Dynamical principles in neuroscience

Mikhail I. Rabinovich, Pablo Varona, Allen I. Selverston, and Henry D. I. Abarbanel

Rev. Mod. Phys. 78, 1213 – Published 14 November 2006

Abstract

Dynamical modeling of neural systems and brain functions has a history of success over the last half century. This includes, for example, the explanation and prediction of some features of neural rhythmic behaviors. Many interesting dynamical models of learning and memory based on physiological experiments have been suggested over the last two decades. Dynamical models even of consciousness now exist. Usually these models and results are based on traditional approaches and paradigms of nonlinear dynamics including dynamical chaos. Neural systems are, however, an unusual subject for nonlinear dynamics for several reasons: (i) Even the simplest neural network, with only a few neurons and synaptic connections, has an enormous number of variables and control parameters. These make neural systems adaptive and flexible, and are critical to their biological function. (ii) In contrast to traditional physical systems described by well-known basic principles, first principles governing the dynamics of neural systems are unknown. (iii) Many different neural systems exhibit similar dynamics despite having different architectures and different levels of complexity. (iv) The network architecture and connection strengths are usually not known in detail and therefore the dynamical analysis must, in some sense, be probabilistic. (v) Since nervous systems are able to organize behavior based on sensory inputs, the dynamical modeling of these systems has to explain the transformation of temporal information into combinatorial or combinatorial-temporal codes, and vice versa, for memory and recognition. In this review these problems are discussed in the context of addressing the stimulating questions: What can neuroscience learn from nonlinear dynamics, and what can nonlinear dynamics learn from neuroscience?

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DOI:https://doi.org/10.1103/RevModPhys.78.1213

Authors & Affiliations

Mikhail I. Rabinovich^*

Institute for Nonlinear Science, University of California, San Diego, 9500 Gilman Drive 0402, La Jolla, California 92093-0402, USA

Pablo Varona

GNB, Departamento de Ingeniería Informática, Universidad Autónoma de Madrid, 28049 Madrid, Spain and Institute for Nonlinear Science, University of California, San Diego, 9500 Gilman Drive 0402, La Jolla, California 92093-0402, USA

Allen I. Selverston

Institute for Nonlinear Science, University of California, San Diego, 9500 Gilman Drive 0402, La Jolla, California 92093-0402, USA

Henry D. I. Abarbanel

Department of Physics and Marine Physical Laboratory (Scripps Institution of Oceanography) and Institute for Nonlinear Science, University of California, San Diego, 9500 Gilman Drive 0402, La Jolla, California 92093-0402, USA

^*Electronic address: mrabinovich@ucsd.edu

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Vol. 78, Iss. 4 — October - December 2006

