Multiscale vision model for event detection and reconstruction in two-photon imaging data

Reliable detection of calcium waves in multiphoton imaging data is challenging because of the low signal-to-noise ratio and because of the unpredictability of the time and location of these spontaneous events. This paper describes our approach to calcium wave detection and reconstruction based on a modified multiscale vision model, an object detection framework based on the thresholding of wavelet coefficients and hierarchical trees of significant coefficients followed by nonlinear iterative partial object reconstruction, for the analysis of two-photon calcium imaging data. The framework is discussed in the context of detection and reconstruction of intercellular glial calcium waves. We extend the framework by a different decomposition algorithm and iterative reconstruction of the detected objects. Comparison with several popular state-of-the-art image denoising methods shows that performance of the multiscale vision model is similar in the denoising, but provides a better segmenation of the image into meaningful objects, whereas other methods need to be combined with dedicated thresholding and segmentation utilities

The spatiotemporal dynamics of human focal seizures

Spontaneous human focal seizures can present with a plethora of behavioral manifestations that vary according to the affected cortical regions; however, several key features have been consistently observed. During my doctoral studies, I applied both theoretical and experimental methods to study mechanisms underpinning these consistently seen dynamics. I first analyzed human intracranial EEG recordings, describing statistical methods for measuring their electrophysiological signatures. I next proposed several neurophysiological hypotheses that could explain seizure dynamics and verified them in rodent seizure models. Finally, a computational model was developed, successfully explaining how the complex spatiotemporal evolution of focal seizures emerges from simple neurophysiological principles. In Chapter 1, the long-standing behavioral manifestations and the most up-to-date electrophysiology findings are reviewed. This section details the inspiration for the studies reported in the subsequent chapters. In Chapter 2, I describe several statistical methods for estimating traveling wave velocities. I show most ictal discharges can be described as traveling waves whose velocities contain rich information about the stages of seizure evolution. I compare performance of various statistical methods and propose a robust approach to boost the quality of each method’s estimation results. In Chapter 3, I show how inhibition modulates seizure propagation patterns. Surround inhibition spatially restrains focal seizures and masks excitatory projections of ictal activities. When compromised, two patterns of seizure propagation emerge according to the position of inhibition defects relative to the ictal focus. I show that two distant ictal foci can communicate via physiological connectivity without any chronic rewiring processes – confirming the existence of long-range propagation pathways that could lead to epileptic network formation. In Chapter 4, I show that thalamic inputs might be necessary for interictal epileptiform discharges (IEDs). The relative positions between IEDs and ictal foci indicate that surround inhibition, shown in the previous chapter, can be exhausted by repetitive exposure to ictal projections. In Chapter 5, I propose a neural network model that can explain both long-standing behavioral observations of seizures and account for the most up-to-date electrophysiological recordings of spontaneous human focal seizures. The model relies on few assumptions, all of which are proved or supported in earlier chapters of this thesis. The model explains phasic evolution of seizure dynamics – how the commonly observed patterns arise from simple neurophysiological principles, as well as seizure onset subtypes, traveling wave directions and speeds. The model also predicts how spontaneous seizures might arise from synaptic plasticity. The chapter ends with a discussion of the model’s implications and future work. The thesis is organized in a way that each chapter can be read independently, with Chapter 5 summarizing the central theory spanning the whole study. Each chapter is also tightly linked to a clinically relevant question. In sum, the dissertation’s goal is to provide an in-principle understanding of focal seizure dynamics. With rapid advancement of clinical and experimental tools, I believe this work provides a roadmap for future therapies for epilepsy patients

Neuronal population and network analysis tools for large-scale calcium imaging datasets

