Implication of Kv7 Channels in the Spinal Antinociceptive Actions of Celecoxib.

Celecoxib is a nonsteroidal anti-inflammatory drug (NSAID) commonly used to treat pain conditions in humans. In addition to its blocking activity on cyclooxygenase (COX) enzymes, several other targets could contribute to its analgesic activity. Here we explore the spinal antinociceptive actions of celecoxib and the potential implication of Kv7 channels in mediating its effects. Spinal cord in vitro preparations from hind paw-inflamed animals were used to assess the segmental sensory-motor and the early sensory processing of nociceptive information. Electrophysiological recordings of ventral roots and dorsal horn neurones were obtained, and the effects of celecoxib and Kv7 modulators on responses to repetitive dorsal root stimulation at C-fiber intensity were assessed. Celecoxib applied at clinically relevant concentrations produced depressant effects on responses to dorsal root stimulation recorded from both ventral roots and individual dorsal horn neurones; by contrast, the non-nociceptive monosynaptic reflex was unaffected. The NSAID indomethacin had no effect on spinal reflexes, but further coapplication of celecoxib still produced depressant effects. The depressant actions of celecoxib were abolished after Kv7 channel blockade and mimicked by its structural analog dimethyl-celecoxib, which lacks COX-blocking activity. The present results identify Kv7 channels as novel central targets for celecoxib, which may be relevant to its analgesic effect. This finding contributes to better understand the pharmacology of celecoxib and reinforces both the role of Kv7 channels in modulating the excitability of central pain pathways and its validity as target for the design of analgesics.

Analysis of spontaneous activity of superficial dorsal horn neurons in vitro: neuropathy-induced changes.

The superficial dorsal horn contains large numbers of interneurons which process afferent and descending information to generate the spinal nociceptive message. Here, we set out to evaluate whether adjustments in patterns and/or temporal correlation of spontaneous discharges of these neurons are involved in the generation of central sensitization caused by peripheral nerve damage. Multielectrode arrays were used to record from discrete groups of such neurons in slices from control or nerve damaged mice. Whole-cell recordings of individual neurons were also obtained. A large proportion of neurons recorded extracellularly showed well-defined patterns of spontaneous firing. Clock-like neurons (CL) showed regular discharges at ∼6 Hz and represented 9 % of the sample in control animals. They showed a tonic-firing pattern to direct current injection and depolarized membrane potentials. Irregular fast-burst neurons (IFB) produced short-lasting high-frequency bursts (2-5 spikes at ∼100 Hz) at irregular intervals and represented 25 % of the sample. They showed bursting behavior upon direct current injection. Of the pairs of neurons recorded, 10 % showed correlated firing. Correlated pairs always included an IFB neuron. After nerve damage, the mean spontaneous firing frequency was unchanged, but the proportion of CL increased significantly (18 %) and many of these neurons appeared to acquire a novel low-threshold A-fiber input. Similarly, the percentage of IFB neurons was unaltered, but synchronous firing was increased to 22 % of the pairs studied. These changes may contribute to transform spinal processing of nociceptive inputs following peripheral nerve damage. The specific roles that these neurons may play are discussed.

Characterisation of rebound depolarisation in mice deep dorsal horn neurons in vitro.

Spinal dorsal horn neurons constitute the first relay for pain processing and participate in the processing of other sensory, motor and autonomic information. At the cellular level, intrinsic excitability is a factor contributing to network function. In turn, excitability is set by the array of ionic conductance expressed by neurons. Here, we set out to characterise rebound depolarisation following hyperpolarisation, a feature frequently described in dorsal horn neurons but never addressed in depth. To this end, an in vitro preparation of the spinal cord from mice pups was used combined with whole-cell recordings in current and voltage clamp modes. Results show the expression of H- and/or T-type currents in a significant proportion of dorsal horn neurons. The expression of these currents determines the presence of rebound behaviour at the end of hyperpolarising pulses. T-type calcium currents were associated to high-amplitude rebounds usually involving high-frequency action potential firing. H-currents were associated to low-amplitude rebounds less prone to elicit firing or firing at lower frequencies. For a large proportion of neurons expressing both currents, the H-current constitutes a mechanism to ensure a faster response after hyperpolarisations, adjusting the latency of the rebound firing. We conclude that rebound depolarisation and firing are intrinsic factors to many dorsal horn neurons that may constitute a mechanism to integrate somatosensory information in the spinal cord, allowing for a rapid switch from inhibited-to-excited states.

