Extracellular Neuronal Recordings Research Articles

Integration of vestibular and hindlimb inputs by vestibular nucleus neurons: multisensory influences on postural control.

We recently demonstrated in decerebrate and conscious cat preparations that hindlimb somatosensory inputs converge with vestibular afferent input onto neurons in multiple central nervous system (CNS) locations that participate in balance control. Although it is known that head position and limb state modulate postural reflexes, presumably through vestibulospinal and reticulospinal pathways, the combined influence of the two inputs on the activity of neurons in these brainstem regions is unknown. In the present study, we evaluated the responses of vestibular nucleus (VN) neurons to vestibular and hindlimb stimuli delivered separately and together in conscious cats. We hypothesized that VN neuronal firing during activation of vestibular and limb proprioceptive inputs would be well fit by an additive model. Extracellular single-unit recordings were obtained from VN neurons. Sinusoidal whole body rotation in the roll plane was used as the search stimulus. Units responding to the search stimulus were tested for their responses to 10° ramp-and-hold roll body rotation, 60° extension hindlimb movement, and both movements delivered simultaneously. Composite response histograms were fit by a model of low- and high-pass filtered limb and body position signals using least squares nonlinear regression. We found that VN neuronal activity during combined vestibular and hindlimb proprioceptive stimulation in the conscious cat is well fit by a simple additive model for signals with similar temporal dynamics. The mean R2 value for goodness of fit across all units was 0.74 ± 0.17. It is likely that VN neurons that exhibit these integrative properties participate in adjusting vestibulospinal outflow in response to limb state.NEW & NOTEWORTHY Vestibular nucleus neurons receive convergent information from hindlimb somatosensory inputs and vestibular inputs. In this study, extracellular single-unit recordings of vestibular nucleus neurons during conditions of passively applied limb movement, passive whole body rotations, and combined stimulation were well fit by an additive model. The integration of hindlimb somatosensory inputs with vestibular inputs at the first stage of vestibular processing suggests that vestibular nucleus neurons account for limb position in determining vestibulospinal responses to postural perturbations.

Laryngeal Adductor Reflex Motor Bursts Rapidly Oscillate in the Cat

The laryngeal adductor reflex (LAR) is a protective behavior induced by stimulation of upper airway afferents. Laryngeal afferent information reaches interneurons in the medulla via the superior laryngeal nerve (SLN). Expiratory laryngeal motoneurons (ELMs) are subsequently excited causing contraction of the thyroarytenoid (TA) and posterior cricoarytenoid (PCA) muscles. The LAR consists of a short latency (~10 ms), short duration (~10 ms) burst (R1) and a longer latency (~40ms) burst (R2) in laryngeal electromyogram (EMG) activity. We have shown that R1 LAR magnitude undergoes frequency‐dependent depression in response to electrical stimulation (eStim) of the SLN. Based on preliminary observations, we hypothesized that the R1 component of the LAR induced by SLN eStim oscillates. In anesthetized, spontaneously breathing cats (n=12: 7 males, 5 females), we recorded EMG activity from the TA bilaterally and the PCA unilaterally. The SLN was electrically stimulated at 2 or 20 Hz to evoke TA LAR ipsilateral to stimulation (iTA). No sex differences in TA or PCA LAR EMG magnitude were observed. Consistent with previous findings, TA LAR magnitude differed with breathing phase; normalized iTA LAR magnitude was 10% larger during expiration compared to inspiration. TA LAR contralateral to stimulation (cTA) and ipsilateral PCA LAR magnitudes were not breathing phase dependent. TA and PCA LAR EMG oscillations were highly variable across animals (range: 244 to 1140 Hz). Mean iTA EMG frequency was decreased at 20 Hz (2 to 20 Hz: 616 to 518 Hz, p=0.05). Mean cTA periodicity trended down at 20 Hz (2 to 20 Hz cTA: 647 to 531 Hz, p=0.07). In separate decerebrate, paralyzed cats (n=13), extracellular recordings of neurons in the ventral respiratory column (VRC) with multiple electrode arrays were conducted. Peristimulus time histograms provided evidence that ELMs oscillated at frequencies following SLN eStim similar to the lower range of periodicities in TA EMGs in unparalyzed animals. A subset of neurons recorded in the VRC were excited or inhibited by SLN eStim at short latencies. Spike train analysis suggested that ELM oscillations could be accounted for by synaptic inhibition and excitation from laryngeal‐responsive VRC inspiratory, expiratory, and non‐breathing modulated neurons. We conclude that the LAR is temporally regulated by a complex, anatomically distributed brainstem network that is capable of strong synchrony in response to stimulation of laryngeal afferents. We speculate that the function of this laryngeal‐responsive network is to exert tight regulatory control over LAR patterning.Support or Funding InformationSupported by NIH HL131716 and 3OT2OD023854

