Delayed Intrahemispheric Remote Hypometabolism

Abstract

Although ‘intrahemispheric diaschisis’ (i.e. a hypometabolism affecting the cerebral hemisphere ipsilateral to but remote from the infarct) may classically exacerbate acute-stage neurological deficit and influence early recovery, it has been studied only rarely. Out of a series of 30 patients with first-ever middle cerebral artery (MCA) territory stroke, we analyzed the data from 19 survivors investigated by 15O positron emission tomography (PET) both in the acute (within 5–18 h of clinical onset) and subacute (approximately 3 weeks later) stage, and for whom chronic-stage CT coregistered with PET was available to assess infarct topography and size. Orgogozo’s MCA scale was used to assess neurological deficits at the time of, and recovery between, the PET studies. Oxygen consumption was obtained for both PET sessions for the whole ipsilateral hemisphere (excluding ventricles and infarct), as well as for the thalamus and the occipital and mesial-prefrontal cortex (i.e. potentially deafferented tissue outside the MCA territory). In all regions except the occipital cortex, the oxygen consumption significantly decreased between the first and the second session, without significant correlation with the concomitant changes in MCA scores. However, acute-stage mesial-prefrontal metabolism was significantly correlated with neurological recovery. Also, both the hemisphere and the mesial-prefrontal metabolism at the second session were significantly correlated with both infarct size and concomitant MCA scores, but the latter relationship became insignificant when infarct size was taken into account. This study reveals no evidence of acute intrahemispheric diaschisis after MCA territory stroke in man. However, it documents for the first time a phenomenon of delayed intrahemispheric remote hypometabolism developing while the patients clinically recover. Because the degree of this secondary phenomenon is a function of infarct size, a mechanism of degeneration of the damaged neuron terminals is likely. Finally, contrary to other reports, neurological recovery was not a function of thalamic hypometabolism, but appeared to be influenced by acute-stage mesial-frontal metabolism, perhaps because this region is part of a network that has an important compensatory role in motor recovery.