Synchronous firing of dorsal horn neurons at the origin of dorsal root reflexes in naïve and paw-inflamed mice.

Spinal interneurons located in the dorsal horn induce primary afferent depolarization (PAD) controlling the excitability of the afferent's terminals. Following inflammation, PAD may reach firing threshold contributing to maintain inflammation and pain. Our aim was to study the collective behavior of dorsal horn neurons, its relation to backfiring of primary afferents and the effects of a peripheral inflammation in this system. Experiments were performed on slices of spinal cord obtained from naïve adult mice or mice that had suffered an inflammatory pretreatment. Simultaneous recordings from groups of dorsal horn neurons and primary afferents were obtained and machine-learning methodology was used to analyze effective connectivity between them. Dorsal horn recordings showed grouping of spontaneous action potentials from different neurons in "population bursts." These occurred at irregular intervals and were formed by action potentials from all classes of neurons recorded. Compared to naïve, population bursts from treated animals concentrated more action potentials, had a faster onset and a slower decay. Population bursts were disrupted by perfusion of picrotoxin and held a strong temporal correlation with backfiring of afferents. Effective connectivity analysis allowed pinpointing specific neurons holding pre- or post-synaptic relation to the afferents. Many of these neurons had an irregular fast bursting pattern of spontaneous firing. We conclude that population bursts contain action potentials from neurons presynaptic to the afferents which are likely to control their excitability. Peripheral inflammation may enhance synchrony in these neurons, increasing the chance of triggering action potentials in primary afferents and contributing toward central sensitization.

Changes in membrane excitability and potassium currents in sensitized dorsal horn neurons of mice pups.

Rationally, an increased intrinsic excitability of dorsal horn neurons could be a factor contributing to alter the gain of the nociceptive system during central sensitization, however direct evidence is scarce. Here we have examined this hypothesis using current and voltage-clamp recordings from dorsal horn neurons in the spinal cord in vitro preparation obtained from mice pups of either sex. Cords were extracted from carrageenan-pretreated and control animals to allow for comparison. Dorsal horn neurons from treated animals showed significantly larger and faster synaptic responses. Synaptic changes started developing shortly after inflammation (1 h) and developed further after a longer-term inflammation (20 h). However, these neurons showed biphasic changes in membrane excitability with an increase shortly after inflammation and a decrease in the longer term. Concomitant changes were observed in transient (I(A)) and sustained potassium currents (I(DR)). Prolonged superfusion of naive spinal cords with NMDA led to a decreased neuronal excitability and to increased potassium currents. Results suggest that excitability plays a role more complex than expected during the process of central sensitization of dorsal horn neurons and that modulation of potassium currents may contribute to shape the changing states of excitability. The decreased excitability observed after long-term inflammation is interpreted as a homeostatic correction to an abnormal state of synaptic activity.

Accumulation of Kv7.2 channels in putative ectopic transduction zones of mice nerve-end neuromas.

BACKGROUND: Modulation of M-type currents has been proposed as a new strategy for the treatment of neuropathic pain due to their role in regulating neuronal excitability. Using electrophysiological techniques we showed previously that the opening of Kv7 channels with retigabine, blocked ectopic discharges from axotomized fibers but did not alter transduction at intact skin afferents. We hypothesized that after nerve damage, accumulation of Kv7 channels in afferent fibers may increase M-type currents which then acquired a more important role at regulating fiber excitability. FINDINGS: In this study, we used an immunohistochemical approach to examine patterns of expression of Kv7.2 channels in afferent fibers after axotomy and compared them to patterns of expression of voltage gated Na+ channels (Nav) which are key electrogenic elements in peripheral axons known to accumulate in experimental and human neuromas.Axotomy induced an enlargement and narrowing of the nodes of Ranvier at the proximal end of the neuroma together with a dramatic demyelination and loss of structure at its distal end in which naked accumulations of Nav were present. In addition, axotomy also induced accumulations of Kv7.2 that co-localized with those of Nav channels. CONCLUSIONS: Whilst Nav channels are mandatory for initiation of action potentials, (i.e. responsible for the generation/propagation of ectopic discharges) an increased accumulation of Kv7.2 channels after axotomy may represent a homeostatic compensation to over excitability in axotomized fibers, opening a window for a peripheral action of M-current modulators under conditions of neuropathy.

