Sci 29(37):115401549. 39. Burns SP, Xing D, Shapley RM (2010) Comparisons in the dynamics

Sci 29(37):115401549. 39. Burns SP, Xing D, Shapley RM (2010) Comparisons with the dynamics of neighborhood field prospective and multiunit activity signals in macaque visual cortex. J Neurosci 30(41): 137393749. 40. Nemoto M, et al. (2012) Diversity of neural-hemodynamic relationships connected with differences in cortical processing throughout bilateral somatosensory activation in rats. Neuroimage 59(four):3325338. 41. Goense J, Merkle H, Logothetis NK (2012) High-resolution fMRI reveals laminar variations in neurovascular coupling in between good and damaging BOLD responses. Neuron 76(three):62939. 42. Silva AC, Kim SG (1999) Pseudo-continuous arterial spin labeling technique for measuring CBF dynamics with high temporal resolution. Magn Reson Med 42(3): 42529. 43. Ueki M, Linn F, Hossmann KA (1988) Functional activation of cerebral blood flow and metabolism ahead of and following international ischemia of rat brain. J Cereb Blood Flow Metab 8(four):48694. 44. Kossut M, Hand PJ, Greenberg J, Hand CL (1988) Single vibrissal cortical column in SI cortex of rat and its alterations in neonatal and adult vibrissa-deafferented animals: a quantitative 2DG study. J Neurophysiol 60(two):82952. 45. Einevoll GT, et al. (2007) Laminar population evaluation: estimating firing rates and evoked synaptic activity from multielectrode recordings in rat barrel cortex.25-Hydroxycholesterol J Neurophysiol 97(3):2174190. 46. Malonek D, Grinvald A (1996) Interactions amongst electrical activity and cortical microcirculation revealed by imaging spectroscopy: Implications for functional brain mapping. Science 272(5261):55154. 47. Greenberg JH, Sohn NW, Hand PJ (1999) Nitric oxide and also the cerebral-blood-flow response to somatosensory activation following deafferentation. Exp Brain Res 129(4):54150. 48. Shtoyerman E, Arieli A, Slovin H, Vanzetta I, Grinvald A (2000) Long-term optical imaging and spectroscopy reveal mechanisms underlying the intrinsic signal and stability of cortical maps in V1 of behaving monkeys. J Neurosci 20(21):8111121. 49. Fukuda M, Moon CH, Wang P, Kim SG (2006) Mapping iso-orientation columns by contrast agent-enhanced functional magnetic resonance imaging: Reproducibility, specificity, and evaluation by optical imaging of intrinsic signal. J Neurosci 26(46): 118211832. 50. Yacoub E, Harel N, Ugurbil K (2008) High-field fMRI unveils orientation columns in humans. Proc Natl Acad Sci USA 105(30):106070612. 51. Gawne TJ (2010) The local and non-local elements from the regional field prospective in awake primate visual cortex. J Comput Neurosci 29(3):61523. 52. Kajikawa Y, Schroeder CE (2011) How local would be the local field prospective Neuron 72(5): 84758. 53. Gaucher Q, Edeline JM, Gour itch B (2012) How diverse would be the neighborhood field potentials and spiking activities Insights from multi-electrodes arrays.Florfenicol J Physiol Paris 106(3-4):9303.PMID:23613863 54. Lind H, et al. (2011) Modeling the spatial reach on the LFP. Neuron 72(five):85972. 55. Nelson MJ, Bosch C, Venance L, Pouget P (2013) Microscale inhomogeneity of brain tissue distorts electrical signal propagation. J Neurosci 33(7):2821827. 56. Qiu D, Zaharchuk G, Christen T, Ni WW, Moseley ME (2012) Contrast-enhanced functional blood volume imaging (CE-fBVI): Enhanced sensitivity for brain activation in humans working with the ultrasmall superparamagnetic iron oxide agent ferumoxytol. Neuroimage 62(3):1726731. 57. Sanganahalli BG, Bailey CJ, Herman P, Hyder F (2009) Tactile and non-tactile sensory paradigms for fMRI and neurophysiologic studies in rodents. Strategies Mol Biol 489: 2.