Digital holographic microscopy (DHM) has been gaining interest from cell biology community because of its label free
nature and quantitative phase signal output. Besides, fast shutter time, image reconstruction by numerical propagation of
the wave fields, and numerical compensation of the aberrations are other intrinsic advantages of this technique that can
be explored for harsh imaging conditions. In the frame of this work, a transmission type DHM is developed with a
decoupled epifluorescence microscopy mode for cytomorphological monitoring under zero gravity and hyper gravity.
With the implemented automatic post processing routines, real time observation of the cell morphology is proven to be
feasible under the influence of mechanical disturbances of zero gravity platforms. Post processing of holograms is
composed from dynamic numerical compensation of holograms, robust autofocusing and phase image registration.
Experiments on live myoblast cells are carried out on two different platforms; random positioning machine (RPM), a
ground base microgravity simulation platform, and parabolic flight campaign (PFC), a fixed wing plane flight providing
short durations of alternating gravity conditions. Results show clear perinuclear phase increase. During seconds scale
microgravity exposure, measurable scale morphological modifications are observed with the accumulated effect of
repetitive exposures and short breaks.