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Figure 1
(Color online) Illustration of the functional parts and electrical properties of neurons. (a) The neuron receives inputs through synapses on its dendritic tree. These inputs may or may not lead to the generation of a spike at the spike generation zone of the cell body that travels down the axon and triggers chemical transmitter release in the synapses of the axonal tree. If there is a spike, it leads to transmitter release and activates the synapses of a postsynaptic neuron and the process is repeated. (b) Simplified electrical circuit for a membrane patch of a neuron. The nonlinear ionic conductances are voltage dependent and correspond to different ion channels. This type of electrical circuit can be used to model isopotential single neurons. Detailed models that describe the morphology of the cells use several isopotential compartments implemented by these circuits coupled by a longitudinal resistance; these are called compartmental models. (c) A typical spike event is of the order of $100 mV$ in amplitude and $1 - 2 ms$ in duration, and is followed by a longer after-hyperpolarization period during which the neuron is less likely to generate another spike; this is called a refractory period.Reuse & Permissions
Figure 2
Six examples of limit cycle bifurcations observed in living and model neural systems [see 50; 45; 118; 133; 63; 187; 59; 94; 105; 186; 191; 34; 117; 268; 280].Reuse & Permissions
Figure 3
Examples of (a) the anatomical diversity of neurons, and (b) the single-neuron membrane voltage activity associated with them. (1) Lobster pyloric neuron; (2) neuron in rat midbrain; (3) cat thalamocortical relay neuron; (4) guinea pig inferior olivary neuron; (5) aplysia R15 neuron; (6) cat thalamic reticular neuron; (7) sepia giant axon; (8) rat thalamic reticular neuron; (9) mouse neocortical pyramidal neuron; (10) rat pituitary gonadotropin-releasing cell. In many cases, the behavior depends on the level of current injected into the cell as shown in (b). Modified from 318.Reuse & Permissions
Figure 4
Spike-timing-dependent synaptic plasticity observed in hippocampal neurons. Each data point represents the relative change in the amplitude of evoked postsynaptic current after repetitive application of presynaptic and postsynaptic spiking pairs ( $1 Hz$ for $60 s$ ) with fixed spike timing $Δ t$ , which is defined as the time interval between postsynaptic and presynaptic spiking within each pair. Long-term potentiation (LTP) and depression (LTD) windows are each fitted with an exponential function. Modified from 29.Reuse & Permissions
Figure 5
Example of a synchronization experiment. Top: The interspike intervals (ISIs) of the postsynaptic biological neuron. Bottom: The synaptic strength $g (t)$ . Presynaptic spikes with ISI of $255 ms$ were presented to a postsynaptic neuron with periodic oscillations at an ISI of $330 ms$ . Before coupling with the presynaptic spike generator, the biological neuron spikes tonically at its intrinsic ISI of $330 ms$ . Coupling was switched on with $g (t = 0) = 15 nS$ at time $6100 s$ . As one can see the postsynaptic neuron quickly synchronizes to the presynaptic spike generator (top panel, dashed line). The synaptic strength continuously adapts to the state of the postsynaptic neuron, effectively counteracting adaptation and other modulations of the system. This leads to a very precise and robust synchronization at a nonzero phase lag. The precision of the synchronization manifests itself in small fluctuations of the postsynaptic ISIs in the synchronized state. Robustness and phase lag cannot be seen directly. Modified from 214.Reuse & Permissions
Figure 6
(Color online) The presynaptic signal generator presents a periodic spike train with ISI of $T_{1}$ to a postsynaptic neuron with ISI of $T_{2}^{0}$ , before coupling. When neurons are coupled, $T_{2}^{0} \to T_{2}$ . We plot the ratio of these periods after coupling as a function of the ratio before coupling (a), for a synapse with constant $g$ and (b) for a synaptic connection $g (t)$ following the rule in the text. The enlarged domain of one-to-one synchronization in the latter case is quite clear and, as shown by the change in the error bar sizes, the synchronization is much better. This result persists when noise is added to the presynaptic signal and to the synaptic action (not shown). Modified from 214.Reuse & Permissions
Figure 7
Examples of invertebrate CPG microcircuits from arthropod, mollusk, and annelid preparations. All produce rhythmic spatiotemporal motor patterns when activated by nonpatterned input. The black dots represent chemical inhibitory synapses. Resistors represent electrical connections. Triangles are chemical excitatory synapses, and diodes are rectifying synapses (electrical synapses in which the current flows only in one direction). Individual neurons are identifiable from one preparation to another.Reuse & Permissions