Discovering Effective Connectivity in Neural Circuits: Analysis Based on Machine Learning Methodology.

As multielectrode array technology increases in popularity, accessible analytical tools become necessary. Simultaneous recordings from multiple neurons may produce huge amounts of information. Traditional tools based on classical statistics are either insufficient to analyze multiple spike trains or sophisticated and expensive in computing terms. In this communication, we put to the test the idea that AI algorithms may be useful to gather information about the effective connectivity of neurons in local nuclei at a relatively low computing cost. To this end, we decided to explore the capacity of the algorithm C5.0 to retrieve information from a large series of spike trains obtained from a simulated neuronal circuit with a known structure. Combinatory, iterative and recursive processes using C5.0 were built to examine possibilities of increasing the performance of a direct application of the algorithm. Furthermore, we tested the applicability of these processes to a reduced dataset obtained from original biological recordings with unknown connectivity. This was obtained in house from a mouse in vitro preparation of the spinal cord. Results show that this algorithm can retrieve neurons monosynaptically connected to the target in simulated datasets within a single run. Iterative and recursive processes can identify monosynaptic neurons and disynaptic neurons under favorable conditions. Application of these processes to the biological dataset gives clues to identify neurons monosynaptically connected to the target. We conclude that the work presented provides substantial proof of concept for the potential use of AI algorithms to the study of effective connectivity.

DREAM regulates BDNF-dependent spinal sensitization.

BACKGROUND: The transcriptional repressor DREAM (downstream regulatory element antagonist modulator) controls the expression of prodynorphin and has been involved in the modulation of endogenous responses to pain. To investigate the role of DREAM in central mechanisms of pain sensitization, we used a line of transgenic mice (L1) overexpressing a Ca(2+)- and cAMP-insensitive DREAM mutant in spinal cord and dorsal root ganglia. RESULTS: L1 DREAM transgenic mice showed reduced expression in the spinal cord of several genes related to pain, including prodynorphin and BDNF (brain-derived neurotrophic factor) and a state of basal hyperalgesia without change in A-type currents. Peripheral inflammation produced enhancement of spinal reflexes and increased expression of BDNF in wild type but not in DREAM transgenic mice. The enhancement of the spinal reflexes was reproduced in vitro by persistent electrical stimulation of C-fibers in wild type but not in transgenic mice. Exposure to exogenous BDNF produced a long-term enhancement of dorsal root-ventral root responses in transgenic mice. CONCLUSIONS: Our results indicate that endogenous BDNF is involved in spinal sensitization following inflammation and that blockade of BDNF induction in DREAM transgenic mice underlies the failure to develop spinal sensitization.

Origin and classification of spontaneous discharges in mouse superficial dorsal horn neurons.

Superficial laminae of the spinal cord possess a considerable number of neurons with spontaneous activity as reported in vivo and in vitro preparations of several species. Such neurons may play a role in the development of the nociceptive system and/or in the spinal coding of somatosensory signals. We have used electrophysiological techniques in a horizontal spinal cord slice preparation from adult mice to investigate how this activity is generated and what are the main patterns of activity that can be found. The results show the existence of neurons that fire regularly and irregularly. Within each of these main types, it was possible to distinguish patterns of spontaneous activity formed by single action potentials and different types of bursts according to intra-burst firing frequency. Activity in neurons with irregular patterns was blocked by a mixture of antagonists of the main neurotransmitter receptors present in the cord. Approximately 82% of neurons with a regular firing pattern were insensitive to synaptic antagonists but their activity was inhibited by specific ion channel blockers. It is suggested that these neurons generate endogenous activity due to the functional expression of hyperpolarisation-activated and persistent sodium currents driving the activity of irregular neurons.

Spinal Reflexes and Windup In Vitro: Effects of Analgesics and Anesthetics.

The spinal cord is the first relay center for nociceptive information. Following peripheral injury, the spinal cord sensitizes. A sign of spinal sensitization is the hyper-reflexia which develops shortly after injury and can be detected in the isolated spinal cord as a "memory of pain." In this context, it is easy to understand that many analgesic compounds target spinally located sites of action to attain analgesia. In vitro isolated spinal cord preparations have been used for a number of years, and experience on the effects of compounds of diverse pharmacological families on spinal function has accumulated. Recently, we have proposed that the detailed study of spinal segmental reflexes in vitro may produce data relevant to the evaluation of the analgesic potential of novel compounds. In this review, we describe the main features of segmental reflexes obtained in vitro and discuss the effects of compounds of diverse chemical nature and pharmacological properties on such reflexes. Our aim was to compare the different profiles of action of the compounds on segmental reflexes in order to extract clues that may be helpful for pharmacological characterization of novel analgesics.

