In this master thesis, we explore magnetoactive elastomers (MAEs) that are structured with lamellae on the surface. We perform basic characterization of relaxation times and the hysteresis response of the structures in a homogeneous magnetic field. For analysis, we employ direct measurement of the peak tracking of the bending lamellae and indirect measurement of their reflectivity as a proxy observable. We compare the results with the continuum theory of lamellar bending, which provides insights into the mechanisms of structure movement. We explain and demonstrate that due to their real-time hysteresis response, MAE lamellae are suitable for the fabrication of transport surfaces for liquids or for active elements in microfluidic circuits. We also describe their potential applicability in adjustable apertures and diffraction gratings. We conclude with prospects for further experiments aimed at their utilization in microfluidics and soft robotics.