Figure 8
(Color) Phase portrait of typical CPG output. The data were recorded in the pyloric CPG of the lobster stomatogastric ganglion. Each axis represents the firing rate of one of three pyloric neurons: LP, VD, and PD (see Fig. 7). (a) The orbit of the oscillating pyloric system is shown in blue and the average orbit is shown in red; (b) the same but with a hyperpolarizing dc current injected into the PD; (c) the difference between the averaged orbits; (d) time series of the membrane potentials of the three neurons. Figure provided by T. Nowotny, R. Levi, and A. Szücs.Reuse & Permissions
Figure 9
(Color online) Competition without winner in a model of the pyloric CPG. (a) Schematic diagram of the three-neuron network used for rate modeling. Black dots represent chemical inhibitory synapses with strengths given in nanoseconds $(X > 160)$ . (b) Phase portrait of the model: The limit cycle corresponding to the rhythmic activity is in the 2D simplex (326). (c) Robustness in the presence of noise: Noise introduced into the model shows no effect on the order of activation for each type of neuron. Figure provided by R. Huerta.Reuse & Permissions
Figure 10
(Color online) Three-dimensional projection of the many-dimensional phase portrait of a circuit with the same architecture as the one shown in Fig. 9, using Hodgkin-Huxley spiking-bursting neuron models.Reuse & Permissions
Figure 11
Artificial electrical coupling between two living chaotic PD cells of the stomatogastric ganglion of a crustacean can demonstrate both synchronous and asynchronous regimes of activity. In this case the artificial electrical synapse was built on top of the existing natural coupling between two PD cells. This shows different synchronization levels (a)–(d) as a function of the artificial coupling $g_{a}$ and a dc current $I$ injected in one of the cells. (a) With their natural coupling $g_{a} = 0$ the two cells are synchronized and display irregular spiking-bursting activity. (b) With an artificial electrical coupling that changes the sign of the current $g_{a} = - 200 nS$ , and thus compensates the natural coupling, the two neurons behave independently. (c) Increasing the negative conductance leads to a regularized antiphase spiking activity (by mimicking mutual inhibitory synapses). (d) With no artificial coupling but adding a dc current two neurons are synchronized, displaying tonic spiking activity. Modified from 85.Reuse & Permissions
Figure 12
(a) Schematic circuit diagram underlying MCN1 activation of the gastric mill rhythm of a crustacean. The circuit represents two phases of the rhythm, retraction (left) and protraction (right). Lighter lines represent inactive connections. LG, Int1, and DG are members of the gastric CPG and AB and PD are members of the pyloric CPG. Arrows represent functional transmission pathways from the MCN1 neuron. Bars are excitatory and dots are inhibitory. (b) The gastric mill cycle period; the timing of each cycle is a function of the pyloric rhythm frequency. With the pyloric rhythm turned off, the gastric rhythm cycles slowly (LG). Replacing the AB inhibition of Int1 with current into LG using a dynamic clamp reduces the gastric mill cycle period. Modified from 27.Reuse & Permissions
Figure 13
Coupling of two biological pyloric CPGs Pyl 1 and Pyl 2 by means of dynamic clamp artificial inhibitory synapses. The dynamic clamp is indicated by DCL. Reciprocal inhibitory coupling between the pacemaker groups AB and PD leads to antiphase synchronization while nonreciprocal coupling from the LPs produces in-phase synchronization. Figure provided by A. Szücs.Reuse & Permissions
Figure 14
Chaotic spiking-bursting activity of isolated CPG neutrons. Top panel: Chaotic membrane potential time series of a synaptically isolated LP neuron from the pyloric CPG. Bottom panel: State-space attractor reconstructed from the voltage measurements of the LP neuron shown in the top panel using delayed coordinates $[x (t), y (t), z (t)] = [V (t), V (t - T), V (t - 2 T)]$ . This attractor is characterized by two positive Lyapunov exponents. Modified from 235.Reuse & Permissions
Figure 15
Average bursting period of the model heartbeat CPG activity as a function of the inhibitory coupling $ϵ$ . Modified from 190.Reuse & Permissions
Figure 16
(Color online) Two possible codes for the activity of a single neuron. In a rate code, different inputs (A–D) are transformed into different output spiking rates. In a timing code, different inputs are transformed into different spiking sequences with precise timing.Reuse & Permissions
Figure 17
(Color online) Temporal dynamics of individual CA1 neurons of the hippocampus in response to “startling” events. Spike raster plots [(a)–(d) upper, seven repetitions each] and corresponding perievent histogram [(a)–(d) lower, bin width $500 ms$ ] for units exhibiting the four major types of firing changes observed: (a) transient increase, (b) prolonged increase, (c) transient decrease, (d) and prolonged decrease. From 178.Reuse & Permissions