Neurons in the rat superior colliculus translate visual threat into autonomic responses via a relay in the rostral ventromedial medulla

The superior colliculus (SC) is a sensory integration hub in the dorsal brainstem where multimodal information is combined and, depending on the saliency of the competing sensory inputs, appropriate motor commands and supportive autonomic changes initiated. In rodents, the SC is indispensable for initiating behavioral responses to stereotypical visual stimuli that resemble approaching objects, such as looming (an expanding overhead black circle). Here we report that presentation of overhead looming or naturalistic stimuli drove acute surges in blood pressure in telemetered conscious rats, an effect that was replicated by optogenetic stimulation of the deep SC (dSC). dSC stimulation also evoked increases in respiratory rate and tail vasoconstriction in the absence of detectable anxiety‐like behaviors and continued to exert excitatory effects on heart rate, respiratory rate, and sympathetic nerve activity under urethane anesthesia. The objective of the current study was to identify the central pathways responsible for mediating these physiological effects.Anterograde labeling of dSC neurons revealed a previously uncharacterized axonal projections to brainstem cell groups associated with arousal and autonomic control, including the locus coeruleus, A5 group and, most extensively, neurons within a region that spanned the medullary gigantocellular and raphe cell groups, collectively called the rostral ventromedial medulla (RVMM). Optogenetic stimulation of dSC terminals within the RVMM recapitulated some of the sympathetic and respiratory effects evoked by dSC stimulation, and optogenetic dSC activation evoked powerful excitatory effects on extracellular recordings of putative RVMM sympathetic premotor neurons, suggesting that elements of the physiological response dSC stimulation are mediated by direct activation of medullary autonomic neurons.To investigate the contribution of environmental stimuli to the excitability of this pathway we conducted single‐unit recordings of SC neuronal responses to visual and acoustic stimuli using high‐density silicon probes. In addition to responding to stereotypical audio‐visual looming stimuli, we report the presence of SC neurons with higher‐order visual capabilities relating to object detection that differ by subregion and are several orders of magnitude more complex than previously recognized. These tuning properties were also found in subpopulations of opto‐tagged SC neurons that project to the RVMM. Our data suggest that the SC is not only capable of nuanced object recognition, but can translate naturalistic visual cues into fast‐acting autonomic changes via direct medullary projectionsSupport or Funding InformationResearch was supported by the NHMRC and Hillcrest Foundation

Abstract TP111: TRPM2 is a Therapeutic Target for Reversal of Stroke-Induced Dementia-Like Symptoms

Introduction: Cognitive impairments and memory loss are common after stroke, with an emerging awareness of a high risk of conversion to post-stroke dementia. It is increasingly clear that in addition to neuronal injury following cerebral ischemia, impaired functional networks contribute to long-term functional deficits. Synaptic plasticity (long term potentiation; LTP) is the leading cellular model of learning and memory. Thus, we utilize electrophysiological recordings of hippocampal LTP as an indicator of network health following ischemia in combination with neurobehavioral assessments of memory function. TRPM2 channels are oxidative stress sensitive ion channels that have been implicated in ischemic injury. Hypothesis: Inhibition of TRPM2 channels reverse stroke-induced cognitive deficits. Methods: Extracellular field recordings of CA1 neurons were performed in acute hippocampal slices prepared 30 days after recovery from transient MCAO (45 min) in adult (6-8 week) mice. A behavioral fear conditioning paradigm was used to evaluate contextual memory 30 days after MCAO. Slices or mice were treated with our newly developed peptide inhibitor of TRPM2, termed tatM2NX. Results: Recordings obtained in brain slices 30 days after MCAO exhibited near complete loss of LTP; 161±9%, n=6 in sham compared to 115±4%, n=7 30 days after MCAO in the ipsilateral hippocampus. Similar deficit in LTP observed in the contralateral hippocampus. Remarkably, iv injection of 20 mg/kg tatM2NX on day 29 after MCAO reversed MCAO-induced loss of LTP when recorded on day 30, recovering to 175±9% (n=3). Memory function, measured using contextual fear conditioning, was consistent with our LTP findings. MCAO decreased freezing behavior, indicating lack of memory (62±5% in sham mice (n=5) and 24±3% in MCAO mice, n=4). This was reversed in MCAO mice given tatM2NX (20 mg/kg iv injection 24 hr before testing) on day 29 post MCAO, increasing freezing to 73±12% (n=3). Conclusion: These data indicate that our new TRPM2 channel inhibitor, tatM2NX, restores synaptic plasticity and memory function after experimental stroke. Therefore, inhibition of TRPM2 channels at chronic timepoints following ischemia may represent a novel strategy to improve functional recovery following stroke.

