Effects of stimulus pulse rate on somatosensory adaptation in the human cortex

BackgroundIntracortical microstimulation (ICMS) of the somatosensory cortex can restore sensation to people with neurological diseases. However, many aspects of ICMS are poorly understood, including the effect of continuous stimulation on percept intensity over time.ObjectiveHere, we evaluate how tactile percepts, evoked by ICMS in the somatosensory cortex of a human participant adapt over time.MethodsWe delivered continuous and intermittent ICMS to the somatosensory cortex and assessed the reported intensity of tactile percepts over time in a human participant. Experiments were conducted across approximately one year and linear mixed effects models were used to assess significance.ResultsContinuous stimulation at high frequencies led to rapid decreases in intensity, while low frequency stimulation maintained percept intensity for longer periods. Burst-modulated stimulation extended the time before the intensity began to decrease, but all protocols ultimately resulted in complete sensation loss within one minute. Intermittent stimulation paradigms with several seconds between stimulus trains also led to decreases in intensity on many electrodes, but never resulted in extinction of sensation after over three minutes of stimulation. Additionally, longer breaks between each pulse train resulted in some recovery of the stimulus-evoked percepts. For several electrodes, intermittent stimulation had almost no effect on the perceived intensity.ConclusionsIntermittent ICMS paradigms were more effective at maintaining percepts, and given that transient activity in the somatosensory cortex dominates the response to object contact, this stimulation method may mimic natural cortical activity and improve the perception of stimulation over time.

Genome-Wide Analysis of the TCP Transcription Factor Genes in Dendrobium catenatum Lindl.

Teosinte branched1/cycloidea/proliferating cell factor (TCP) gene family members are plant-specific transcription factors that regulate plant growth and development by controlling cell proliferation and differentiation. However, there are no reported studies on the TCP gene family in Dendrobium catenatum Lindl. Here, a genome-wide analysis of TCP genes was performed in D. catenatum, and 25 TCP genes were identified. A phylogenetic analysis classified the family into two clades: Class I and Class II. Genes in the same clade share similar conserved motifs. The GFP signals of the DcaTCP-GFPs were detected in the nuclei of tobacco leaf epidermal cells. The activity of DcaTCP4, which contains the miR319a-binding sequence, was reduced when combined with miR319a. A transient activity assay revealed antagonistic functions of Class I and Class II of the TCP proteins in controlling leaf development through the jasmonate-signaling pathway. After different phytohormone treatments, the DcaTCP genes showed varied expression patterns. In particular, DcaTCP4 and DcaTCP9 showed opposite trends after 3 h treatment with jasmonate. This comprehensive analysis provides a foundation for further studies on the roles of TCP genes in D. catenatum.

Concluding comments and new challenges

This chapter emphasises that the Shikoku pilgrimage is not a singular transient event but a recurrent thread in the lives of pilgrims, many of whom plan to continue doing it until they die or are physically unable. They often also do other pilgrimages and have a primary identity as pilgrims. Pilgrimage is unending while the image of life itself as pilgrimage permeates popular understandings of the Shikoku pilgrimage. We introduce a Shikoku pilgrimage T-shirt that symbolically reflects this view of pilgrimage as infinite and unending, arguing that such themes are not unique to Shikoku, although they have rarely been discussed in studies of pilgrimage. Researchers need to look more closely at the issues discussed in this book, for Shikoku pilgrimage shows that pilgrimage is not a transient activity but a life course that pilgrims view as unending.

Pilgrims Until We Die

The Shikoku pilgrimage, a 1400-kilometre, eighty-eight-temple circuit around Japan’s fourth largest island, takes around forty days by foot and a week by car. Historically Buddhist ascetics walked it incessantly, creating a tradition of unending pilgrimage that continues in the present era, both by pilgrims on foot and by those in cars. Some spend decades walking the pilgrimage, while others drive repeatedly and do hundreds of pilgrimage circuits. Most are retired and make the pilgrimage the centre of their post-work lives, while others work full-time but spend their free time and weekends as pilgrims. Some have only done the pilgrimage a few times but already imagine themselves as unending pilgrims and intend to do it ‘until we die’. They talk, happily, of being addicted and having Shikokubyō, ‘Shikoku illness’, while portraying such ‘illness’ and addiction as blessings. This book, based in extensive fieldwork, shows that unending pilgrimage is the dominant theme of the Shikoku pilgrimage and argues that this is not specific to Shikoku but found widely in global contexts, although it has barely been examined in studies of pilgrimage. It counteracts normative portrayals of pilgrimage as a transient activity involving temporarily leaving home to visit sacred places outside the everyday parameters of life; rather, pilgrimage for many participants means creating a sense of home and permanence on the road. As such this book presents new theoretical perspectives on pilgrimage in general, along with rich ethnographic examples of pilgrimage practices in contemporary Japan.

Increased theta/alpha synchrony in the habenula-prefrontal network with negative emotional stimuli in human patients

Lateral habenula is believed to encode negative motivational stimuli and plays key roles in the pathophysiology of psychiatric disorders. However, how habenula activities are modulated during the processing of emotional information is still poorly understood. We recorded local field potentials from bilateral habenula areas with simultaneous cortical magnetoencephalography in nine patients with psychiatric disorders during an emotional picture-viewing task. Transient activity in the theta/alpha band (5–10 Hz) within the habenula and prefrontal cortical regions, as well as the coupling between these structures, is increased during the perception and processing of negative emotional stimuli compared to positive emotional stimuli. The increase in theta/alpha band synchronization in the frontal cortex-habenula network correlated with the emotional valence but not the arousal score of the stimuli. These results provide direct evidence for increased theta/alpha synchrony within the habenula area and prefrontal cortex-habenula network in the perception of negative emotion in human participants.