Potassium channels in neuropathic pain: advances, challenges, and emerging ideas.

A workshop of the 2015 International Neuropathic Pain Congress was focused on potassium channels to propose emerging ideas on the role of these channels on pain modulation and to determine whether they can become relevant targets for designing novel analgesic compounds. Two kinds of potassium channels were particularly evoked: selected subunits of the voltage-gated potassium (Kv) and of the K2P channel families. In this review, the role of the former is described with a focus first on silent subunits as modulators of Kv and second on the Kv7 subunits. The physiological, pathophysiological, and pharmacological involvement of the K2P in pain modulation is then described. Throughout this review, the role of potassium channels in pain is obvious, which renders them potential targets for innovative analgesics with peripheral and/or central action depending on the channel. Clearly, some preliminary results obtained with known or novel potassium channel openers suggest that they might represent a novel class of analgesics in neuropathic pain or other pathological contexts.

Effects of novel subtype selective M-current activators on spinal reflexes in vitro: Comparison with retigabine.

The activation of Kv7 channels and the resulting M-current is a powerful mechanism to control neuronal excitability with profound effects in pain pathways. Despite the lack of specific data on the expression and role of these channels in nociceptive processing, much attention has been paid at exploring their potential value as targets for analgesia. Here we have characterized the spinal actions of two novel subunit selective Kv7 activators, ICA-069673 and ML213, and compared their effects to those of retigabine that acts with similar affinity on all neuronal Kv7 channels. Spinal reflexes were recorded in a mouse spinal cord in vitro preparation to allow the testing of the compounds on native spinal pathways at known concentrations. As retigabine, novel compounds depressed spinal segmental transmission with particularly strong effects on wind up, showing an adequate pro-analgesic profile. ML213 presented the highest potency. In contrast to retigabine, the effects of ICA-069673 and ML213 were blocked by XE-991 even at the highest concentrations used, suggesting specific effect on Kv7 channels. In addition, the effects of ICA-069673 on repetitive stimulation are consistent with a mode of action involving state or activity dependent interaction with the channels. Compared to retigabine, novel Kv7 openers maintain strong depressant effects on spinal nociceptive transmission showing an improved specificity on Kv7 channels. The differential effects obtained with these Kv7 openers may indicate the existence of several Kv7 conformations in spinal circuits.

Role of serotonin1A receptors on the modulation of rat spinal mono-synaptic reflexes in vitro.

The present study aimed at determining the role of the serotonin(1A) (5-HT(1A)) receptor subtype on the modulation of the mono-synaptic reflex (MSR) elicited by dorsal root stimulation and recorded from ventral roots in the hemisected spinal cord obtained from rat pups. Serotonin and 5-carboxamidotryptamine (5-CT) depressed both the MSR and the cumulative depolarisation (CD) produced by repetitive dorsal root stimulation, whereas the specific 5-HT(1A) receptor agonist (R)-(+)-8-hydroxy-2-(di-n-propylamino)tetralin (8-OH-DPAT) applied at 1 microM showed a selective depressant effect on the MSR. Superfusion of the 5-HT(1A) receptor antagonist (+)-N-tert-butyl-3(4(2-methoxyphenyl)-piperazin-1-yl)-2-phenylprpanamide ((+)WAY 100135) produced a complete blockade of 8-OH-DPAT effects. In addition (+)WAY 100135 blocked partially the effects of 5-HT and 5-CT on the MSR but not the effects of these compounds on the CD. The results are consistent with an intervention of 5-HT(1A) receptors in the modulation of non-nociceptive reflexes but do not support a prominent role for this receptor in the modulation of nociceptive reflexes.

Stimulation of dorsal root afferents increases the excitability of ascending sensory axons in the isolated spinal cord of mature mice.

