Direct Transfer of GaAs Microtube Arrays onto Transparent Substrates for Imaging Neuron Outgrowth

Abstract: We introduce a direct method for transferring arrays of GaAs microtubes from an opaque substrate to a transparent glass substrate in a controlled manner. This enables us to build a platform for optical readout of the microtubes' interaction with overgrown cellular networks. We achieve this by applying a double layer of polydimethylsiloxane (PDMS). The first PDMS layer serves as a smooth and mechanically compliant transparent substrate. The second, adhesive layer contains a mixture of PDMS and n-hexane, which c… Show more

“…Due to restrictions of the MBE, we engineered this emission WL to be 820 nm. The room temperature (RT) photoluminescence (PL) measurements are carried out on microtubes, which are transferred to a transparent glass substrate coated with a double‐layer system of PDMS . This transfer is essential, since (a) the interaction of GaAs substrate with the cellular materials is completely avoided and (b) the emission of the microtube–axon hybrids is more pronounced, i.e., less absorption by the semiconductor substrate .…”

Approaching Integrated Hybrid Neural Circuits: Axon Guiding on Optically Active Semiconductor Microtube Arrays

“…Due to restrictions of the MBE, we engineered this emission WL to be 820 nm. The room temperature (RT) photoluminescence (PL) measurements are carried out on microtubes, which are transferred to a transparent glass substrate coated with a double‐layer system of PDMS . This transfer is essential, since (a) the interaction of GaAs substrate with the cellular materials is completely avoided and (b) the emission of the microtube–axon hybrids is more pronounced, i.e., less absorption by the semiconductor substrate .…”

Approaching Integrated Hybrid Neural Circuits: Axon Guiding on Optically Active Semiconductor Microtube Arrays

Synthetic neuronal circuits: Optically active semiconductor microtubes as remotely accessible sensors for action potentials