posted on 2022-04-11, 16:09authored byJosé
C. Mateus, Sean Weaver, Dirk van Swaay, Aline F. Renz, Julian Hengsteler, Paulo Aguiar, János Vörös
Methods for patterning neurons in vitro have gradually
improved and are used to investigate questions that are difficult
to address in or ex vivo. Though
these techniques guide axons between groups of neurons, multiscale
control of neuronal connectivity, from circuits to synapses, is yet
to be achieved in vitro. As studying neuronal circuits
with synaptic resolution in vivo poses significant
challenges, we present an in vitro alternative to
validate biophysical and computational models. In this work we use
a combination of electron beam lithography and photolithography to
create polydimethylsiloxane (PDMS) structures with features ranging
from 150 nm to a few millimeters. Leveraging the difference between
average axon and dendritic spine diameters, we restrict axon growth
while allowing spines to pass through nanochannels to guide synapse
formation between small groups of neurons (i.e., nodes). We show this
technique can be used to generate large numbers of isolated feed-forward
circuits where connections between nodes are restricted to regions
connected by nanochannels. Using a genetically encoded calcium indicator
in combination with fluorescently tagged postsynaptic protein, PSD-95,
we demonstrate functional synapses can form in this region.