Animal models of liver ischaemia and reperfusion are frequently used to study the consequences on liver cells of transient oxygen deprivation. In 3 different rat models we studied ischaemia/reperfusion effects on liver cell membrane integrity, cytoplasmic enzyme proteins and enzyme activities by in situ histochemical techniques. In vivo ischaemia, as well as no-flow hypoxia, or N2-induced hypoxia in isolated perfused livers, reduced the activity of 5'-nucleotidase, a sensitive marker for plasma membrane damage in hepatocytes. As little as 2 minutes of reoxygenation in each model resulted in leakage of soluble enzymes from parenchymal and non-parenchymal liver cells, as shown by decreased protein level and activity of cytoplasmic enzymes. Whereas a multifocal decrease was observed after in vivo reperfusion, a decrease was found in all periportal and midzonal cells after blood-free reoxygenation. As judged by alkaline phosphatase activity and immunohistochemistry, an influx of inflammatory cells was not found in the in vivo model. Our findings indicate that reoxygenation itself, rather than restoration of flow, accounts for the loss of soluble enzymes from liver cells after a period of hypoxia. In situ detection of enzyme protein and activity proved useful for the examination of very early ischaemia/reperfusion effects on rat liver cells.