NEW MODELS OF FOCAL CEREBRAL-ISCHEMIA

1 Studies in animal models of stroke have provided an invaluable contribution to our current understanding of the pathogenesis of cerebral ischaemia. The strengths of stroke research in animals are: 1) the ability to control the severity, duration, location and cause of the ischaemia, variables which confound interpretation of human stroke data; 2) co-existent disease states and variations in cerebrovascular anatomy are avoided; and 3) physiological parameters such as blood pressure, blood gases, temperature and plasma glucose (all of which influence the magnitude of the ischaemic lesion) can be closely monitored and controlled. Taking all these things on board, it is possible to induce a consistent focal ischaemic lesion in animal models of stroke (e.g. the permanent occlusion of the middle cerebral artery (MCA) in the rat). This has resulted in the wide use of animal models for assessment of anti-ischaemic drug efficacy as well as for research into the pathophysiological sequelae of stroke. 2 Traditionally focal ischaemia models involved permanent occlusion of a major cerebral artery such as the MCA. However, since vessel occlusion is seldom permanent in human stroke more recent developments have incorporated reperfusion (following ischaemia) into the design of the animal model. This has been achieved by reversible occlusion of cerebral vessels using 1) intraluminal filaments; 2) microclips; 3) the abluminal application of potent and prolonged vasoconstrictors; or 4) the introduction of emboli into the cerebral circulation. 3 Future stroke research will therefore encompass not only the primary consequences of a focal ischaemic insult but also the secondary consequences of reflow through the ischaemic tissue both in terms of the resultant tissue damage and the efficacy of drugs targeted at either the ischaemic or reperfusion phase.