Phase-dependent modulation of cortical and thalamic sensory responses during spike-and-wave discharges.

The neuronal underpinnings of impaired consciousness during absence seizures remain largely unknown. Spike-and-wave (SW) activity associated with absences imposes two extremely different states in cortical neurons, which transition from suprathreshold synaptic depolarizations during spike phases to membrane hyperpolarization and electrical silence during wave phases. To investigate whether this rhythmic alternation of neuronal states affects the processing of sensory information during seizures, we examined cortical and thalamic responsiveness to brief sensory stimuli in the different phases of the epileptic cycle. Electrocorticographic (ECoG) monitoring from the primary somatosensory cortex combined with intracellular recordings of subjacent pyramidal neurons, or extracellular recordings of somatosensory thalamic neurons, were performed in the Genetic Absence Epilepsy Rat From Strasbourg. Sensory stimuli consisted of pulses of compressed air applied to the contralateral whiskers. Whisker stimuli delivered during spike phases evoked smaller depolarizing synaptic potentials and fewer action potentials in cortical neurons compared to stimuli occurring during wave phases. This spike-related attenuation of cortical responsiveness was accompanied by a reduced neuronal membrane resistance, likely due to the large increase in synaptic conductance. Sensory-evoked firing in thalamocortical neurons was also decreased during ECoG spikes as compared to wave phases, indicating that time-to-time changes in the thalamocortical volley may also contribute to the variability of cortical responses during seizures. These findings demonstrate that thalamocortical sensory processing during absence seizures is nonstationary and strongly suggest that the cortical impact of a given environmental stimulus is conditioned by its exact timing relative to the SW cycle. The lack of stability of thalamic and cortical responses along seizures may contribute to impaired conscious sensory perception during absences.

Microneurosurgical techniques and perioperative strategies utilized to optimize experimental supracollicular decerebration in rats.

Decerebration permits neurophysiological experimentation absent the confounding effects of anesthesia. Use of the unanesthetized decerebrate preparation in vivo offers several advantages compared with recordings performed in reduced slice preparations, providing the capacity to perform extracellular and intracellular neuronal recordings in the presence of an intact brainstem network. The decerebration procedure typically generates variable degrees of blood loss, which often compromises the hemodynamic stability of the preparation. We describe our microsurgical techniques and discuss microsurgical pearls utilized in order to consistently generate normotensive supracollicularly decerebrate preparations of the rat, exhibiting an augmenting pattern of phrenic nerve discharge. In brief, we perform bilateral ligation of the internal carotid arteries, biparietal craniectomies, securing of the superior sagittal sinus to the overlying strip of bone, removal of the median strip of bone overlying the superior sagittal sinus, supracollicular decerebrative encephalotomy, removal of the cerebral hemispheres, and packing of the anterior and middle cranial fossae with thrombin soaked gelfoam sponges. Hypothermia and potent inhalational anesthesia ensure neuroprotection during postdecerebrative neurogenic shock. Advantages of our approach include a bloodless and fast operation with a nil percent rate of operative mortality. We allow animal arterial pressure to recover gradually in parallel with gentle weaning of anesthesia following decerebration, performed contemporaneously with the provision of the neuromuscular antagonist vecuronium. Anesthetic weaning and institution of vecuronium should be contemporaneous, coordinate, gentle, gradual, and guided by the spontaneous recovery of the arterial blood pressure. We describe our microsurgical techniques and perioperative management strategy designed to achieve decerebration and accordingly survey the literature on techniques used across several studies in achieving these goals.

