilized in a uniform and functional manner. Multi-protein arrays can be systematically fabricated by iterative erase-and-write processes, and employed for protein-protein interaction analysis. Fabrication of two-dimensionally arranged nanocatalytic centres with biological activity will establish a versatile tool for nanobiotechnology. As an alternative chip fabrication approach, the combined application of methodologies from surface chemistry, semiconductor technology, and chemical biology demonstrated successfully how pre-patterned templates for micro- and nanoarrays for protein chips are fabricated. The surface physical, as well the biophysical experiments, proved the functionality of this technology. The promises of such process technology are fast and economic fabrication of ready-to-use nanostructured biochips at industrial scale. Membrane proteins are complicated in handling and hence require sophisticated solutions for chip technological application. A silicon-on-insulator (SOI) chip substrate with microcavities and nanopores was employed for first technological investigation to construct a protein chip suitable for membrane proteins. The formation of an artificial lipid bilayer using vesicle fusion on oxidized SOI cavity substrates was verified by CLSM. Future AFM experiments will give further insights into the chip architecture and topography. This will provide last evidence of the sealing of the cavity by the lipid bilayer. Transmembrane proteins will be employed for reconstitution experiments on this membrane protein chip platform. Highly integrated microdevices will find application in basic biomedical and pharmaceutical research, whereas robust and portable point-of-care devices will be used in clinical settings.