Figure 18
(Color online) Classification, visualization, and dynamical decoding of CA1 ensemble representations of startle episodes by multiple-discriminant analysis (MDA) methods. (a) Firing patterns during rest, air blow, drop, and shake epochs are shown after being projected to a three-dimensional space obtained by using MDA for mouse A; MDA1–MDA3 denote the discriminant axes. Both training (dark symbols) and test data are shown. After the identification of startle types, a subsequent MDA is further used to resolve contexts (full vs empty symbols) in which the startle occurred for air-blow context (b) and for elevator drop (c). (d) Dynamical monitoring of ensemble activity and the spontaneous reactivation of startle representations. Three-dimensional subspace trajectories of the population activity in the two minutes after an air-blow startle in mouse A are shown. The initial response to an air blow (black line) is followed by two large spontaneous excursions (blue/dark and red/light lines), characterized by coplanar, geometrically similar lower-amplitude trajectories (directionality indicated by arrows). (e) The same trajectories as in (a) from a different 3D angle. (f) The timing ( $t_{1} = 31.6 s$ and $t_{2} = 54.8 s$ ) of the two reactivations (marked in blue/dark and red/light, respectively) after the actual startle (in black) $(t = 0 s)$ . The vertical axis indicates the air-blow classification probability. From 178.Reuse & Permissions
Figure 19
(Color online) Summary of possible scenarios for the transformation of codes, their functional implications, and the dynamical mechanism involved.Reuse & Permissions
Figure 20
(Color) Illustration of the transformation of temporal into spatial information. If a coincidence detection occurs, the local excitatory connections activate the neighbors of the active neuron (yellow neurons). Coincidence detection of input is now more probable in these activated neighborhoods than in other Kenyon cells (KCs). Which of the neighbors might fire a spike, however, depends on the activity of the projection neurons (PNs) in the next cycle. It might be a different neuron for active group B of PNs (upper branch) than for active group C (lower branch). In this way local sequences of active KCs form. These depend on the identity of active PNs (coincidence detection) as well as on the temporal order of their activity (activated neighborhoods). Modified from 213.Reuse & Permissions
Figure 21
(Color online) Reverberation can be the dynamical origin for working memory in minimal circuits. (a) Most neurons respond to excitatory stimuli [upward steps in the line below (c)] by spiking only as long as each stimulus lasts. (b) Very rare neurons are bistable: brief excitation leads to persistent spiking, always at the same rate; brief inhibition [downward steps in the line below (c)] can turn it off. (c) Multistable neurons persistently increase or decrease their spiking across a range of rates in response to repeated brief stimuli. (d) In the reverberatory network model of short-term memory discussed in the text, an excitatory stimulus (left arrow) leads to recursive activity in interconnected neurons. Inhibitory stimuli (bar on the right) can halt the activity. (e) 80 suggest that graded persistent activity in single neurons [as in (c)] might be triggered by a pulse of internal ${Ca}^{2 +}$ ions that enter through voltage-gated channels; ${Ca}^{2 +}$ then activates calcium-dependent nonspecific cation (CAN) channels, through which an inward current (largely comprising ${Na}^{+}$ ions) enters, persistently exciting the neuron. The positive feedback loop (broken arrows) may include the activity of many ionic channels. Modified from 56.Reuse & Permissions
Figure 22
Temporal responses of self-recurrent units: Near-saddle-node bifurcation with $a = 11.11$ , $b = - 7.9$ (center panels). Increased bias, $b = - 3.0$ (left panels). Decreased bias $b = - 9.0$ (right panels). Modified from 206.Reuse & Permissions
Figure 23
Hallucinations generated by LSD are an example of a dynamical representation of the internal activity of the visual cortex without an input stimulus. Figure shows examples of (a) funnel and (b) spiral hallucinations. Modified from 38.Reuse & Permissions
Figure 24
(Color online) Dual sensory network dynamics. Top panels: Schematic representation of the dual role of a single statocyst, the gravity sensory organ of the mollusk Clione. During normal swimming, a stonelike structure, the statolith, hits the mechanoreceptor neurons that react to this excitation. In Clione’s hunting behavior, the statocyst receptors receive additional excitation from the cerebral hunting neuron (H) which generates a winnerless competition among them. Bottom panels: Chaotic sequential switching displayed by the activity of the statocyst during hunting mode in a model of a six-receptor network. This panel displays the time intervals in which each neuron is active $(a_{i} > 0.03)$ . Each neuron is represented by a different color. The dotted rectangles indicate the activation-sequence locks among units that are active at a given time interval within each network for time windows in which all six neurons are active.Reuse & Permissions