Postpartum changes in affect-related behavior and VTA dopamine neuron activity in rats

The onset of motherhood is accompanied by alterations in emotional and affective behaviors. Many new mothers experience transient and mild depressive symptoms that typically resolve spontaneously (i.e. postpartum blues) but increase the risk for postpartum depression (PPD). There is little data regarding the neural adaptations occurring in response to parturition and shortly after birth that may be associated with these affective changes. Although the dopamine (DA) system is involved in affect, maternal motivation and PPD, little is known about postpartum DA function. We compared affective behavior in virgin and postpartum adult female rats at early and late time points. In vivo extracellular recordings of VTA DA neurons were performed to evaluate 3 parameters: number of active DA neurons (i.e. population activity), firing rate, and firing pattern. Compared with virgins, postpartum rats exhibited increased anxiety-like behavior in the elevated plus maze at 1-day postpartum; reduced social motivation at 1- and 3-days postpartum, reduced anxiety-like behavior in the novelty suppressed feeding test throughout the first week postpartum and increased forced swim test immobility at 1-day postpartum. 1- and 3-day postpartum females exhibited attenuated VTA population activity without changes in firing rate or pattern. None of these effects were observed in late postpartum females when compared with virgins. These data suggest that parturition induces time-dependent changes in a subset of affect-related behaviors and DA function during the postpartum period in rodents, with early postpartum females exhibiting depression-related phenotypes (i.e. low social motivation, higher immobility, blunted DA activity).

Contribution of Corticotropin-Releasing Factor Receptor 1 (CRF1) to Serotonin Receptor 5-HT2CR Function in Amygdala Neurons in a Neuropathic Pain Model.

The amygdala plays a key role in emotional-affective aspects of pain and in pain modulation. The central nucleus (CeA) serves major amygdala output functions related to emotional-affective behaviors and pain modulation. Our previous studies implicated the corticotropin-releasing factor (CRF) system in amygdala plasticity and pain behaviors in an arthritis model. We also showed that serotonin (5-HT) receptor subtype 5-HT2CR in the basolateral amygdala (BLA) contributes to increased CeA output and neuropathic pain-like behaviors. Here, we tested the novel hypothesis that 5-HT2CR in the BLA drives CRF1 receptor activation to increase CeA neuronal activity in neuropathic pain. Extracellular single-unit recordings of CeA neurons in anesthetized adult male rats detected increased activity in neuropathic rats (spinal nerve ligation model) compared to sham controls. Increased CeA activity was blocked by local knockdown or pharmacological blockade of 5-HT2CR in the BLA, using stereotaxic administration of 5-HT2CR short hairpin RNA (shRNA) viral vector or a 5-HT2CR antagonist (SB242084), respectively. Stereotaxic administration of a CRF1 receptor antagonist (NBI27914) into the BLA also decreased CeA activity in neuropathic rats and blocked the facilitatory effects of a 5-HT2CR agonist (WAY161503) administered stereotaxically into the BLA. Conversely, local (BLA) knockdown of 5-HT2CR eliminated the inhibitory effect of NBI27914 and the facilitatory effect of WAY161503 in neuropathic rats. The data suggest that 5-HT2CR activation in the BLA contributes to neuropathic pain-related amygdala (CeA) activity by engaging CRF1 receptor signaling.

Central, but not systemic, thermoregulatory effects of leptin are impaired in rats with obesity: interactions with GABAB agonist and antagonist.

Leptin is an adipokine that regulates body weight by decreasing appetite and increasing energy expenditure. Besides the effects on food intake, leptin can regulate energy expenditure at least in part by modulating thermogenesis. Many of the effects of leptin are attributable to action in the central nervous system, particularly in the hypothalamus. Common forms of obesity are associated with increased leptin levels and a failure to suppress feeding and mediate weight loss in response to exogenous leptin. This apparent leptin ineffectiveness defines a state of so-called leptin resistance. We examined the effect of leptin on core body temperature in rats with normal weight and diet-induced obesity (DIO), as well as thermoregulatory interactions between leptin and GABAB-agonist and an antagonist. We found that leptin retains the ability to induce hyperthermic effect in rats with DIO. Additionally, temperature responses produced by GABAB agonist and antagonist are altered in a state of obesity and by administration of leptin. We evaluated whether the medial preoptic area of the anterior hypothalamus (MPA) still remains sensitive to leptin action during DIO. Using extracellular recordings of neurons and phospho-signal transducer and the activator of transcription 3 (pSTAT3) immunohistochemistry, we have provided strong evidence that leptin signaling in the MPA is impaired in obese rats. We believe that leptin resistance in the MPA may play a role in the pathogenesis of obesity and obesity-related disease states.

A dynamic network model of temporal receptive fields in primary auditory cortex.

