| BMC Neuroscience | |
| Kuramoto model simulation of neural hubs and dynamic synchrony in the human cerebral connectome | |
| Research Article | |
| Leonard H. van den Berg1 Karl J. R. LaFleur1 Ruben Schmidt1 Marcel A. de Reus2 Martijn P. van den Heuvel2 | |
| [1] Department of Neurology, Brain Center Rudolf Magnus, University Medical Center Utrecht, PO Box 85500, Heidelberglaan 100, 3508 GA, Utrecht, Netherlands;Department of Psychiatry, Brain Center Rudolf Magnus, University Medical Center Utrecht, PO Box 85500, Heidelberglaan 100, 3508 GA, Utrecht, Netherlands; | |
| 关键词: Hub node; Structural connectivity; Neural synchronization; Cortical coupling; Suppression; Perturbation; | |
| DOI : 10.1186/s12868-015-0193-z | |
| received in 2014-12-19, accepted in 2015-08-14, 发布年份 2015 | |
| 来源: Springer | |
 PDF
|
|
【 摘 要 】
BackgroundThe topological structure of the wiring of the mammalian brain cortex plays an important role in shaping the functional dynamics of large-scale neural activity. Due to their central embedding in the network, high degree hub regions and their connections (often referred to as the ‘rich club’) have been hypothesized to facilitate intermodular neural communication and global integration of information by means of synchronization. Here, we examined the theoretical role of anatomical hubs and their wiring in brain dynamics. The Kuramoto model was used to simulate interaction of cortical brain areas by means of coupled phase oscillators—with anatomical connections between regions derived from diffusion weighted imaging and module assignment of brain regions based on empirically determined resting-state data.ResultsOur findings show that synchrony among hub nodes was higher than any module’s intramodular synchrony (p < 10−4, for cortical coupling strengths, λ, in the range 0.02 < λ < 0.05), suggesting that hub nodes lead the functional modules in the process of synchronization. Furthermore, suppressing structural connectivity among hub nodes resulted in an elevated modular state (p < 4.1 × l0−3, 0.015 < λ < 0.04), indicating that hub-to-hub connections are critical in intermodular synchronization. Finally, perturbing the oscillatory behavior of hub nodes prevented functional modules from synchronizing, implying that synchronization of functional modules is dependent on the hub nodes’ behavior.ConclusionOur results converge on anatomical hubs having a leading role in intermodular synchronization and integration in the human brain.
【 授权许可】
CC BY
© Schmidt et al. 2015
【 预 览 】
| Files | Size | Format | View |
|---|---|---|---|
| RO202311104590831ZK.pdf | 2141KB |  download |
【 参考文献 】
- [1]
- [2]
- [3]
- [4]
- [5]
- [6]
- [7]
- [8]
- [9]
- [10]
- [11]
- [12]
- [13]
- [14]
- [15]
- [16]
- [17]
- [18]
- [19]
- [20]
- [21]
- [22]
- [23]
- [24]
- [25]
- [26]
- [27]
- [28]
- [29]
- [30]
- [31]
- [32]
- [33]
- [34]
- [35]
- [36]
- [37]
- [38]
- [39]
- [40]
- [41]
- [42]
- [43]
- [44]
- [45]
- [46]
- [47]
- [48]
- [49]
- [50]
- [51]
- [52]
- [53]
- [54]
- [55]
878987797
028-85220240
