Diamond exhibits several special properties, for example good biocompatibility and a large electrochemical potential window, that make it particularly suitable for biofunctionalization and biosensing. Here we show that proteins can be attached covalently to nanocrystalline diamond thin films. Moreover, we show that, although the biomolecules are immobilized at the surface, they are still fully functional and active. Hydrogen-terminated nanocrystalline diamond films were modified by using a photochemical process to generate a surface layer of amino groups, to which proteins were covalently attached. We used green fluorescent protein to reveal the successful coupling directly. After functionalization of nanocrystalline diamond electrodes with the enzyme catalase, a direct electron transfer between the enzyme's redox centre and the diamond electrode was detected. Moreover, the modified electrode was found to be sensitive to hydrogen peroxide. Because of its dual role as a substrate for biofunctionalization and as an electrode, nanocrystalline diamond is a very promising candidate for future biosensor applications.
High-pressure
high-temperature (HPHT) nanodiamonds originate from grinding of diamond
microcrystals obtained by HPHT synthesis. Here we report on a simple
two-step approach to obtain as small as 1.1 nm HPHT nanodiamonds of
excellent purity and crystallinity, which are among the smallest artificially
prepared nanodiamonds ever shown and characterized. Moreover we provide
experimental evidence of diamond stability down to 1 nm. Controlled
annealing at 450 °C in air leads to efficient purification from
the nondiamond carbon (shells and dots), as evidenced by X-ray photoelectron
spectroscopy, Raman spectroscopy, photoluminescence spectroscopy,
and scanning transmission electron microscopy. Annealing at 500 °C
promotes, besides of purification, also size reduction of nanodiamonds
down to ∼1 nm. Comparably short (1 h) centrifugation of the
nanodiamonds aqueous colloidal solution ensures separation of the
sub-10 nm fraction. Calculations show that an asymmetry of Raman diamond
peak of sub-10 nm HPHT nanodiamonds can be well explained by modified
phonon confinement model when the actual particle size distribution
is taken into account. In contrast, larger Raman peak asymmetry commonly
observed in Raman spectra of detonation nanodiamonds is mainly attributed
to defects rather than to the phonon confinement. Thus, the obtained
characteristics reflect high material quality including nanoscale
effects in sub-10 nm HPHT nanodiamonds prepared by the presented method.
The optical properties of nanocrystalline diamond films grown from a hydrogen-rich CH4∕H2 gas phase by hot filament chemical vapor deposition, as well as from an argon-rich Ar∕CH4 gas phase by microwave plasma enhanced chemical vapor deposition, are reported. The influence of nitrogen incorporation on the optical absorption is investigated. The diamond films are characterized by photothermal deflection spectroscopy and temperature dependent spectrally resolved photoconductivity. An onset of absorption at about 0.8eV in undoped films is attributed to transitions from π to π states introduced into the band gap by the high amount of sp2 bonded carbon at the grain boundaries. Incorporation of nitrogen leads to a strong absorption in the whole energy spectrum, as a result of the increasing number of sp2 carbon atoms. The effect of surface states has been observed in the high energy region of the spectrum. Transitions to the conduction band tail and photothermal ionization processes account for the observed onset at 4.4eV. Photocurrent quenching at about 3.3eV is observed in the case of samples grown from a hydrogen-rich CH4∕H2 gas phase.
Microscopic chemical patterning of diamond surfaces by hydrogen and oxygen surface atoms is used for self-assembly of human osteoblastic cells into micro-arrays. The cell adhesion and assembly is further controlled by concentration of cells (2,500-10,000 cells/cm2) and fetal bovine serum (0-15%). The cells are characterized by fluorescence microscopy of actin fibers and nuclei. The serum protein adsorption is studied by atomic force microscopy (AFM). The cells are arranged selectively on O-terminated patterns into 30-200 μm wide arrays. Higher cell concentrations allow colonization of unfavorable H-terminated regions due to mutual cell communication. There is no cell selectivity without the proteins in the medium. Based on the AFM, the proteins are present on both H- and O-terminated surfaces. Pronounced differences in their thickness, surface roughness, morphology, and phase images indicate different conformation of the proteins and explain the cell selectivity.
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