Auditory neurons encode stimulus history, which is often modelled using a span of time-delays in a spectro-temporal receptive field (STRF). We propose an alternative model for the encoding of stimulus history, which we apply to extracellular recordings of neurons in the primary auditory cortex of anaesthetized ferrets. For a linear-non-linear STRF model (LN model) to achieve a high level of performance in predicting single unit neural responses to natural sounds in the primary auditory cortex, we found that it is necessary to include time delays going back at least 200 ms in the past. This is an unrealistic time span for biological delay lines. We therefore asked how much of this dependence on stimulus history can instead be explained by dynamical aspects of neurons. We constructed a neural-network model whose output is the weighted sum of units whose responses are determined by a dynamic firing-rate equation. The dynamic aspect performs low-pass filtering on each unit’s response, providing an exponentially decaying memory whose time constant is individual to each unit. We find that this dynamic network (DNet) model, when fitted to the neural data using STRFs of only 25 ms duration, can achieve prediction performance on a held-out dataset comparable to the best performing LN model with STRFs of 200 ms duration. These findings suggest that integration due to the membrane time constants or other exponentially-decaying memory processes may underlie linear temporal receptive fields of neurons beyond 25 ms.

Experimental pediatric stroke shows age-specific recovery of cognition and role of hippocampal Nogo-A receptor signaling

Ischemic stroke is a leading cause of death worldwide and clinical data suggest that children may recover from stroke better than adults; however, supporting experimental data are lacking. We used our novel mouse model of experimental juvenile ischemic stroke (MCAO) to characterize age-specific cognitive dysfunction following ischemia. Juvenile and adult mice subjected to 45-min MCAO, and extracellular field recordings of CA1 neurons were performed to assess hippocampal synaptic plasticity changes after MCAO, and contextual fear conditioning was performed to evaluate memory and biochemistry used to analyze Nogo-A expression. Juvenile mice showed impaired synaptic plasticity seven days after MCAO, followed by full recovery by 30 days. Memory behavior was consistent with synaptic impairments and recovery after juvenile MCAO. Nogo-A expression increased in ipsilateral hippocampus seven days after MCAO compared to contralateral and sham hippocampus. Further, inhibition of Nogo-A receptors reversed MCAO-induced synaptic impairment in slices obtained seven days after juvenile MCAO. Adult MCAO-induced impairment of LTP was not associated with increased Nogo-A. This study demonstrates that stroke causes functional impairment in the hippocampus and recovery of behavioral and synaptic function is more robust in the young brain. Nogo-A receptor activity may account for the impairments seen following juvenile ischemic injury.

The projection of anorectal afferents to spinal cord and effect of sacral neuromodulation on dorsal horn neurons which receive such input in the rat.

The rat has served usefully as a model for fecal incontinence and exploration of the mechanism of action of sacral neuromodulation (SNM). There remains a deficit in information regarding the location and type of spinal neurons which receive anorectal input and the effect of SNM on those neurons. Single neuronal extracellular recordings of neurons receiving anorectal input were made at the S1 level of the spinal cord using sharp glass electrodes. SNM at S1 was delivered at 2Hz for 3minutes and its effect on discharge was quantified. In total, 31 units (n=14 animals) receiving anorectal synaptic input were recorded at the first sacral (S1) segmental level in either lamina III or IV of the dorsal horn. The inputs were classified according to afferent fiber conduction speed (16 Aδ, 11 Aβ, and 4 C-fiber). The baseline firing frequency (ie, the mean firing frequency before the application of SNM) was 0.48Hz±0.49 (mean±SD) and 58% of units responded to acute SNM with either an increase or decrease in mean firing frequency. In this study, the majority of spinal neurons receiving anorectal input changed their activity in response to SNM. These findings provide the basis for future studies which aim to explore the precise cellular mechanism of action of SNM on this fecal continence pathway.

Calcium imaging, MEA recordings, and immunostaining images dataset of neuron-astrocyte networks in culture under the effect of norepinephrine.

