This K01 application is designed to prepare the applicant with the skills necessary to establish an independent research program on pain-related processing in the cerebellum. Although pain studies using functional imaging in humans consistently find cerebellar activation, the role of this structure during pain is unknown. In such studies, speculation regarding the cerebellum's function during a painful event is often influenced by its reputation as a coordinator of motor function, though animal studies have indicated that it may also modulate the neural encoding of noxious stimuli. The candidate has published work that indicates a functional dichotomy in the way the cerebellum responds to experimental pain in healthy subjects and neuropathic pain patients. This suggests that the cerebellum has been overlooked as a potential pain processing area, and research into this area could lend invaluable insight into the basic physiological circuitry involved with pain and its modulation. The hypothesis of this project is that the cerebellum serves as an integrator of aversive stimuli and adaptive motor behavior, and may modulate the emotional and cognitive experience that distinguishes the perception of pain from the appreciation of innocuous sensory stimulation. A human trigeminal model of experimental pain will be used, as all the pain-related circuitry involved can be imaged along with the cerebellum at the same time.
The specific aims are (1) to map cerebellar activations related to sensory coding of noxious stimuli and to correlate functional activity with anatomical connectivity using functional magnetic resonance imaging (fMRI) and diffusion tensor imaging (DTI);(2) to distinguish between pain and its anticipation based on cerebellar responses and connectivity;and (3) to determine whether physical pain and aversive images engage similar circuitry in the cerebellum. To accomplish these aims, the candidate will need to expand his background in fMRI of cortical and brainstem pain processing to encompass cerebellar physiology, become proficient in DTI analysis, and learn the white matter connectivity to and from the cerebellum. The research environment at McLean Hospital and the other affiliates of the Harvard Medical School system will provide the candidate with the resources to reach his aims within 4 years. Enhanced understanding of cerebellar pain processing may lead to new treatments for chronic neuropathic pain conditions, which can have altered cerebellar functionality.

National Institute of Health (NIH)
National Institute on Drug Abuse (NIDA)
Research Scientist Development Award - Research & Training (K01)
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Human Development Research Subcommittee (NIDA)
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Lin, Yu
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Children's Hospital Boston
United States
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Moulton, Eric A; Elman, Igor; Becerra, Lino R et al. (2014) The cerebellum and addiction: insights gained from neuroimaging research. Addict Biol 19:317-31
Moulton, Eric A; Pendse, Gautam; Becerra, Lino R et al. (2012) BOLD responses in somatosensory cortices better reflect heat sensation than pain. J Neurosci 32:6024-31
Linnman, Clas; Moulton, Eric A; Barmettler, Gabi et al. (2012) Neuroimaging of the periaqueductal gray: state of the field. Neuroimage 60:505-22
Moulton, E A; Becerra, L; Maleki, N et al. (2011) Painful heat reveals hyperexcitability of the temporal pole in interictal and ictal migraine States. Cereb Cortex 21:435-48
Moulton, Eric A; Elman, Igor; Pendse, Gautam et al. (2011) Aversion-related circuitry in the cerebellum: responses to noxious heat and unpleasant images. J Neurosci 31:3795-804
Moulton, Eric A; Schmahmann, Jeremy D; Becerra, Lino et al. (2010) The cerebellum and pain: passive integrator or active participator? Brain Res Rev 65:14-27