Figure 25
(Color online) Clione swimming trajectories in different situations. (a) Three-dimensional trajectory of routine swimming. Here and in the following figures, different colors (gray tones) are used to emphasize the three-dimensional perception of the trajectories and change according to the $x$ axis. The indicated time $t$ is the duration of the trajectory. (b) Swimming trajectory of Clione with the statocysts surgically removed. (c) Trajectory of swimming during hunting behavior evoked by the contact with the prey. (d) Trajectory of swimming after immersion of Clione in a solution that pharmacologically evokes hunting. Modified from 174.Reuse & Permissions
Figure 26
(Color online) Irregular switching in a network of six statocyst receptors. Traces represent the instantaneous spiking rate of each neuron $a_{i}$ [neurons 1,2,3 are shown in (a), neurons 4,5,6 in (b)]. Note that after a neuron is silent for a while, its activity reappears with the same sequence relative to the others (see arrows, and Fig. 24). (c) A projection of the phase portrait of the strange attractor in 3D space; see model (15).Reuse & Permissions
Figure 27
(Color online) Chaotic dynamics increases information transmission in IO models. Top panel: Largest Lyapunov exponent as a function of the electrical coupling strength $g_{c}$ for different IO networks of nonidentical cells. Bottom panel: Network average mutual information per spike as a function of $g_{c}$ . Modified from 253.Reuse & Permissions
Figure 28
Dynamical synapses imply that synaptic transmission depends on previous presynaptic activity. This shows the average postsynaptic activity generated in response to a presynaptic spike train (bottom trace) in a pyramidal neuron (top trace) and in a model of a depressing synapse (middle trace). Postsynaptic potential in the model is computed using a passive membrane mechanism $τ_{m} (d V ∕ d t) = - V + R_{i} I_{syn} (t)$ , where $R_{i}$ is the input resistance. Modified from 299.Reuse & Permissions
Figure 29
Example of recovery of hidden information in neural channels. A presynaptic cell receives specified input and connects to a postsynaptic cell through a dynamical synapse. Top panel: the time series of synaptic input to the presynaptic cell $J_{1} (t)$ ; middle panel: the membrane potential of the first bursting neuron $X_{1} (t)$ ; bottom panel: the membrane potential of the second bursting neuron $X_{2} (t)$ . Note that features of the input hidden in the response $X_{1} (t)$ are recovered in the response following a dynamical synapse $X_{2} (t)$ (note hyperpolarization regions for $X_{2}$ ). Modified from 81.Reuse & Permissions
Figure 30
An example of binding showing dependence of synchrony on transparency conditions and receptive field (RF) configuration in the cat visual cortex. (a) Stimulus configuration. (b) Synchronization between neurons with nonoverlapping RFs and similar directional preferences recorded from areas A18 and PMLS of the cat visual cortex. Left, RF constellation and tuning curves; right, cross correlograms for responses to a nontransparent (left) and transparent plaid (right) moving in the cells’ preferred direction. Grating luminance was asymmetric to enhance perceptual transparency. Small dark correlograms are shift predictors. (c) Synchronization between neurons with different direction preferences recorded from A18 (polar and RF plots, left). Top, correlograms of responses evoked by a nontransparent (left) and a transparent (right) plaid moving in a direction intermediate to the cells’ preferences. Bottom, correlograms of responses evoked by a nontransparent plaid with reversed contrast conditions (left), and by a surface defined by coherent motion of intersections (right). Scale on polar plots: discharge rate in spikes per second. Scale on correlograms: abscissa, shift interval in ms, bin width $1 ms$ ; ordinate, number of coincidences per trial, normalized. Modified from 47.Reuse & Permissions
Figure 31
(Color online) Spontaneous spatiotemporal patterns observed in the neocortex in vitro under the action of carbachol. Images composed of optical signals recorded by eight detectors arranged horizontally. The optical signal from each detector was normalized to the maximum on that detector during that period and normalized values were assigned colors according to a linear color scale (at the top right). The traces above images 2 and 5 are optical signals from two optical detectors labeled with this color scale. The $x$ direction of the images represents time $(12 s)$ and the $y$ direction of each image represents $2.6 mm$ of space in cortical tissue. Note also that the first spike had a high amplitude but propagated more slowly in the tissue. Modified from 25.Reuse & Permissions