BackgroundMonitoring the activity and morphology of neuron-astrocyte networks in culture is a powerful tool for studying dynamics, structure, and communication in neuron-astrocyte networks independently or as a model of the sub-brain network. These cultures are known to produce stereotypical patterns of activity, e.g., highly synchronized network bursts resembling sleep or seizure states, thus it enables the exploration of behaviors that can relate to brain function and disease. High-resolution microscopy of calcium imaging combined with simultaneous electrical recording provides a comprehensive overview on the network's dynamics. This setup makes it possible to apply global perturbations of electrical and chemical stimulation on the cultures during the recording task and to record the effects on network activity on-line. Morphological changes in the cultures can be obtained to have a complete dataset for structure-function study of neuron-astrocyte networks in vitro.FindingsThe 4 TB of data presented here was recorded and imaged as part of an accompanying study looking at in vitro structure-function of neuron-astrocyte networks. Simultaneous optical (calcium imaging) and electrical (micro-electrode array) recordings lasted 5–12 minutes and included spontaneous activity recording, electrical and chemical stimulation of neuron-astrocyte, and isolated astrocyte cultures. The data include activity recordings of 58 different cultures, with 1–2 regions of interest recorded for each culture. Production procedures, experimental protocols, and reuse options are included. The data have been suitable to reveal changes in the activity and morphology of the cultures and enabled observation and analysis of neuron-astrocyte and isolated astrocyte culture behaviors under the applied perturbations.ConclusionsOur dataset is sufficient to show significant changes in activity and morphology of neuron-astrocyte networks in culture under the applied stimulations. More than 100 recordings of 58 different cultures give insight of the observation's significance and led to conclusions about astrocyte activity and neuron-astrocyte network communication. Making it available here will allow others to test new tools for calcium imaging analysis and extracellular neuronal voltage recordings.

Temporal Contingencies Determine Whether Adaptation Strengthens or Weakens Normalization.

A fundamental and nearly ubiquitous feature of sensory encoding is that neuronal responses are strongly influenced by recent experience, or adaptation. Theoretical and computational studies have proposed that many adaptation effects may result in part from changes in the strength of normalization signals. Normalization is a "canonical" computation in which a neuron's response is modulated (normalized) by the pooled activity of other neurons. Here, we test whether adaptation can alter the strength of cross-orientation suppression, or masking, a paradigmatic form of normalization evident in primary visual cortex (V1). We made extracellular recordings of V1 neurons in anesthetized male macaques and measured responses to plaid stimuli composed of two overlapping, orthogonal gratings before and after prolonged exposure to two distinct adapters. The first adapter was a plaid consisting of orthogonal gratings and led to stronger masking. The second adapter presented the same orthogonal gratings in an interleaved manner and led to weaker masking. The strength of adaptation's effects on masking depended on the orientation of the test stimuli relative to the orientation of the adapters, but was independent of neuronal orientation preference. Changes in masking could not be explained by altered neuronal responsivity. Our results suggest that normalization signals can be strengthened or weakened by adaptation depending on the temporal contingencies of the adapting stimuli. Our findings reveal an interplay between two widespread computations in cortical circuits, adaptation and normalization, that enables flexible adjustments to the structure of the environment, including the temporal relationships among sensory stimuli.SIGNIFICANCE STATEMENT Two fundamental features of sensory responses are that they are influenced by adaptation and that they are modulated by the activity of other nearby neurons via normalization. Our findings reveal a strong interaction between these two aspects of cortical computation. Specifically, we show that cross-orientation masking, a form of normalization, can be strengthened or weakened by adaptation depending on the temporal contingencies between sensory inputs. Our findings support theoretical proposals that some adaptation effects may involve altered normalization and offer a network-based explanation for how cortex adjusts to current sensory demands.

Opioid and noradrenergic contributions of tapentadol to the inhibition of locus coeruleus neurons in the streptozotocin rat model of polyneuropathic pain

Tapentadol is an analgesic that acts as an agonist of µ opioid receptors (MOR) and that inhibits noradrenaline reuptake. Data from healthy rats show that tapentadol inhibits neuronal activity in the locus coeruleus (LC), a nucleus regulated by both the noradrenergic and opioid systems. Thus, we set out to investigate the effect of tapentadol on LC activity in streptozotocin (STZ)-induced diabetic rats, a model of diabetic polyneuropathy, by analyzing single-unit extracellular recordings of LC neurons. Four weeks after inducing diabetes, tapentadol dose-response curves were obtained from animals pre-treated with RX821002 or naloxone (alpha2-adrenoceptors and opioid receptors antagonists, respectively). In STZ rats, the spontaneous activity of LC neurons (0.9 ± 0.1 Hz) was lower than in naïve animals (1.5 ± 0.1 Hz), and tapentadol's inhibitory effect was also weaker. Alpha2-adrenoceptors blockade by RX821002 (100 μg/kg i.v.) in STZ animals significantly increased the spontaneous activity (from 0.8 ± 0.1 to 1.4 ± 0.2 Hz) and it dampened the inhibition of LC neurons produced by tapentadol. However, opioid receptors blockade following naloxone pre-treatment (5 mg/kg i.v.) did not alter the spontaneous firing rate (0.9 ± 0.2 vs 0.9 ± 0.2 Hz) or the inhibitory effect of tapentadol on LC neurons in STZ animals. Thus, diabetic polyneuropathy appears to exert neuroplastic changes in LC neurotransmission, enhancing the sensitivity of alpha2-adrenoceptors and dampening opioid receptors expression. Tapentadol's activity seems to be predominantly mediated through its noradrenergic effects rather than its influence on opioid receptors in the STZ model of diabetic polyneuropathy.

