Prefrontal regions supporting spontaneous and directed application of verbal learning strategies: Evidence from PET

doi:10.1093/brain/124.1.219

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Brain, Vol. 124, No. 1, 219-231, January 2001
© 2001 Oxford University Press

Prefrontal regions supporting spontaneous and directed application of verbal learning strategies

Evidence from PET

Cary R. Savage¹, Thilo Deckersbach¹, Stephan Heckers¹, Anthony D. Wagner²^,3, Daniel L. Schacter⁴, Nathaniel M. Alpert², Alan J. Fischman² and Scott L. Rauch¹^,2

¹ Departments of Psychiatry and ² Radiology, Massachusetts General Hospital and Harvard Medical School, Boston, ³ Department of Brain and Cognitive Sciences, Massachusetts Institute of Technology and ⁴ Department of Psychology, Harvard University, Cambridge, Massachusetts, USA

Correspondence to: Cary Savage, Cognitive Neuroscience Group, Department of Psychiatry, 149-9102, Massachusetts General Hospital, Building 149, 13th St. Charlestown, MA 02129-2060, USA E-mail: savage{at}psych.mgh.harvard.edu

The prefrontal cortex has been implicated in strategic memoryprocesses, including the ability to use semantic organizationalstrategies to facilitate episodic learning. An important featureof these strategies is the way they are applied in novel orambiguous situations—failure to initiate effective strategiesspontaneously in unstructured settings is a central cognitivedeficit in patients with frontal lobe disorders. The currentstudy examined strategic memory with PET and a verbal encodingparadigm that manipulated semantic organization in three encodingconditions: spontaneous, directed and unrelated. During thespontaneous condition, subjects heard 24 words that were relatedin four categories but presented in mixed order, and they werenot informed of this structure beforehand. Any semantic reorganizationwas, therefore, initiated spontaneously by the subject. In thedirected condition, subjects were given a different list of24 related words and explicitly instructed to notice relationshipsand mentally group related words together to improve memory.The unrelated list consisted of 24 unrelated words. Behaviouralmeasures included semantic clustering, which assessed activeregrouping of words into semantic categories during free recall.In graded PET contrasts (directed > spontaneous > unrelated),two distinct activations were found in left inferior prefrontalcortex (inferior frontal gyrus) and left dorsolateral prefrontalcortex (middle frontal gyrus), corresponding to levels of semanticclustering observed in the behavioural data. Additional covariateanalyses in the first spontaneous condition indicated that bloodflow in orbitofrontal cortex (OFC) was strongly correlated withsemantic clustering scores during immediate free recall. Thus,blood flow in OFC during encoding predicted which subjects wouldspontaneously initiate effective strategies during free recall.Our findings indicate that OFC performs an important, and previouslyunappreciated, role in strategic memory by supporting the earlymobilization of effective behavioural strategies in novel orambiguous situations. Once initiated, lateral regions of leftprefrontal cortex control verbal semantic organization.

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