Combined Ion Conductance and Atomic Force Microscope for Fast Simultaneous Topographical and Surface Charge Imaging.

We report here an advanced approach for simultaneous and independent submicroscale imaging of local surface charge and topography using microchanneled cantilevers, also known as FluidFM nanopipette probes. These hollow cantilevers with a 300 nm opening are employed for ion current measurements that provide access to the local properties of the electrical double layer using the phenomenon of ion current rectification, while also taking advantage of the force sensing capabilities for accurate probe vertical positioning and topography imaging. The independent nature of this atomic force microscope (AFM) feedback opens up a possibility to significantly increase the sensitivity for probing local surface charges in a wider range of salt concentrations, especially in electrolytes of low ionic strength (below 10 mM), where classical local ion conductance measurements with glass nanopipettes would suffer from inaccuracies and instabilities, but where the electrical double layer extends further into the liquid medium and has stronger effect on the measured ion currents for charge imaging.

Simple and Inexpensive Paper-Based Astrocyte Co-culture to Improve Survival of Low-Density Neuronal Networks.

Bottom-up neuroscience aims to engineer well-defined networks of neurons to investigate the functions of the brain. By reducing the complexity of the brain to achievable target questions, such bioassays better control experimental variables and can serve as a versatile tool for fundamental and pharmacological research. Astrocytes are a cell type critical to neuronal function, and the addition of astrocytes to neuron cultures can improve the quality of assays.

Local Chemical Stimulation of Neurons with the Fluidic Force Microscope (FluidFM).

Physiological communication between neurons is dependent on the exchange of neurotransmitters at the synapses. Although this chemical signal transmission targets specific receptors and allows for subtle adaptation of the action potential, in vitro neuroscience typically relies on electrical currents and potentials to stimulate neurons. The electric stimulus is unspecific and the confinement of the stimuli within the media is technically difficult to control and introduces large artifacts in electric recordings of the activity.

Collaborative effects of electric field and fluid shear stress on fibroblast migration.

Cells are inherently exposed to a number of different biophysical stimuli such as electric fields, shear stress, and tensile or compressive stress from the extracellular environment in vivo. Each of these biophysical cues can work simultaneously or independently to regulate cellular functions and tissue integrity in both physiological and pathological conditions. Thus, it is vital to understand the interaction of multiple stimuli on cells by decoupling and coupling the stimuli in simple combinations and by investigating cellular behaviors in response to these cues.