Discrete Sparse Coding.

Sparse coding algorithms with continuous latent variables have been the subject of a large number of studies. However, discrete latent spaces for sparse coding have been largely ignored. In this work, we study sparse coding with latents described by discrete instead of continuous prior distributions. We consider the general case in which the latents (while being sparse) can take on any value of a finite set of possible values and in which we learn the prior probability of any value from data. This approach can be applied to any data generated by discrete causes, and it can be applied as an approximation of continuous causes. As the prior probabilities are learned, the approach then allows for estimating the prior shape without assuming specific functional forms. To efficiently train the parameters of our probabilistic generative model, we apply a truncated expectation-maximization approach (expectation truncation) that we modify to work with a general discrete prior. We evaluate the performance of the algorithm by applying it to a variety of tasks: (1)we use artificial data to verify that the algorithm can recover the generating parameters from a random initialization, (2)use image patches of natural images and discuss the role of the prior for the extraction of image components, (3)use extracellular recordings of neurons to present a novel method of analysis for spiking neurons that includes an intuitive discretization strategy, and (4) apply the algorithm on the task of encoding audio waveforms of human speech. The diverse set of numerical experiments presented in this letter suggests that discrete sparse coding algorithms can scale efficiently to work with realistic data sets and provide novel statistical quantities to describe the structure of the data.

Monomethyl fumarate inhibits pain behaviors and amygdala activity in a rat arthritis model.

Neuroplasticity in the amygdala, a brain center for emotions, leads to increased neuronal activity and output that can generate emotional-affective behaviors and modulate nocifensive responses. Mechanisms of increased activity in the amygdala output region (central nucleus, CeA) include increased reactive oxygen species, and so we explored beneficial effects of monomethyl fumarate (MMF), which can have neuroprotective effects through the nuclear factor (erythroid-derived 2)-like 2 (Nrf2) antioxidant response pathway. Systemic (intraperitoneal) MMF dose-dependently inhibited vocalizations and mechanosensitivity (hindlimb withdrawal reflexes) of rats in an arthritis pain model (kaolin-carrageenan-induced monoarthritis in the knee). Stereotaxic administration of MMF into the CeA by microdialysis also inhibited vocalizations but had a limited effect on mechanosensitivity, suggesting a differential contribution to emotional-affective vs sensory pain aspects. Extracellular single-unit recordings of CeA neurons in anesthetized rats showed that stereotaxic administration of MMF into the CeA by microdialysis inhibited background activity and responses of CeA neurons to knee joint stimulation in the arthritis pain model. Monomethyl fumarate had no effect on behaviors and neuronal activity under normal conditions. The results suggest that MMF can inhibit emotional-affective responses in an arthritis pain model through an action that involves the amygdala (CeA).

Characterization of functional μ opioid receptor turnover in rat locus coeruleus: an electrophysiological and immunocytochemical study.

Regulation of μ receptor dynamics such as its trafficking is a possible mechanism underlying opioid tolerance that contributes to inefficient recycling of opioid responses. We aimed to characterize the functional turnover of μ receptors in the noradrenergic nucleus locus coeruleus (LC). We measured opioid effect by single-unit extracellular recordings of LC neurons from rat brain slices. Immunocytochemical techniques were used to evaluate μ receptor trafficking. After near-complete, irreversible μ receptor inactivation with β-funaltrexamine (β-FNA), opioid effect spontaneously recovered in a rapid and efficacious manner. In contrast, α2 -adrenoceptor-mediated effect hardly recovered after receptor inactivation with the irreversible antagonist EEDQ. When the recovery of opioid effect was tested after various inactivating time schedules, we found that the longer the β-FNA pre-exposure, the less efficient and slower the functional μ receptor turnover became. Interestingly, μ receptor turnover was slower when β-FNA challenge was repeated in the same cell, indicating constitutive μ receptor recycling by trafficking from a depletable pool. Double immunocytochemistry confirmed the constitutive nature of μ receptor trafficking from a cytoplasmic compartment. The μ receptor turnover was slowed down when LC neuron calcium- or firing-dependent processes were prevented or vesicular protein trafficking was blocked by a low temperature or transport inhibitor. Constitutive trafficking of μ receptors from a depletable intracellular pool (endosome) may account for its rapid and efficient functional turnover in the LC. A finely-tuned regulation of μ receptor trafficking and endosomes could explain neuroadaptive plasticity to opioids in the LC.

