Teich Andrew F, Qian Ning
Center for Neurobiology and Behavior, Mahoney Center for Brain and Behaviour Research, and Department of Physiology and Cellular Biophysics, Columbia University, New York, NY 10032, USA.
J Neurophysiol. 2006 Jul;96(1):404-19. doi: 10.1152/jn.00015.2005. Epub 2006 Apr 19.
Several models exist for explaining primary visual cortex (V1) orientation tuning. The modified feedforward model (MFM) and the recurrent model (RM) are major examples. We have implemented these two models, at the same level of detail, alongside a few newer variations, and thoroughly compared their receptive-field structures. We found that antiphase inhibition in the MFM enhances both spatial phase information and orientation tuning, producing well-tuned simple cells. This remains true for a newer version of the MFM that incorporates untuned complex-cell inhibition. In contrast, when the recurrent connections in the RM are strong enough to produce typical V1 orientation tuning, they also eliminate spatial phase information, making the cells complex. Introducing phase specificity into the connections of the RM (as done in an original version of the RM) can make the cells phase sensitive, but the cells show an incorrect 90 degrees peak shift of orientation tuning under opposite contrast signs. An inhibition-dominant version of the RM can generate well-tuned cells across the simple-complex spectrum, but it predicts that the net effect of cortical interactions is to suppress feedforward excitation across all orientations in simple cells. Finally, adding antiphase inhibition used in the MFM into the RM produces a most general model. We call this new model the modified recurrent model (MRM) and show that this model can also produce well-tuned cells throughout the simple-complex spectrum. Unlike the inhibition-dominant RM, the MRM is consistent with data from cat V1, suggesting that the net effect of cortical interactions is to boost simple cell responses at the preferred orientation. These results suggest that the MFM is well suited for explaining orientation tuning in simple cells, whereas the standard RM is for complex cells. The assignment of the RM to complex cells also avoids conflicts between the RM and the experiments of cortical inactivation (done on simple cells) and the spatial-frequency dependency of orientation tuning (found in simple cells). Because orientation-tuned V1 cells show a continuum of simple- to complex-cell behavior, the MRM provides the best description of V1 data.
存在多种用于解释初级视觉皮层(V1)方向调谐的模型。改进的前馈模型(MFM)和循环模型(RM)是主要的例子。我们以相同的详细程度实现了这两种模型,以及一些较新的变体,并全面比较了它们的感受野结构。我们发现,MFM中的反相抑制增强了空间相位信息和方向调谐,产生了调谐良好的简单细胞。对于纳入了未调谐复杂细胞抑制的MFM新版本,情况依然如此。相比之下,当RM中的循环连接足够强以产生典型的V1方向调谐时,它们也会消除空间相位信息,使细胞变为复杂细胞。在RM的连接中引入相位特异性(如原始版本的RM中所做的那样)可以使细胞对相位敏感,但在相反的对比度符号下,细胞的方向调谐会出现90度的错误峰值偏移。RM的抑制主导版本可以在简单 - 复杂频谱范围内生成调谐良好的细胞,但它预测皮层相互作用的净效应是抑制简单细胞在所有方向上的前馈兴奋。最后,将MFM中使用的反相抑制添加到RM中产生了一个最通用的模型。我们将这个新模型称为改进的循环模型(MRM),并表明该模型也可以在整个简单 - 复杂频谱范围内产生调谐良好的细胞。与抑制主导的RM不同,MRM与猫V1的数据一致,表明皮层相互作用的净效应是增强简单细胞在偏好方向上的反应。这些结果表明,MFM非常适合解释简单细胞中的方向调谐,而标准RM则适用于复杂细胞。将RM分配给复杂细胞也避免了RM与皮层失活实验(在简单细胞上进行)以及方向调谐的空间频率依赖性(在简单细胞中发现)之间的冲突。由于方向调谐的V1细胞表现出从简单细胞到复杂细胞行为的连续体,MRM提供了对V1数据的最佳描述。
