<!--The MED system is well suited for experiments using acute slices as well as slice (and cell) cultures. The low impedance of of Pt. black electrodees (7-10 khom at 1 kHz tycpially) enables to acquire several types of signals (from slow-wave to spike signals) easily.  

<!--The MED system is well suited for experiments using acute slices as well as slice (and cell) cultures. The low impedance of of Pt. black electrodees (7-10 khom at 1 kHz tycpially) enables to acquire several types of signals (from slow-wave to spike signals) easily.  

Multi-electrode arrays are widely used in studies of the central (CNS: e.g. Cortex, Hippocampus; retina, Suprachiasmatic Nucleus, SCN) and peripheral (PNS: e.g. Dorsal Root Ganglion, DRG) nervous system, as well as myocardial and other excitable tissue (e.g. smooth muscle). Extracellular stimulation and recording can be combined with patch clamping, microscopic visualization, or other methods (e.g. Ca ++ imaging) used to examine relationships between structure and function.-->

Multi-electrode arrays are widely used in studies of the central (CNS: e.g. Cortex, Hippocampus; retina, Suprachiasmatic Nucleus, SCN) and peripheral (PNS: e.g. Dorsal Root Ganglion, DRG) nervous system, as well as myocardial and other excitable tissue (e.g. smooth muscle). Extracellular stimulation and recording can be combined with patch clamping, microscopic visualization, or other methods (e.g. Ca ++ imaging) used to examine relationships between structure and function.-->

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