Abstract
Functional magnetic resonance imaging, as a non-invasive technique, offers unique opportunities to assess brain function and connectivity under a broad range of applications, ranging from passive sensory stimulation to high-level cognitive abilities, in awake animals. This approach is confounded, however, by the fact that physical restraint and loud unpredictable acoustic noise must inevitably accompany fMRI recordings. These factors induce marked stress in rodents, and stress-related elevations of corticosterone levels are known to alter information processing and cognition in the rodent. Here, we propose a habituation strategy that spans specific stages of adaptation to restraint, MRI noise, and confinement stress in awake rats and circumvents the need for surgical head restraint. This habituation protocol results in stress levels during awake fMRI that do not differ from pre-handling levels and enables stable image acquisition with very low motion artifacts. For this, rats were gradually trained over a period of three weeks and eighteen training sessions. Stress levels were assessed by analysis of fecal corticosterone metabolite levels and breathing rates. We observed significant drops in stress levels to below pre-handling levels at the end of the habituation procedure. During fMRI in awake rats, after the conclusion of habituation and using a non-invasive head-fixation device, breathing was stable and head motion artifacts were minimal. A task-based fMRI experiment, using acoustic stimulation, conducted 2 days after the end of habituation, resulted in precise whole brain mapping of BOLD signals in the brain, with clear delineation of the expected auditory-related structures. The active discrimination by the animals of the acoustic stimuli from the backdrop of scanner noise was corroborated by significant increases in BOLD signals in the thalamus and reticular formation. Taken together, these data show that effective habituation to awake fMRI can be achieved by gradual and incremental acclimatization to the experimental conditions. Subsequent BOLD recordings, even during superimposed acoustic stimulation, reflect low stress-levels, low motion and a corresponding high-quality image acquisition. Furthermore, BOLD signals obtained during fMRI indicate that effective habituation facilitates selective attention to sensory stimuli that can in turn support the discrimination of cognitive processes in the absence of stress confounds.
Highlights
Functional magnetic resonance imaging, based on the blood-oxygenation-level dependent (BOLD) signal, is a powerful non-invasive procedure, which serves as an indirect indicator of neuronal activity (Ogawa et al, 1992; Logothetis, 2002)
We describe a novel method to habituate rats to Functional magnetic resonance imaging (fMRI) procedures that results in lower stress levels in the animals, such that stress confounds in data acquisition are circumvented
These findings show how awake fMRIhabituation of rats to achieve stress levels that are not different from pre-handling levels, low motion estimates, stable physiological parameters and the use of a sparse imaging paradigm, allow for sensitive detection of brain activity linked to auditory information processing
Summary
Functional magnetic resonance imaging (fMRI), based on the blood-oxygenation-level dependent (BOLD) signal, is a powerful non-invasive procedure, which serves as an indirect indicator of neuronal activity (Ogawa et al, 1992; Logothetis, 2002). To acquire meaningful functional neuroimaging data, subjects must remain still during imaging For this reason, most animal fMRI studies are conducted under general anesthesia, or sedation, to minimize motion artifacts and to remove the stress component (Sicard et al, 2003): Stress increases the likelihood of head movement and distorts cognition and information encoding (Lucassen et al, 2014; Joëls, 2018), selective attention (Elling et al, 2011; Dagnino-Subiabre, 2013; Hurtubise and Howland, 2017), and creates a bias in the fMRI results obtained (Diamond et al, 1992, 2004; Kim and Diamond, 2002). Anesthesia and sedation alter the threshold for the induction of synaptic plasticity (Riedel et al, 1994; Ribeiro et al, 2015), a key cellular process underlying experience-dependent information encoding and updating in the brain (Manahan-Vaughan, 2017)
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