Hemodynamic and metabolic changes induced by cocaine in anesthetized rat observed with multimodal functional MRI

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TitleHemodynamic and metabolic changes induced by cocaine in anesthetized rat observed with multimodal functional MRI
Publication TypeJournal Article
Year of Publication2006
AuthorsSchmidt, KF, Febo, M, Shen, Q, Luo, F, Sicard, KM, Ferris, CF, Stein, EA, Duong, TQ
JournalPsychopharmacology (Berl)Psychopharmacology (Berl)
Volume185
Pagination479-86
Date PublishedMay
ISBN Number0033-3158 (Print)<br/>0033-3158 (Linking)
Accession Number16550388
AbstractRATIONALE: Physiological changes (such as heart rate and respiration rate) associated with strong pharmacological stimuli could change the blood-oxygenation-level-dependent (BOLD) functional magnetic resonance imaging (fMRI) mapping signals, independent of neural activity. OBJECTIVES: This study investigates whether the physiological changes per se associated with systemic cocaine administration (1 mg/kg) contaminate the BOLD fMRI signals by measuring BOLD and cerebral blood flow (CBF) fMRI and estimating the cerebral metabolic rate of oxygen (CMRO(2)) changes. MATERIALS AND METHODS: BOLD and CBF fMRI was performed, and changes in CMRO(2) were estimated using the BOLD biophysical model. RESULTS: After systemic cocaine administration, blood pressure, heart rate, and respiration rate increased, fMRI signals remained elevated after physiological parameters had returned to baseline. Cocaine induced changes in the BOLD signal within regions of the reward pathway that were heterogeneous and ranged from -1.2 to 5.4%, and negative changes in BOLD were observed along the cortical surface. Changes in CBF and estimated CMRO(2) were heterogeneous and positive throughout the brain, ranging from 14 to 150% and 10 to 55%, respectively. CONCLUSIONS: This study demonstrates a valuable tool to investigate the physiological and biophysical basis of drug action on the central nervous system, offering the means to distinguish the physiological from neural sources of the BOLD fMRI signal.