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304-04-008
ISMRM Abstract
Zona Incerta Neural Activity Regulates Sensorimotor Cortical-Subcortical Network Dynamics through Hypothalamus and Striatum
Accepted
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1. Yang Y, Jiang T, Jia X, Yuan J, Li X, Gong H. Whole-brain connectome of GABAergic neurons in the mouse zona incerta. Neuroscience Bulletin 38:1315–1329, (2022).
2. Zhao ZD, Chen Z, Xiang X, Hu M, Xie H, Jia X, Cai F, Cui Y, Chen Z, Qian L, Liu J, Shang C, Yang Y, Ni X, Sun W, Hu J, Cao P, Li H, Shen WL. Zona incerta GABAergic neurons integrate prey-related sensory signals and induce an appetitive drive to promote hunting. Nature Neuroscience 22:921–932, (2019).
3. Liu K, Kim J, Kim DW, Zhang YS, Bao H, Denaxa M, Lim SA, Kim E, Liu C, Wickersham IR, Pachnis V, Hattar S, Song J, Brown SP, Blackshaw S. Lhx6-positive GABA-releasing neurons of the zona incerta promote sleep. Nature 548:582–587, (2017).
4. Wu K, Wang D, Wang Y, Tang P, Li X, Pan Y, Tao HW, Zhang LI, Liang F. Distinct circuits in anterior cingulate cortex encode safety assessment and mediate flexibility of fear reactions. Neuron 111(22):3650–3667.e6, (2023).
5. Zhou M, Liu Z, Melin MD, Ng YH, Xu W, Südhof TC. A central amygdala to zona incerta projection is required for acquisition and remote recall of conditioned fear memory. Nature Neuroscience 21:1515–1519, (2018).
6. Weitz AJ, Lee HJ, Choy M, Lee JH. Thalamic Input to Orbitofrontal Cortex Drives Brain-wide, Frequency-Dependent Inhibition Mediated by GABA and Zona Incerta. Neuron, 104(6), 1153–1167.e4. (2019).
7. Finn ES, Poldrack RA, Shine JM. Functional neuroimaging as a catalyst for integrated neuroscience. Nature 623:263–273, (2023).
8. Moon HS, Vo TT, Ho Im G, Hong SJ, Kim SG. Interhemispheric resting-state functional connectivity correlates with spontaneous neural interactions. Proceedings of the National Academy of Sciences of the United States of America 122(34):e2505294122, (2025).
9. Xie L, Wang X, Lin X, Wen J, Ma T, Leong ATL, Wu EX. Brain-wide resting-state fMRI network dynamics elicited by activation of single thalamic input. Nature Communications, (2025; in press).
10. Xie L, Wang X, Ma T, Zeng H, Wen J, Cao P, Wu EX, Leong ATL. Short single pulse optogenetic fMRI mapping of downstream targets in thalamo-cortical pathways. Proceedings of the International Society for Magnetic Resonance in Medicine:1268, (2023).
11. Xie L, Wang X, Lin X, Ma T, Wen J, Cao P, Leong ATL, Wu EX. Single-pulse optogenetic perturbation of thalamo-cortical networks reveals functional architecture of rsfMRI networks. Proceedings of the International Society for Magnetic Resonance in Medicine:0530, (2024).
12. Xie L, Wang X, Lin X, Wen J, Leong ATL, Wu EX. Intra- and inter-regional neural activity synchronizations drive fMRI network dynamics upon single thalamic input. Proceedings of the International Society for Magnetic Resonance in Medicine:0989, (2025).
13. Leong ATL, Chan RW, Gao PP, Chan YS, Tsia KK, Yung WH, Wu EX. Long-range projections coordinate distributed brain-wide neural activity with a specific spatiotemporal profile. Proceedings of the National Academy of Sciences of the United States of America 113:E8306–E8315, (2016).
14. Chan RW, Leong ATL, Ho LC, Gao PP, Wong EC, Dong CM, Wang X, He J, Chan YS, Lim LW, Wu EX. Low-frequency hippocampal–cortical activity drives brain-wide resting-state functional MRI connectivity. Proceedings of the National Academy of Sciences of the United States of America 114(33):E6972–E6981, (2017).
15. Wang X, Leong ATL, Chan RW, Liu Y, Wu EX. Thalamic low frequency activity facilitates resting-state cortical interhemispheric MRI functional connectivity. NeuroImage 200:115985, (2019).
16. Wang X, Leong ATL, Tan SZK, Wong EC, Liu Y, Lim LW, Wu EX. Functional MRI reveals brain-wide actions of thalamically initiated oscillatory activities on associative memory consolidation. Nature Communications 14:2195, (2023).
17. Lin S, Zhu MY, Tang MY, Wang M, Yu XD, Zhu Y, Xie SZ, Yang D, Chen J, Li XM. Somatostatin-positive neurons in the rostral zona incerta modulate innate fear-induced defensive response in mice. Neuroscience Bulletin 39:245–260, (2023).
18. Chou XL, Wang X, Zhang ZG, Shen L, Zingg B, Huang J, Zhong W, Mesik L, Zhang LI, Tao HW. Inhibitory gain modulation of defense behaviors by zona incerta. Nature Communications 9:1151, (2018).
19. Wang X, Chou X, Peng B, Shen L, Huang JJ, Zhang LI, Tao HW. A cross-modality enhancement of defensive flight via parvalbumin neurons in zona incerta. eLife 8:e42728, (2019).
20. Shine JM, Aburn MJ, Breakspear M, Poldrack RA. The modulation of neural gain facilitates a transition between functional segregation and integration in the brain. eLife 7:e31130, (2018).
21. Bassett DS, Wymbs NF, Porter MA, Mucha PJ, Carlson JM, Grafton ST. Dynamic reconfiguration of human brain networks during learning. Proceedings of the National Academy of Sciences of the United States of America 108(18):7641–7646, (2011).
Cite this abstract
http://echo.ismrm.org/p/ISMRM2026/304-04-008