Phase Dependency of the Human Primary Motor Cortex and Cholinergic Inhibition Cancelation during Beta tACS

The human motor cortex has a tendency to resonant activity at about 20 Hz so stimulation should more readily entrain neuronal populations at this frequency. We investigated whether and how different interneuronal circuits contribute to such resonance by using transcranial magnetic stimulation (TMS) during transcranial alternating current stimulation (tACS) at motor (20 Hz) and a nonmotor resonance frequency (7 Hz). We tested different TMS interneuronal protocols and triggered TMS pulses at different tACS phases. The effect of cholinergic short-latency afferent inhibition (SAI) was abolished by 20 Hz tACS, linking cortical beta activity to sensorimotor integration. However, this effect occurred regardless of the tACS phase. In contrast, 20 Hz tACS selectively modulated MEP size according to the phase of tACS during single pulse, GABAAergic short-interval intracortical inhibition (SICI) and glutamatergic intracortical facilitation (ICF). For SICI this phase effect was more marked during 20 Hz stimulation. Phase modulation of SICI also depended on whether or not spontaneous beta activity occurred at ~20 Hz, supporting an interaction effect between tACS and underlying circuit resonances. The present study provides in vivo evidence linking cortical beta activity to sensorimotor integration, and for beta oscillations in motor cortex being promoted by resonance in GABAAergic interneuronal circuits

Metabotropic Glutamate Receptor Activation in Cerebelar Purkinje Cells as Substrate for Adaptive Timing of the Classicaly Conditioned Eye Blink Response

To understand how the cerebellum adaptively times the classically conditioned nictitating membrane response (NMR), a model of the metabotropic glutamate receptor (mGluR) second messenger system in cerebellar Purkinje cells is constructed. In the model slow responses, generated postsynaptically by mGluR-mediated phosphoinositide hydrolysis, and calcium release from intracellular stores, bridge the interstimulus interval (ISI) between the onset of parallel fiber activity associated with the conditioned stimulus (CS) and climbing fiber activity associated with unconditioned stimulus (US) onset. Temporal correlation of metabotropic responses and climbing fiber signals produces persistent phosphorylation of both AMPA receptors and Ca2+-dependent K+ channels. This is responsible for long-term depression (LTD) of AMPA receptors. The phosphorylation of Ca2+-dependent K+ channels leads to a reduction in baseline membrane potential and a reduction of Purkinje cell population firing during the CS-US interval. The Purkinje cell firing decrease disinhibits cerebellar nuclear cells which then produce an excitatory response corresponding to the learned movement. Purkinje cell learning times the response, while nuclear cell learning can calibrate it. The model reproduces key features of the conditioned rabbit NMR: Purkinje cell population response is properly timed, delay conditioning occurs for ISIs of up to four seconds while trace conditioning occurs only at shorter ISIs, mixed training at two different ISis produces a double-peaked response, and ISIs of 200-400ms produce maximal responding. Biochemical similarities between timed cerebellar learning and photoreceptor transduction, and circuit similarities between the timed cerebellar circuit and a timed dentate-CA3 hippocampal circuit, are noted.Office of Naval Research (N00014- 92-J-4015, N00014-92-J-1309, N00014-95-1-0409); Air Force Office of Scientific Research (F49620-92-J-0225);National Science Foundation (IRI-90-24877