Transient dopamine neuron activity precedes and encodes the vigor of contralateral movements

SummaryDopamine neurons (DANs) in the substantia nigra pars compacta (SNc) have been related to movement vigor, and loss of these neurons leads to bradykinesia in Parkinson’s disease. However, it remains unclear whether DANs encode a general motivation signal or modulate movement kinematics. We imaged activity of SNc DANs in mice trained in a novel operant task which relies on individual forelimb movement sequences. We uncovered that a similar proportion of SNc DANs increased their activity before ipsi- vs. contralateral forelimb movements. However, the magnitude of this activity was higher for contralateral actions, and was related to contralateral but not ipsilateral action vigor. In contrast, the activity of reward-related DANs, largely distinct from those modulated by movement, was not lateralized. Finally, unilateral dopamine depletion impaired contralateral, but not ipsilateral, movement vigor. These results indicate that movement-initiation DANs encode more than a general motivation signal, and invigorate kinematic aspects of contralateral movements.HighlightsDeveloped a freely-moving task where mice learn rapid individual forelimb sequences.Movement-related DANs encode contralateral but not ipsilateral action vigor.The activity of reward-related DANs is not lateralized.Unilateral dopamine depletion impaired contralateral, but not ipsilateral, movement vigor.eTOC summary: Mendonça et al. show that transient activity in movement-related dopamine neurons in substantia nigra pars compacta encodes contralateral, but not ipsilateral action vigor. Consistently, unilateral dopamine depletion impaired contralateral, but not ipsilateral, movement vigor.

Interacting synapses stabilise both learning and neuronal dynamics in biological networks

Distinct synapses influence one another when they undergo changes, with unclear consequences for neuronal dynamics and function. Here we show that synapses can interact such that excitatory currents are naturally normalised and balanced by inhibitory inputs. This happens when classical spike-timing dependent synaptic plasticity rules are extended by additional mechanisms that incorporate the influence of neighbouring synaptic currents and regulate the amplitude of their efficacy changes accordingly. The resulting control of excitatory plasticity by inhibitory activation, and vice versa, gives rise to quick and long-lasting memories as seen experimentally in receptive field plasticity paradigms. In models with additional dendritic structure, we observe experimentally reported clustering of co-active synapses that depends on initial connectivity and morphology. Finally, in recurrent neuronal networks, rich and stable dynamics with high input sensitivity emerge, providing transient activity that resembles recordings from motor cortex. Our model provides a general framework for codependent plasticity that frames individual synaptic modifications in the context of population-wide changes, allowing us to connect micro-level physiology with network-wide phenomena.

How the anisotropy of surface oxide formation influences the transient activity of a surface reaction

Scanning photoelectron microscopy (SPEM) and photoemission electron microscopy (PEEM) allow local surface analysis and visualising ongoing reactions on a µm-scale. These two spatio-temporal imaging methods are applied to polycrystalline Rh, representing a library of well-defined high-Miller-index surface structures. The combination of these techniques enables revealing the anisotropy of surface oxidation, as well as its effect on catalytic hydrogen oxidation. In the present work we observe, using locally-resolved SPEM, structure-sensitive surface oxide formation, which is summarised in an oxidation map and quantitatively explained by the novel step density (SDP) and step edge (SEP) parameters. In situ PEEM imaging of ongoing H2 oxidation allows a direct comparison of the local reactivity of metallic and oxidised Rh surfaces for the very same different stepped surface structures, demonstrating the effect of Rh surface oxides. Employing the velocity of propagating reaction fronts as indicator of surface reactivity, we observe a high transient activity of Rh surface oxide in H2 oxidation. The corresponding velocity map reveals the structure-dependence of such activity, representing a direct imaging of a structure-activity relation for plenty of well-defined surface structures within one sample.

An Automated Pipeline for Image Processing and Data Treatment to Track Activity Rhythms of Paragorgia arborea in Relation to Hydrographic Conditions

Imaging technologies are being deployed on cabled observatory networks worldwide. They allow for the monitoring of the biological activity of deep-sea organisms on temporal scales that were never attained before. In this paper, we customized Convolutional Neural Network image processing to track behavioral activities in an iconic conservation deep-sea species—the bubblegum coral Paragorgia arborea—in response to ambient oceanographic conditions at the Lofoten-Vesterålen observatory. Images and concomitant oceanographic data were taken hourly from February to June 2018. We considered coral activity in terms of bloated, semi-bloated and non-bloated surfaces, as proxy for polyp filtering, retraction and transient activity, respectively. A test accuracy of 90.47% was obtained. Chronobiology-oriented statistics and advanced Artificial Neural Network (ANN) multivariate regression modeling proved that a daily coral filtering rhythm occurs within one major dusk phase, being independent from tides. Polyp activity, in particular extrusion, increased from March to June, and was able to cope with an increase in chlorophyll concentration, indicating the existence of seasonality. Our study shows that it is possible to establish a model for the development of automated pipelines that are able to extract biological information from times series of images. These are helpful to obtain multidisciplinary information from cabled observatory infrastructures.