Firing properties of pre‐inspiratory neurons are altered in female rats exposed to chronic intermittent hypoxia

Female rats submitted to chronic intermittent hypoxia (CIH) presented a reduced time of inspiration, sympathetic overactivity and hypertension. The increase in sympathetic nerve discharge in CIH‐female rats is associated to an increase in the inspiratory modulation of sympathetic activity. In this context, we hypothesized that inspiratory neurons at the brainstem have change their activity in CIH‐female rats, which in turn, modulates the presympathetic neurons producing an increase in sympathetic activity during inspiration. To test this hypothesis, juvenile female Wistar rats (P20–21) underwent intermittent hypoxia for 10 days. One day after CIH, we performed the extracellular single unit recordings of respiratory neurons at the ventral surface of the medulla using the ventral approach of the working heart‐brainstem preparation. All the experimental protocols were approved by the institutional ethical committee (#091/2013). Pre‐inspiratory neurons (Pre‐I/I) of CIH‐female rats (n=16) have reduced their firing frequency (58.3 ± 9 vs 107.6 ± 12Hz, p=0.0027) compared to Pre‐I/I neurons of control (n=15). Synaptic blockade demonstrated that Pre‐I/I neurons (n=3) have auto‐depolarization property. Ramp‐I, Early‐I and Late‐I neurons presented no changes in their firing properties after CIH. Regarding the expiratory neurons, post‐inspiratory neurons (Post‐I) have increased the firing time relative to duration of expiration (92.2 ± 2 vs 81.3 ± 3 % of total duration of expiration, p=0.0127) in CIH‐female rats (n=15) compared to control (n=17). We conclude that CIH produces a reduction in the activity of pacemaker Pre‐I/I neurons that could explain the reduced time of inspiration and the increase in inspiratory modulation of sympathetic activity in CIH‐female rats. These findings contribute to a better understanding of the respiratory network activity associated with sympathetic overactivity and hypertension in female rats exposed to CIH.Support or Funding InformationFapesp, CAPES and CNPq

Heterogeneous effects of norepinephrine on spontaneous and stimulus-driven activity in the male accessory olfactory bulb.

Norepinephrine (NE) release has been linked to experience-dependent plasticity in many model systems and brain regions. Among these is the rodent accessory olfactory system (AOS), which is crucial for detecting and processing socially relevant environmental cues. The accessory olfactory bulb (AOB), the first site of chemosensory information processing in the AOS, receives dense centrifugal innervation by noradrenergic fibers originating in the locus coeruleus. Although NE release has been linked to behavioral plasticity through its actions in the AOB, the impacts of noradrenergic modulation on AOB information processing have not been thoroughly studied. We made extracellular single-unit recordings of AOB principal neurons in ex vivo preparations of the early AOS taken from adult male mice. We analyzed the impacts of bath-applied NE (10 μM) on spontaneous and stimulus-driven activity. In the presence of NE, we observed overall suppression of stimulus-driven neuronal activity with limited impact on spontaneous activity. NE-associated response suppression in the AOB came in two forms: one that was strong and immediate (21%) and one other that involved gradual, stimulus-dependent monotonic response suppression (47%). NE-associated changes in spontaneous activity were more modest, with an overall increase in spontaneous spike frequency observed in 25% of neurons. Neurons with increased spontaneous activity demonstrated a net decrease in chemosensory discriminability. These results reveal that noradrenergic signaling in the AOB causes cell-specific changes in chemosensory tuning, even among similar projection neurons.NEW & NOTEWORTHY Norepinephrine (NE) is released throughout the brain in many behavioral contexts, but its impacts on information processing are not well understood. We studied the impact of NE on chemosensory tuning in the mouse accessory olfactory bulb (AOB). Electrophysiological recordings from AOB neurons in ex vivo preparations revealed that NE, on balance, inhibited mitral cell responses to chemosensory cues. However, NE's effects were heterogeneous, indicating that NE signaling reshapes AOB output in a cell- and stimulus-specific manner.