Cortical Auditory Adaptation in the Awake Rat and the Role of Potassium Currents

Responses to sound in the auditory cortex are influenced by the preceding history of firing. We studied the time course of auditory adaptation in primary auditory cortex (A1) from awake, freely moving rats. Two identical stimuli were delivered with different intervals ranging from 50 ms to 8 s. Single neuron recordings in the awake animal revealed that the response to a sound is influenced by sounds delivered even several seconds earlier, the second one usually yielding a weaker response. To understand the role of neuronal intrinsic properties in this phenomenon, we obtained intracellular recordings from rat A1 neurons in vitro and mimicked the same protocols of adaptation carried out in awake animals by means of depolarizing pulses of identical duration and intervals. The intensity of the pulses was adjusted such that the first pulse would evoke a similar number of spikes as its equivalent in vivo. A1 neurons in vitro adapted with a similar time course but less than in awake animals. At least two potassium currents participated in the in vitro adaptation: a Na +-dependent K + current and an apamin-sensitive K + current. Our results suggest that potassium currents underlie at least part of cortical auditory adaptation during the awake state.Fil: Abolafia, Juan M.. INSTITUTO DE INVESTIGACIONES BIOMEDICAS AUGUST PI I SUNYER (IDIBAPS);Fil: Vergara, Ramiro Oscar. INSTITUTO DE INVESTIGACIONES BIOMEDICAS AUGUST PI I SUNYER (IDIBAPS); . Consejo Superior de Investigaciones Científicas. Instituto de Neurociencia de Alicante; España. Universidad Nacional de Quilmes; Argentina. Consejo Nacional de Investigaciones Científicas y Técnicas; ArgentinaFil: Arnold, M. M.. Consejo Superior de Investigaciones Científicas. Instituto de Neurociencia de Alicante; España. INSTITUTO DE INVESTIGACIONES BIOMEDICAS AUGUST PI I SUNYER (IDIBAPS);Fil: Reig, R.. INSTITUTO DE INVESTIGACIONES BIOMEDICAS AUGUST PI I SUNYER (IDIBAPS);Fil: Sanchez Vives, M. V.. INSTITUTO DE INVESTIGACIONES BIOMEDICAS AUGUST PI I SUNYER (IDIBAPS)

Neuronal activity patterns in the mediodorsal thalamus and related cognitive circuits are modulated by metabotropic glutamate receptors.

The mediodorsal thalamus (MD) likely plays an important role in cognition as it receives abundant afferent connections from the amygdala and prefrontal cortex (PFC). Indeed, disturbed activity within the MD is thought to precipitate cognitive deficits associated with schizophrenia. As compounds acting at the Group II metabotropic glutamate (mGlu) receptors (subtypes mGlu2/mGlu3) have efficacy in animal models of schizophrenia, we investigated whether a Group II agonist and an mGlu2 positive allosteric modulator (PAM) could modulate MD activity. Extracellular single-unit recordings were made in vivo from MD neurones in anaesthetised rats. Responses were elicited by electrical stimulation of the PFC and/or amygdala, with Group II compounds locally applied as required. The Group II agonist reduced inhibition evoked in the MD: an effect manifested as an increase in short-latency responses, and a decrease in long-latency burst-firing. This disinhibitory action of the Group II receptors in the MD represents a mechanism of potential therapeutic importance as increased inhibition in the MD has been associated with cognitive deficit-onset. Furthermore, as co-application of the mGlu2 PAM did not potentiate the Group II agonist effects in the MD, we suggest that the Group II disinhibitory effect is majority-mediated via mGlu3. This heterogeneity in Group II receptor thalamic physiology bears consequence, as compounds active exclusively at the mGlu2 subtype are unlikely to perturb maladapted MD firing patterns associated with cognitive deficits, with activity at mGlu3 receptors possibly more appropriate. Indeed, polymorphisms in the mGlu3, but not the mGlu2, gene have been detected in patients with schizophrenia

Plasticity of the cortical representation of finger extensors induced by paired associative stimulation

This dissertation first explored associative plasticity of the human motor cortical representation with the use of noninvasive transcranial magnetic stimulation (TMS) paired with peripheral electrical stimulation. Paired Associative Stimulation (PAS) has grown in popularity because of its potential clinical applications. PAS techniques are used in combination with electromyography (EMG) measurements to study cortical excitability and features of hand movement. This work focuses on a cohesive approach to answer central questions about: the ideal mechanism to facilitate cortical plasticity via PAS, the interaction between the behavior performed and type of stimulation delivered to the targeted cortical network and the effects of PAS, the interaction between interstimulus timing, stimulus timing during movement and the translation of these effects into measurable changes starting from neurophysiological changes and ending up with the behavioral modulation of hand movement. First the role of interstimulus timing and intracortical facilitation on modulation of cortical excitability is explored in the extrinsic hand muscles by showing that PAS can be conditioned by these facilitatory intracortical networks. Using standard indirect approaches utilizing peripheral EMG measures and novel virtual reality (VR) environments, a graded excitability response is shown for the PAS technique and illustrates that interactions of PAS with voluntary movements impacts the degree as well as the state of cortical excitability. Rules governing the interactions of brain stimulation techniques and motor learning are important because brain stimulation techniques can be used to modify and improve neuro motor adaptation and skill learning with great potential for clinical applications such as facilitation of recovery after stroke. PAS provides us with a unique opportunity to study the rules of plasticity at a systems level, which is a combination of synaptic and non-synaptic (metaplastic) changes. Finally, it is shown that changes in cortical excitability may help modulate certain neurophysiological and clinical features of hand function in a pair of patients with chronic stroke in a pilot study. As expected, stroke patients exhibited a smaller degree of excitability increase. It is demonstrated that sessions of intense training with PAS in a VR environment induces significant neuroplastic changes in the sensorimotor cortex. Explicitly, VR based PAS facilitates corticospinal excitability in the ipsilesional sensorimotor cortex. As a result, this dissertation provides a new methodological and technical framework to condition the standard PAS paradigm to engage other intracortical networks. It also shows how PAS can be used to affect motor learning and the role of state of cortical excitation in induction of homeostatic or non-homeostatic plasticity for patients with neurological and neuromuscular impairments for example stroke plus the potential behavioral consequences of PAS in human motor cortex to facilitate functional recovery of hand function