The phenomenon of windup has often been used to assess excitability increases of spinal neurons induced by repetitive stimulation of nociceptive afferents. Windup has been studied in individual spinal cord neurons and in spinal motor reflexes neither of which accurately reflect the forward transmission of nociceptive signals to the brain. In addition, most in vitro studies of spinal windup have been conducted on immature or juvenile animals and it is challenging to extrapolate these results to the adult spinal cord. In the present study, we have used an in vitro whole spinal cord preparation from functionally mature mice (up to 8 weeks old) to record windup activity in ascending axons in the mid-thoracic region evoked by electrical stimulation of a lumbar or sacral dorsal root. Windup responses were observed in axons in the ipsi- and contralateral dorsolateral funiculus (iDLF and cDLF) and in the contralateral ventrolateral funiculus (cVLF). No windup responses were evoked in postsynaptic axons of the ipsilateral dorsal columns (iDC) and no postsynaptic responses were elicited in the ipsilateral ventrolateral funiculus (iVLF) or contralateral dorsal columns (cDC). Between 40% and 45% of all axons in the DLF and cVLF that responded to a single dorsal root stimulus also showed windup. The NMDA receptor antagonist MK-801 reversibly blocked such windup responses. These results illustrate that windup can be consistently recorded from ascending pathways in the mature spinal cord in vitro but also show that windup can only be elicited in a proportion of sensory axons projecting through some, but not all, ascending spinal cord pathways.

Enhancing m currents: a way out for neuropathic pain?

Almost three decades ago, the M current was identified and characterized in frog sympathetic neurons (Brown and Adams, 1980). The years following this discovery have seen a huge progress in the understanding of the function and the pharmacology of this current as well as on the structure of the underlying ion channels. Therapies for a number of syndromes involving abnormal levels of excitability in neurons are benefiting from research on M currents. At present, the potential of M current openers as analgesics for neuropathic pain is under discussion. Here we offer a critical view of existing data on the involvement of M currents in pain processing. We believe that enhancement of M currents at the site of injury may become a powerful strategy to alleviate pain in some peripheral neuropathies.

Actualización del reporte de biopsiapor aspiración con aguja fina de mama / Report of breast fine needle aspiration biopsy: an update

Las recomendaciones para la biopsia por aspiración con aguja fina de mama se desarrollaron y aprobaron en 1997 por el Instituto Nacional de Cáncer en Bethesda, Estados Unidos y fueron adaptadas a nuestro país en 2007, sin embargo, en los últimos años no se han realizado cambios formales en estas indicaciones. El objetivo de este módulo es presentar la actualización del reporte de biopsia por aspiración con aguja fina de mama, usando el sistema de reporte Bethesda, realizado por consenso con un grupo de patólogos, clínicos, radiólogos, cirujanos de mama y otros profesionales de la salud de Colombia y otros países, y con base en la experiencia realizando biopsia por aspiración con aguja fina de mama del Hospital Pablo Tobón Uribe y de Dinámica IPS.

Recommendations for breast fine needle aspiration biopsy were developed and approved in 1997 by The National Cancer Institute of Bethesda, United States, , and were adapted to our country on 2007, however, in last years these indications have not changed in a formal manner. The purpose of this review was to provide an update of the report for breast fine needle aspiration biopsy using the Bethesda system. This guide was made by consensus with pathologists, clinicians, radiologists, breast surgeons and other health professionals of Colombia and other countries. The update was basis on the experience of Hospital Pablo Tobon Uribe and Dinamica IPS in performing breast fine needle aspiration biopsy.

Serotonergic modulation of spinal sensory circuits.

The role of serotonin (5-HT) as a mediator of the endogenous pain control system has been investigated over the last 30 years. Here we review a subset of studies that used electrophysiological techniques to study the mechanisms of action as well as the receptors mediating the spinal effects of serotonin. The works herein discussed employed in vivo or in vitro preparations of control or hyperalgesic animals. According to these reports, 5-HT triggers depressant effects on synaptic transmission limiting the release of neurotransmitters from afferent terminals or the responsiveness of NMDA receptors located in dorsal horn neurones. These mechanisms are most likely mediated by 5-HT1 receptors. In contrast, 5-HT2 receptors seem to mediate excitatory effects such as depolarisation, increased excitability, and neurotransmitter release. The role of 5-HT3 receptors is less clear as they could mediate excitatory or inhibitory effects, depending on variables such as concentration of 5-HT or the state (sensitised/unsensitised) of the spinal cord. The consequences of these spinal effects of serotonin are discussed in the context of pain and analgesia.