Jenison Rick L, Reale Richard A, Armstrong Amanda L, Oya Hiroyuki, Kawasaki Hiroto, Howard Matthew A
Department of Psychology, University of Wisconsin Madison, Madison, Wisconsin, United States of America.
Department of Psychology, University of Wisconsin Madison, Madison, Wisconsin, United States of America; Department of Neurosurgery, University of Iowa, Iowa City, Iowa, United States of America.
PLoS One. 2015 Sep 14;10(9):e0137915. doi: 10.1371/journal.pone.0137915. eCollection 2015.
Spectro-Temporal Receptive Fields (STRFs) were estimated from both multi-unit sorted clusters and high-gamma power responses in human auditory cortex. Intracranial electrophysiological recordings were used to measure responses to a random chord sequence of Gammatone stimuli. Traditional methods for estimating STRFs from single-unit recordings, such as spike-triggered-averages, tend to be noisy and are less robust to other response signals such as local field potentials. We present an extension to recently advanced methods for estimating STRFs from generalized linear models (GLM). A new variant of regression using regularization that penalizes non-zero coefficients is described, which results in a sparse solution. The frequency-time structure of the STRF tends toward grouping in different areas of frequency-time and we demonstrate that group sparsity-inducing penalties applied to GLM estimates of STRFs reduces the background noise while preserving the complex internal structure. The contribution of local spiking activity to the high-gamma power signal was factored out of the STRF using the GLM method, and this contribution was significant in 85 percent of the cases. Although the GLM methods have been used to estimate STRFs in animals, this study examines the detailed structure directly from auditory cortex in the awake human brain. We used this approach to identify an abrupt change in the best frequency of estimated STRFs along posteromedial-to-anterolateral recording locations along the long axis of Heschl's gyrus. This change correlates well with a proposed transition from core to non-core auditory fields previously identified using the temporal response properties of Heschl's gyrus recordings elicited by click-train stimuli.
从人类听觉皮层的多单元分类簇和高伽马功率响应中估计了光谱-时间感受野(STRF)。颅内电生理记录用于测量对伽马通刺激的随机和弦序列的响应。从单单元记录中估计STRF的传统方法,如脉冲触发平均法,往往噪声较大,对其他响应信号(如局部场电位)的鲁棒性较差。我们对最近从广义线性模型(GLM)估计STRF的先进方法进行了扩展。描述了一种使用正则化的回归新变体,该正则化对非零系数进行惩罚,从而得到一个稀疏解。STRF的频率-时间结构倾向于在频率-时间的不同区域分组,我们证明,应用于STRF的GLM估计的组稀疏诱导惩罚在保留复杂内部结构的同时降低了背景噪声。使用GLM方法从STRF中分解出局部尖峰活动对高伽马功率信号的贡献,在85%的情况下,这种贡献是显著的。虽然GLM方法已被用于估计动物的STRF,但本研究直接从清醒人脑的听觉皮层检查了详细结构。我们使用这种方法来识别沿着Heschl回长轴从后内侧到前外侧记录位置估计的STRF最佳频率的突然变化。这种变化与先前使用点击训练刺激引起的Heschl回记录的时间响应特性确定的从核心听觉场到非核心听觉场的拟议转变密切相关。
