Abstract
Functional magnetic resonance imaging (fMRI) is a unique window to the brain, enabling scientists to follow changes in brain activity in response to hormones, ageing, environment, drugs of abuse and other stimuli. There are two features that make fMRI unique when compared with other imaging modalities used in behavioural neuroscience. First, it can be entirely noninvasive: each animal can serve as its own control over the natural course of its life, vital for following neuroadaptation and other developmental processes critical to understanding behaviour. Second, fMRI has the spatial and temporal resolution to observe patterns of neuronal activity across the entire brain in less than a minute. Although fMRI does not have the cellular spatial resolution of immunostaining, nor the millisecond temporal resolution of electrophysiology, synchronised changes in neuronal activity across multiple brain areas seen with functional MRI can be viewed as functional neuroanatomical circuits coordinating the thoughts, memories and emotions for particular behaviours. Thus, fMRI affords a systems approach to the study of the brain, complementing and building from other neurobiological techniques to understand how behaviour is organised across multiple brain regions. In this review, we present a general background to fMRI and the different imaging modalities that can be used in fMRI studies. Included are examples of the application of fMRI in behavioural neuroscience research, along with discussion of the advantages and disadvantages of this technology.
Highlights
Functional magnetic resonance imaging is a unique window to the brain, enabling scientists to follow changes in brain activity in response to hormones, ageing, environment, drugs of abuse and other stimuli
The relationship between metabolism, haemoglobin oxygen saturation, blood flow and MR signal intensity is shown in Fig. 1 and is called the blood oxygen level dependent technique for functional imaging or Blood oxygen level dependent (BOLD) [5]
There are no significant differences in the response to ethanol challenge between cortex and striatum in terms of absorption and maximum response; a much slower elimination rate was observed in cortex compared to striatum leading to Cerebral blood volume (CBV) signal with a greater area under the curve (AUC) in cortex
Summary
Functional magnetic resonance imaging in conscious animals: a new tool in behavioural neuroscience research. Let us know how access to this document benefits you. Part of the Medicine and Health Sciences Commons, and the Neuroscience and Neurobiology Commons. Repository Citation Ferris CF, Febo M, Luo F, Schmidt KF, Brevard ME, Harder JA, Kulkarni PP, Messenger TL, King JA. Functional Magnetic Resonance Imaging in Conscious Animals: A New Tool in Behavioural Neuroscience Research.
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