Figure 32
(Color online) Sequential changing of cortical modes in the turtle visual cortex. Comparison between the spatial organization of the cortical activity in the turtle visual system and the normal modes of a rectangular membrane (drum). From 260.Reuse & Permissions
Figure 33
(Color) Space representation of cortical responses in the turtle visual cortex to left, center, and right stimuli. From 77.Reuse & Permissions
Figure 34
(Color online) Relation between the spiking activity of a single neuron and the population state of cortical networks. (a) From bottom to top: stimulus time course; correlation coefficient of the instantaneous snapshot of population activity with the spatial pattern obtained by averaging over all patterns observed at the times corresponding to spikes evoked by the optimal orientation of the stimulus called the neuron’s preferred cortical state (PCS) pattern; observed spike train of evoked activity with the optimal orientation for that neuron; reconstructed spike train. The similarity between the reconstructed and observed spike trains is evident. Also, strong upswings in the values of correlation coefficients are evident each time the neuron emits bursts of action potentials. Every strong burst is followed by a marked downswing in the values of the correlation coefficients. (b) The same as (a), but for a spontaneous activity recording session from the same neuron (eyes closed). (c) The neuron’s PCS, calculated during evoked activity and used to obtain both (a) and (b). (d) The cortical state corresponding to spontaneous action potentials. The two patterns are nearly identical (correlation coefficient 0.81). (e) and (f) Another example of the similarity between the neuron’s PCS (e) and the cortical state corresponding to spontaneous activity (f) from a different cat obtained with the high-resolution imaging system (correlation coefficient 0.74). Modified from 298.Reuse & Permissions
Figure 35
Connection function $ω (x, y)$ , centered at the center of the domain. Modified from 162.Reuse & Permissions
Figure 36
Six-bump stable solution of the model (21, 22, 23): $b = 0.45$ , $τ = 0.1$ , $th = 1.5$ . Modified from 162.Reuse & Permissions
Figure 37
Sequence of pools of excitatory neurons, connected in a feedforward way by so-called divergent and convergent connections. The network is called a synfire chain if it supports the propagation of synchronous spike patterns. Modified from 109.Reuse & Permissions
Figure 38
Propagation of firing activity in synfire chains. (a) Stable and (b) unstable propagation of synchronous spiking in a model of cortical networks. Raster displays of propagating spike volley along fully connected synfire chain. Panels show the spikes in ten successive groups of 100 neurons each (synaptic delays arbitrarily set to $5 ms$ ). Initial spike volley (not shown) was fully synchronized, containing (a) 50 or (b) 48 spikes. Modified from 73.Reuse & Permissions
Figure 39
(Color online) Illustration of WLC dynamics. Top panel: Phase portrait corresponding to the autonomous WLC dynamics of a three-dimensional case. Bottom panel: Projection of a nine-dimensional heteroclinic orbit of three inhibitory coupled FitzHugh-Nagumo spiking neurons in a three-dimensional space (the variables $ξ_{1}$ , $ξ_{3}$ , $ξ_{3}$ are linear combinations of the actual phase variables of the system). From 234.Reuse & Permissions
Figure 40
Transformation of the identity spatial input into spatiotemporal output based on the intrinsic sequential dynamics of a neural ensemble with WLC.Reuse & Permissions
Figure 41
Spatiotemporal patterns generated by a network of nine FitzHugh-Nagumo neurons with inhibitory connections. The left and right panels correspond to two different stimuli. From 234.Reuse & Permissions
Figure 42
(Color) Result of simulating a network of 100 neurons subject to the learning rule $g (a_{i}, a_{j}) = a_{i} a_{j} [10 \tanh (a_{j} - a_{i}) + 1]$ . The activity of representative neurons in this network is shown in different colors. The system starts from random initial conditions for the connections. The noise level is $η = 0.01$ . For simplicity, the switching activity of only four of the 100 neurons is shown.Reuse & Permissions
Figure 43
(Color online) Example of WLC dynamics entrained in a network by a local learning rule. In isolation, the four HH neurons in the network are rebound bursters, i.e., they fire a brief burst of spikes after being strongly inhibited. The all-to-all inhibitory synapses in the small network are governed by a STDP learning rule which strengthens the synapse for positive time delays between postsynaptic and presynaptic activity and weakens it otherwise. Such STDP of inhibitory synapses has been observed in the entorhinal cortex of rats (121). (a) Before entrainment the neurons just follow the input signal of periodic current pulses. (b) The resulting bursts strengthen the forward synapses corresponding to the input sequence making them eventually strong enough to cause rebound bursts. (c) After entrainment activating any one of the neurons leads to an infinite repetition of the trained sequence carried by the successive rebound bursts of the neurons.Reuse & Permissions