An investigation of NMDA receptor subunit pharmacology

N-Methyl-D-aspartate (NMDA) receptors are critically involved in synaptic transmission, neural development and various forms of neuronal plasticity including long-term potentiation (LTP) and long-term depression (LTD). They are also involved in the production of neuronal damage following excessive activation by glutamate released as a result of hypoxia or ischaemia. Each heteromeric receptor includes one or two NRl subunits, at least two of the four NR2A-D subunits and less usually the NR3AJB subunits. This study demonstrates that the putative NR2B subunit-containing NMDA receptor antagonist Ro 25-6981 potentiates the effects ofNMDA on rat hippocampal slices. The NR2A subunit antagonist PEAQX blocks the effects of NMDA alone and the potentiated response following Ro 25-6981 application. Furthermore, Ro 25-6981 was not neuroprotective as reported previously but unexpectedly precipitated excitotoxicity. The potentiating effect of Ro 25-6981 required around 20 minutes to become apparent, took a further 30 minutes to reach its maximum effect and was irreversible. It was not prevented by staurosporine (a broad-spectrum protein kinase inhibitor), okadaic acid (a potent inhibitor of the serine/threonine protein phosphatases types 1 and 2A) or anisomycin (a protein synthesis inhibitor). However, the potentiation was prevented by cyclosporin A (an inhibitor of Ca2+/calmodulin-dependent phosphatase 2B [calcineurin]). The results indicate that in an intact neuronal network, NR2B subunits tonically gate NR2A subunit-containing receptor function by a negative coupling mechanism involving ca1cineurin activation. NMDA receptor-dependent LTP induced by high frequency stimulation was prevented by PEAQX, an NR2A antagonist. Ro 25-6981 was unable to prevent L TP induction but was associated with a marginal reduction in the magnitude of LTP induced. There is evidence for the binding of homoquinolinic acid to an NMDAinsensitive novel binding site in the brain. This study investigated the pharmacology of homoquinolinate on the evoked field excitatory synaptic potential (fEPSP) recorded from the CAl area of rat hippocampal slices. Two NMDA receptor agonists, quinolinic acid 150/lM and homoquinolinic acid 2.5/lM, caused an approximately 50% inhibition of fEPSP slope. Paired-pulse studies suggested there might be a presynaptic component to this action that is independent of presynaptic adenosine Al receptor activation. The broad-spectrum EAA antagonist kynurenic acid and the NMDA receptor blockers 2-amino-5-phosphonopentanoic acid and dizocilpine could prevent the inhibition of fEPSP slope. None of these antagonists revealed any other NMDA-insensitive activity of homoquinolinic acid. The use of 2-carboxy-3-carboxymethylquinoline (CCMQ) to displace the reported NMDA-insensitive binding had no effect on either baseline fEPSP slope or the depression caused by homoquinolinic acid. It was also apparent that responses to homoquinolinic acid were blocked completely by the NR2A subunit-selective antagonist PEAQX, but not by the NR2B subunit-selective blocker Ro 25-6981. It was concluded that the novel binding site for homoquinolinic acid does not affect synaptic potentials in the hippocampus and that homoquinolinic acid appears to be a selective agonist at NMDA receptors that include the NR2A subunit. Although the NR2B agonist site may be maximally activated under normal conditions and therefore it is not possible to observe any additional effects upon fEPSP slope. This study next investigated the negative coupling between NR2B and NR2A subunit-containing receptors, combining the NR2A1B subunit selective agonist HQA with the NR2B and NR2A selective antagonists Ro 25-6981 and PEAQX. The negative coupling observed previously with applications of NMDA was also seen using HQA and QA. The potentiation of responses to HQA by Ro 25-6981 application was also associated with an enhancement of paired-pulse interactions. The subsequent application of PEAQX was able to block both the depression of fEPSP slope and the associated enhancement of paired-pulse interactions. The presence of a presynaptic element during applications of HQA alone and potentiated responses alike and the blockade of these effects by PEAQX suggests the NR2A subunit-containing NMDA receptor is responsible for the presynaptic effects acting either directly at presynaptic sites or indirectly at postsynaptic sites leading to the raising of a retrograde signal. The NR2B subunit in both its activated and antagonised state was associated with enhancements in paired-pulse interactions which suggest that it is not able to modulate directly the presynaptic element. However, whilst paired-pulse interactions are generally accepted to he presynaptic phenomena, it does not follow that postsynaptic effects cannot influence the appearance of changes in these interactions in field recordings. The absence of any observable difference between HQA, QA and NMDA results suggests that the NR2D subunit is not obviously involved in these processes

