A novel method for oxygen glucose deprivation model in organotypic spinal cord slices.

This study aimed to establish a model to closely mimic spinal cord hypoxic-ischemic injury with high production and high reproducibility. Fourteen-day cultured organotypic spinal cord slices were divided into 4 groups: control (Ctrl), oxygen glucose deprived for 30min (OGD 30min), OGD 60min, and OGD 120min. The Ctrl slices were incubated with 1ml propidium iodide (PI) solution (5μg/ml) for 30min. The OGD groups were incubated with 1ml glucose-free DMEM/F12 medium and 5μl PI solution (1mg/ml) for 30min, 60min and 120min, respectively. Positive control slice was fixed by 4% paraformaldehyde for 20min. The culture medium in each group was then collected and the Lactate Dehydrogenase (LDH) level in the medium was tested using Multi-Analyte ELISArray kits. Structure and refraction of the spinal cord slices were observed by light microscope. Fluorescence intensity of PI was examined by fluorescence microscopy and was tested by IPP Software. Morphology of astrocytes was observed by immunofluorescence histochemistry. Caspase 3 and caspase 3 active in different groups were tested by Western blot. In the OGD groups, the refraction of spinal cord slices decreased and the structure was unclear. The changes of refraction and structure in the OGD 120min group were similar to that in the positive control slice. Astrocyte morphology changed significantly. With the increase of OGD time, processes became thick and twisted, and nuclear condensations became more apparent. Obvious changes in morphology were observed in the OGD 60min group, and normal morphology disappeared in the OGD 120min group. Fluorescence intensity of PI increased along with the extension of OGD time. The difference was significant between 30min and 60min, but not significant between 60min and 120min. The intensity at OGD 120min was close to that in the positive control. Compare with the Ctrl group, the OGD groups had significantly higher LDH levels and caspase 3 active/caspase 3 ratios. The values increased with the extension of OGD time and reached peak at 120min. The increase was significant between 30min and 60min, but not significant between 60min and 120min. Organotypic spinal cord slices cultured in glucose-free medium and anaerobic incubator could mimic hypoxia-ischemia of the spinal cord perfectly; 60min could be the best duration for OGD. This technique might be a simple and efficient method to obtain in vitro model for spinal cord hypoxic-ischemic injury in sufficient number and with high quality.