Robust associative learning is sufficient to explain structural and dynamical properties of local cortical circuits

Zhang, Danke; Zhang, Chi; Stepanyants, Armen

doi:10.1101/320432

Cited by 9 publications

(38 citation statements)

References 43 publications

(20 reference statements)

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“…On one hand, (a) there exist independent empirical evidences that excitatory to pairs is overexpressedcompared to random network -in rat's visual (Song et al, 2005) and somatosensory (Perin et al, 2011) cortex. In a recent theoretical study this overexpression is explained as a consequence of maximizing capacity of the associative memory (Zhang et al, 2019); these suggest that the emergence of excitatory to pairs is not an accidental observation. On the other hand, (b) we have shown that whenever the background network is sparse, strong negative triple-wise is the signature of excitatory to pairs; and even simultaneous presence of excitation and inhibition does not disturb this conclusion.…”

Section: Discussionmentioning

confidence: 93%

Uncovering Network Architecture Using an Exact Statistical Input-Output Relation of a Neuron Model

Shomali

Ahmadabadi

Rasuli

et al. 2018

Preprint

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An appealing challenge in Neuroscience is to identify network architecture from neural activity. A key requirement is the knowledge of statistical input-output relation of single neurons in vivo. Using a recent exact solution of spike-timing for leaky integrate-and-fire neurons under noisy inputs balanced near threshold, we construct a unified framework that links synaptic inputs, spiking nonlinearity, and network architecture, with statistics of population activity. The framework predicts structured higher-order interactions of neurons receiving common inputs under different architectures: It unveils two network motifs behind sparse activity reported in visual neurons. Comparing model's prediction with monkey's V1 neurons, we found excitatory inputs to pairs explain the sparse activity characterized by negative triple-wise interactions, ruling out shared inhibition. While the model predicts variation in the structured activity according to local circuitries, we show strong negative interactions are in general a signature of excitatory inputs to neuron pairs, whenever background activity is sparse.1 Keywords network architecture, sparse activity, common inputs, higher-order interactions, leaky integrateand-fire neuron model, threshold regime, input-output relation, triple-wise interactions, spontaneous activity

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Section: Discussionmentioning

confidence: 93%

Uncovering Network Architecture Using an Exact Statistical Input-Output Relation of a Neuron Model

Shomali

Ahmadabadi

Rasuli

et al. 2018

Preprint

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“…Second, as synaptic connectivity of neurons changes during learning (3), it is not unreasonable to expect that the requirement of reliable memory retrieval is reflected in the properties of network connectivity and, consequently, the activity of neurons in the brain. Interestingly, local neural networks in the mammalian cortical areas have many common features of connectivity and network activity (18). We show that these network properties in the model emerge all at once during reliable memory storage.…”

Section: Introductionmentioning

confidence: 80%

“…The replica method (32,33) provides an analytical solution in the N → ∞ limit. Though neuron networks in the brain are finite, they are thought to be large enough to have many properties that are well described by this limit (18). More importantly, the analytical solution of the replica method reveals the dependence of the results on combinations of network parameters that can be explored with other methods.…”

Section: B Solutions Of the Modelmentioning

confidence: 99%

“…McCulloch and Pitts neurons (17) loaded to capacity with associative memory sequences (18) in the presence of errors and noise. First, we show that there is a tradeoff between the capacity and reliability of stored sequences which is controlled by the levels of errors and noise present during learning.…”

Section: Introductionmentioning

confidence: 99%

“…Rubin et al (10) considered presynaptic and intrinsic noise and showed that the balance of inhibitory and excitatory currents emerges at capacity. Zhang et al (18) showed that many structural and dynamical properties of local cortical networks emerge in associative networks robustly loaded to capacity. These studies significantly differ from the present work both in terms of the models and the results.…”

Section: Introductionmentioning

confidence: 99%

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Noise in neurons and synapses enables reliable associative memory storage in local cortical circuits

Zhang

Stepanyants

2019

Preprint

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Neural networks in the brain can function reliably despite various sources of errors and noise present at every step of signal transmission. These sources include errors in the presynaptic inputs to the neurons, noise in synaptic transmission, and fluctuations in the neurons' postsynaptic potentials. Collectively they lead to errors in the neurons' outputs which are, in turn, injected into the network. Does unreliable network activity hinder fundamental functions of the brain, such as learning and memory retrieval? To explore this question, this article examines the effects of errors and noise on properties of biologically constrained networks of inhibitory and excitatory neurons involved in associative sequence learning. The associative learning problem is solved analytically and numerically, and it is also shown how memory sequences can be loaded into the network with a more biologically plausible perceptron-type learning rule. Interestingly, the results reveal that errors and noise during learning increase the probability of memory recall. There is a tradeoff 5 the network in an online manner and show that this biologically more plausible method leads to similar network properties as those obtained with the nonlinear optimization and replica methods.Finally, we examine the properties of networks of heterogeneous neurons and make predictions regarding network connectivity. The details of the replica calculation and numerical solutions of the associative memory storage model are provided in SI. RESULTS A. Network model of associative memory storage in the presence of errors and noiseWe modeled associative sequence learning by a local (~100 μm in size), all-to-all potentially (structurally) connected (29, 30) cortical network. The model network consisted of Ninh inhibitory and (N − Ninh) excitatory McCulloch and Pitts neurons (17) ( Figure 1A) and was faced with a task of learning a sequence of consecutive network states, 1 2 1 ... m X X X + →→ , in which X  is a binary vector representing target activities of all neurons at a time step μ, and the ratio m/N is referred to as the memory load. During learning, individual neurons had to independently learn to associate inputs they received from the network with the corresponding target outputs derived from the associative memory sequence. The neurons learned these input-output associations by adjusting the weights of their input connections, ij J (weight of connection from neuron j to neuron i). In contrast to previous studies, we accounted for the fact that learning in the brain is accompanied by several sources of errors and noise. Within the model, these sources are divided into three categories (orange lightning signs in Figure 1A): (1) spiking errors, or errors in X  , (2) synaptic noise, or noise in ij J , and (3) intrinsic noise, which combines all other sources of noise affecting the neurons' postsynaptic potentials. The last category includes background synaptic activity and the stochasticity of ion channels. In the model, this category is equivalent to n...

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Computing and optimizing over all fixed-points of discrete systems on large networks

Riehl

Zimmerman

Singh

et al. 2020

J. R. Soc. Interface.

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Equilibria, or fixed points, play an important role in dynamical systems across various domains, yet finding them can be computationally challenging. Here, we show how to efficiently compute all equilibrium points of discrete-valued, discrete-time systems on sparse networks. Using graph partitioning, we recursively decompose the original problem into a set of smaller, simpler problems that are easy to compute, and whose solutions combine to yield the full equilibrium set. This makes it possible to find the fixed points of systems on arbitrarily large networks meeting certain criteria. This approach can also be used without computing the full equilibrium set, which may grow very large in some cases. For example, one can use this method to check the existence and total number of equilibria, or to find equilibria that are optimal with respect to a given cost function. We demonstrate the potential capabilities of this approach with examples in two scientific domains: computing the number of fixed points in brain networks and finding the minimal energy conformations of lattice-based protein folding models.

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Robust associative learning is sufficient to explain structural and dynamical properties of local cortical circuits

Cited by 9 publications

References 43 publications

Uncovering Network Architecture Using an Exact Statistical Input-Output Relation of a Neuron Model

Uncovering Network Architecture Using an Exact Statistical Input-Output Relation of a Neuron Model

Noise in neurons and synapses enables reliable associative memory storage in local cortical circuits

Computing and optimizing over all fixed-points of discrete systems on large networks

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