The PM is a key component that viruses have to cope with. It is a barrier for infection and egress and is critically involved in antiviral immune signaling.
Beating cardiomyocytes
undergo fast morphodynamics during the contraction–relaxation
cycle. However, imaging these morphodynamics with a high spatial and
temporal resolution is difficult, owing to a lack of suitable techniques.
Here, we combine scanning ion conductance microscopy (SICM) with a
microelectrode array (MEA) to image the three-dimensional (3D) topography
of cardiomyocytes during a contraction–relaxation cycle with
1 μm spatial and 1 ms time resolution. We record the vertical
motion of cardiomyocytes at many locations across a cell by SICM and
synchronize these data using the simultaneously recorded action potential
by the MEA as a time reference. This allows us to reconstruct the
time-resolved 3D morphology of cardiomyocytes during a full contraction–relaxation
cycle with a raw data rate of 200 μs/frame and to generate spatially
resolved images of contractile parameters (maximum displacement, time
delay, asymmetry factor). We use the MEA-SICM setup to visualize the
effect of blebbistatin, a myosin II inhibitor, on the morphodynamics
of contractions. Further, we find an upper limit of 0.02% for cell
volume changes during an action potential. The results show that MEA-SICM
provides an ultrafast imaging platform for investigating the functional
interplay of cardiomyocyte electrophysiology and mechanics.
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