Figure 44
A stable open heteroclinic sequence in a neural circuit with WLC. $W_{s_{i}}$ is a stable manifold of the $i th$ saddle fixed point (heavy dots). The trajectories in the vicinity of the SHS represent sequences with different timings. The time intervals between switches is proportional to $T \sim ∣ \ln η ∣ ∕ λ_{u}$ , where $λ_{u}$ is a positive Lyapunov exponent that characterizes the one-dimensional unstable separatrices of the saddle points (285). Modified from 8.Reuse & Permissions
Figure 45
(Color online) Time series of the activity of a WLC network during ten trials (only 20 neurons are shown): simulations of each trial were started from a different random initial condition. In this plot each neuron is represented by a different color and its level of activity by the saturation of the color. From 8.Reuse & Permissions
Figure 46
(Color) Transient AL dynamics. Top panel: Trajectories of the antennal lobe activity during poststimulus relaxation in one bee. Modified from 102. Bottom panel: Visualization of trajectories representing the response of a PN population in a locust AL over time. Time-slice points were calculated from 110 PN responses to four concentrations (0.01, 0.05, 0.1, 1) of three odors, projected onto three dimensions using locally linear embedding, an algorithm that computes low-dimensional, neighborhood-preserving embeddings of high-dimensional inputs (247). Modified from 286.Reuse & Permissions
Figure 47
(Color online) HVC songbird patterns. Spike raster plot of ten HVC(RA) neurons recorded in one bird during singing. Each row of tick marks shows spikes generated during one rendition of the song or call; roughly ten renditions are shown for each neuron. Modified from 122.Reuse & Permissions
Figure 48
Amplitudes of principal neurons during the memory retrieval phase in a two-layer dynamical model of sequential spatial memory. (a) Periodic retrieval, two different test patterns presented; (b) aperiodic retrieval with modulated inhibition (see text). Modified from 257.Reuse & Permissions
Figure 49
(Color online) Three-dimensional projections of simulations of random networks of 200 neurons. For illustrative purposes we show three types of dynamics that can be generated by a random network: (top) chaos, (middle) limit cycle (both in the areas of parameter space that are close to balanced), and (bottom) transient dynamics (far from balanced).Reuse & Permissions
Figure 50
(Color) Spatiotemporal patterns of coordinated rhythms induced by stimuli in a model of the inferior olive. Several structures with different frequencies can coexist simultaneously in a commensurate representation of the spiking frequencies when several stimuli are present. Incommensurate stimuli are introduced in the form of current injections in different clusters of the network. (Panels on the right show the positions of the input clusters.) These current injections induce different spiking frequencies in the neurons. Colors in these panels represent different current injections, and thus different spiking frequencies in the input clusters. Top row shows the activity of a network with two different input clusters. Bottom row shows the activity of a network with 25 different input clusters. Sequences develop in time from left to right. Regions with the same color have synchronous behavior. Color bar maps the membrane potential. Red corresponds to spiking neurons ( $- 45 mV$ is above the firing threshold in the model). Dark blue means hyperpolarized activity. Bottom panel shows the activity of a single neuron with subthreshold oscillations and spiking activity. Modified from 306.Reuse & Permissions
Figure 51
Illustration of the learned sequential switching in a recurrent network with WLC dynamics: Thin lines, possible learned sequences; thick line, sequential switching chosen online by the dynamical stimulus.Reuse & Permissions
Figure 52
A schematic representation of the mammalian cerebellar circuit. Arrows indicate the direction of transmission across each synapse. Sources of mossy fibers: Ba, basket cell; BR, brush cell; cf, climbing fiber; CN, cerebellar nuclei; Go, Golgi cell; IO, inferior olive; mf, mossy fiber; pf, parallel fiber; PN, pontine nuclei; sb and smb, spiny and smooth branches of P cell dendrites, respectively; PC, Purkinje cell; bat, basket cell terminal; pcc, P cell collateral; no, nucleo-olivary pathway; nc, collateral of nuclear relay cell. Modified from 316.Reuse & Permissions

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