Physiological and behavioural consequences of network breakdown in brain injury

Traumatic brain injury (TBI) is a major public health problem with a huge unmet need for effective long-term care. Advances in MRI technology using diffusion tensor imaging (DTI) have demonstrated structural abnormalities in patients with TBI, often not seen on conventional brain imaging. The structural and neuropsychological consequences are described in existing research. The aim of this thesis is to identify whether there are physiological and behavioural consequences of TBI, which may be contributing to the observed problems in daily activities associated with this condition. This will help to understand the devastating functional impact following TBI, and its neurorehabilitation needs. This thesis initially develops a study protocol to investigate the physiology in TBI. Initial work explores physiology in thirty four healthy individuals using transcranial magnetic stimulation (TMS) to produce a study protocol that can be used in the patient group. This examined a selection of pathways, including the assessment of callosal physiology using a twin coil TMS method to assess for interhemispheric inhibition. This protocol was used to assess seventeen TBI patients, and compared to healthy controls, and demonstrated that callosal transfer is physiologically different between the two groups. The behavioural consequences of callosal transfer were then explored through the development of a bimanual tapping task in twenty nine healthy participants. The behavioural consequences were then assessed in the same group of TBI patients, and compared to the control group. The TBI patients had comparable mean performance. However, the variability in performance was the main difference between the two groups. The MRI DTI metrics were then investigated in the TBI and control groups. A relationship between the physiology, behaviour and microstructure was then explored. Through this series of investigations this thesis hopes to increase existing understanding of the consequences of brain injury

A neural network model of adaptively timed reinforcement learning and hippocampal dynamics

A neural model is described of how adaptively timed reinforcement learning occurs. The adaptive timing circuit is suggested to exist in the hippocampus, and to involve convergence of dentate granule cells on CA3 pyramidal cells, and NMDA receptors. This circuit forms part of a model neural system for the coordinated control of recognition learning, reinforcement learning, and motor learning, whose properties clarify how an animal can learn to acquire a delayed reward. Behavioral and neural data are summarized in support of each processing stage of the system. The relevant anatomical sites are in thalamus, neocortex, hippocampus, hypothalamus, amygdala, and cerebellum. Cerebellar influences on motor learning are distinguished from hippocampal influences on adaptive timing of reinforcement learning. The model simulates how damage to the hippocampal formation disrupts adaptive timing, eliminates attentional blocking, and causes symptoms of medial temporal amnesia. It suggests how normal acquisition of subcortical emotional conditioning can occur after cortical ablation, even though extinction of emotional conditioning is retarded by cortical ablation. The model simulates how increasing the duration of an unconditioned stimulus increases the amplitude of emotional conditioning, but does not change adaptive timing; and how an increase in the intensity of a conditioned stimulus "speeds up the clock", but an increase in the intensity of an unconditioned stimulus does not. Computer simulations of the model fit parametric conditioning data, including a Weber law property and an inverted U property. Both primary and secondary adaptively timed conditioning are simulated, as are data concerning conditioning using multiple interstimulus intervals (ISIs), gradually or abruptly changing ISis, partial reinforcement, and multiple stimuli that lead to time-averaging of responses. Neurobiologically testable predictions are made to facilitate further tests of the model.Air Force Office of Scientific Research (90-0175, 90-0128); Defense Advanced Research Projects Agency (90-0083); National Science Foundation (IRI-87-16960); Office of Naval Research (N00014-91-J-4100