Stimulus contrast modulates burst activity in the lateral geniculate nucleus

Alyssa N. Sanchez , Henry J. Alitto , Daniel L. Rathbun , Tucker G. Fisher , W. Martin Usrey
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Abstract

Burst activity is a ubiquitous feature of thalamic neurons and is well documented for visual neurons in the lateral geniculate nucleus (LGN). Although bursts are often associated with states of drowsiness, they are also known to convey visual information to cortex and are particularly effective in evoking cortical responses. The occurrence of thalamic bursts depends on (1) the inactivation gate of T-type Ca2+ channels (T-channels), which become de-inactivated following periods of increased membrane hyperpolarization, and (2) the opening of the T-channel activation gate, which has voltage-threshold and rate-of-change (δv/δt) requirements. Given the time/voltage relationship for the generation of Ca2+ potentials that underlie burst events, it is reasonable to predict that geniculate bursts are influenced by the luminance contrast of drifting grating stimuli, with the null phase of higher contrast stimuli evoking greater hyperpolarization followed by a larger dv/dt than the null phase of lower contrast stimuli. To determine the relationship between stimulus contrast and burst activity, we recorded the spiking activity of cat LGN neurons while presenting drifting sine-wave gratings that varied in luminance contrast. Results show that burst rate, reliability, and timing precision are significantly greater with higher contrast stimuli compared with lower contrast stimuli. Additional analysis from simultaneous recordings of synaptically connected retinal ganglion cells and LGN neurons further reveals the time/voltage dynamics underlying burst activity. Together, these results support the hypothesis that stimulus contrast and the biophysical properties underlying the state of T-type Ca2+ channels interact to influence burst activity, presumably to facilitate thalamocortical communication and stimulus detection.

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刺激对比调节外侧膝状核的爆发活动
突发活动是丘脑神经元普遍存在的特征,在外侧膝状体核(LGN)的视觉神经元中也有很好的记录。尽管爆发通常与嗜睡状态有关,但众所周知,它们也能向皮层传递视觉信息,并且在唤起皮层反应方面特别有效。丘脑爆发的发生取决于(1)T型Ca2+通道(T通道)的失活门,T通道在膜超极化增加后失活,以及(2)T通道激活门的打开,T通道的激活门具有电压阈值和变化率(δv/δT)要求。考虑到爆发事件背后Ca2+电位产生的时间/电压关系,可以合理地预测膝状体爆发受到漂移光栅刺激的亮度对比度的影响,高对比度刺激的零相位引起更大的超极化,随后是比低对比度刺激零相位更大的dv/dt。为了确定刺激对比度和爆发活动之间的关系,我们记录了猫LGN神经元的尖峰活动,同时呈现亮度对比度变化的漂移正弦波光栅。结果表明,与低对比度刺激相比,高对比度刺激的突发率、可靠性和定时精度显著更高。来自突触连接的视网膜神经节细胞和LGN神经元的同时记录的额外分析进一步揭示了爆发活动背后的时间/电压动力学。总之,这些结果支持了这样一种假设,即刺激对比度和T型Ca2+通道状态下的生物物理特性相互作用,影响爆发活动,可能是为了促进丘脑皮质的交流和刺激检测。
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