The success of high-speed atomic force microscopy in imaging molecular motors 1 , enzymes 2 and microbes 3 in liquid environments suggests that the technique could be of significant value in a variety of areas of nanotechnology. However, the majority of atomic force microscopy experiments are performed in air, and the tapping-mode detection speed of current highspeed cantilevers is an order of magnitude lower in air than in liquids. Traditional approaches to increasing the imaging rate of atomic force microscopy have involved reducing the size of the cantilever 4,5 , but further reductions in size will require a fundamental change in the detection method of the microscope [6][7][8] . Here, we show that high-speed imaging in air can instead be achieved by changing the cantilever material. We use cantilevers fabricated from polymers, which can mimic the high damping environment of liquids. With this approach, SU-8 polymer cantilevers are developed that have an imaging-in-air detection bandwidth that is 19 times faster than those of conventional cantilevers of similar size, resonance frequency and spring constant.A primary research goal in atomic force microscopy (AFM) is to increase the imaging speed, improve its ease of use and expand its potential range of applications 9 . In the most widely used AFM mode (a.c. mode or tapping mode) the detection speed (mechanical bandwidth, BW) of the AFM cantilever fundamentally limits the imaging speed. The bandwidth is a measure of the maximum rate of topography change the cantilever can accurately detect. It is related to the cantilever resonance as BW ∝ f 0 /Q, where the cantilever resonance frequency f 0 is primarily determined by the cantilever mass and elastic modulus, and the quality factor Q is determined by the cantilever damping 10 . When the oscillating cantilever experiences a change in boundary condition (that is, topography), it requires several cycles to reach a new steady-state amplitude (Fig. 1a). A cantilever with higher resonance frequency runs through the required number of cycles more quickly, thereby enabling faster imaging (Fig. 1b). The number of required oscillatory cycles is determined by the damping of the cantilever, characterized by Q. A cantilever with low resonance frequency and low Q can therefore be equally as fast as a cantilever with high resonance frequency and high Q (compare Fig. 1b and c). From a detection bandwidth perspective, the ideal combination is a high resonance frequency and low quality factor (Fig. 1d).The development of current high-speed AFM (HS-AFM) technology was enabled by the miniaturization of silicon and silicon nitride (SiN) cantilevers to x-y dimensions below 10 µm (the approach taken in Fig. 1b), resulting in cantilevers with megahertz resonance frequencies 4,5 . Modelling and an improved understanding of cantilever behaviour in fluids has greatly benefited this geometric optimization. For nearly all cantilevers, viscous damping in the surrounding medium determines Q (ref. 11). In liquid, viscous damping yields Q ≈ 2...
Ceramics are known to be chemically stable, and the possibility to electrically dope polymer-derived ceramics makes it a material of interest for implantable electrode applications. We investigated cytotoxic characteristics of four polymer-derived ceramic candidates with either electrically conductive or insulating properties. Cytotoxicity was assessed by culturing C2C12 myoblast cells under two conditions: by exposing them to material extracts and by putting them directly in contact with material samples. Cell spreading was optically evaluated by comparing microscope observations immediately after the materials insertion and after 24 h culturing. Cell viability (MTT) and mortality (LDH) were quantified after 24-h incubation in contact with the materials. Comparison was made with biocompatible positive references (alumina, platinum, biocompatible stainless steel 1.4435), negative references (latex, stainless steel 1.4301) and controls (no material present in the culture wells). We found that the cytotoxic properties of tested ceramics are comparable to established reference materials. These ceramics, which are reported to be very stable, can be microstructured and electrically doped to a wide range of conductivity and are thus excellent candidates for implantable electrode applications including pacemakers.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.