Recently developed large scale calcium imaging techniques allow functional analysis of hundreds to thousands of simultaneously recorded individual neurons, resulting in exceedingly large datasets. Conventional analysis methods are not scalable for large imaging datasets collected at high speed and high pixel resolution. The efforts described in this dissertation focus on the development of analysis methods designed for large datasets, along with the application of these analytic methods to derive novel conceptual insights into how neuronal circuits function in both healthy and diseased brains. First, an image processing pipeline and a segmentation toolbox were developed and shared as an open-source software. The processing pipeline is a parallelized version of a recently published motion correction algorithm, but which improved processing speed by 10%. The segmentation toolbox is semi-automated and provides high confidence in the spatial extent of segmented cells, with the option to integrate temporal information for the segmentation. Next, these and additionally developed methods were used to study the effect of mild traumatic brain injury (mTBI) on neuronal circuits over consecutive days. Using a newly developed signal normalization technique, we found that immediately following a blast injury event, neurons exhibited two types of changes in intracellular calcium dynamics at different time scales. One was a reduction in basal intracellular calcium levels on a time scale of minutes. The second was a reduction in the rate of transient calcium fluctuations at the sub-second time scale. Both changes recovered one hour post blast injury, suggesting different types of neuronal damage from mTBI. Lastly, we developed a method that allowed us to observe network differences on a trial-by-trial basis with a limited number of data points. We utilized these analysis tools to study hippocampal network responses during two learning processes, trace conditioning and extinction learning. We found a similar pattern of neuronal dynamics for both learning processes, however the single-neuron identities for each process was unique. Overall, this dissertation describes a set of image processing, segmentation, and network analysis tools for large scale calcium imaging datasets, which were applied to analyze network changes during learning and externally induced by mTBI

29th Annual Computational Neuroscience Meeting: CNS*2020

Meeting abstracts This publication was funded by OCNS. The Supplement Editors declare that they have no competing interests. Virtual | 18-22 July 202

The Impact of Mild Traumatic Brain injury on Neuronal Networks and Neurobehavior

Despite its enormous incidence, mild traumatic brain injury is not well understood. One aspect that needs more definition is how the mechanical energy during injury affects neural circuit function. Recent developments in cellular imaging probes provide an opportunity to assess the dynamic state of neural networks with single-cell resolution. In this dissertation, we developed imaging methods to assess the state of dissociated cortical networks exposed to mild injury. We probed the microarchitecture of an injured cortical circuit subject to two different injury levels, mild stretch (10% peak) and mild/moderate (35%). We found that mild injury produced a transient increase in calcium activity that dissipated within 1 h after injury. Alternatively, mild/moderate mechanical injury produced immediate disruption in network synchrony, loss in excitatory tone, and increased modular topology, suggesting a threshold for repair and degradation. The more significant changes in network behavior at moderate stretch are influenced by NMDA receptor activation and subsequent proteolytic changes in the neuronal populations. With the ability to analyze individual neurons in a circuit before and after injury, we identified several biomarkers that confer increased risk or protection from mechanical injury. We found that pre-injury connectivity and NMDA receptor subtype composition (NR2A and NR2B content) are important predictors of node loss and remodeling. Mechanistically, stretch injury caused a reduction in voltage-dependent Mg2+ block of the NR2B-cotaning NMDA receptors, resulting in increased uncorrelated activity both at the single channel and network level. The reduced coincidence detection of the NMDA receptor and overactivation of these receptors further impaired network function and plasticity. Given the demonstrated link between NR2B-NMDARs and mitochondrial dysfunction, we discovered that neuronal de-integration from the network is mediated through mitochondrial signaling. Finally, we bridged these network level studies with an investigation of changes in neurobehavior following blast-induced traumatic brain injury (bTBI), a form of mild TBI. We first developed and validated an open-source toolbox for automating the scoring of several common behavior tasks to study the deficits that occur following bTBI. We then specifically evaluated the role of neuronal transcription factor Elk-1 in mediating deficits following blast by exposing Elk-1 knockout mouse to equivalent blast pressure loading. Our systems-level behavior analysis showed that bTBI creates a complex change in behavior, with an increase in anxiety and loss of habituation in object recognition. Moreover, we found these behavioral deficits were eliminated in Elk-1 knockout animals exposed to blast loading. Together, we merged information from different perspectives (in silico, in vitro, and in vivo) and length scales (single channels, single-cells, networks, and animals) to study the impact of mild traumatic brain injury on neuronal networks and neurobehavior

Activation of the pro-resolving receptor Fpr2 attenuates inflammatory microglial activation

Poster number: P-T099 Theme: Neurodegenerative disorders & ageing Activation of the pro-resolving receptor Fpr2 reverses inflammatory microglial activation Authors: Edward S Wickstead - Life Science & Technology University of Westminster/Queen Mary University of London Inflammation is a major contributor to many neurodegenerative disease (Heneka et al. 2015). Microglia, as the resident immune cells of the brain and spinal cord, provide the first line of immunological defence, but can become deleterious when chronically activated, triggering extensive neuronal damage (Cunningham, 2013). Dampening or even reversing this activation may provide neuronal protection against chronic inflammatory damage. The aim of this study was to determine whether lipopolysaccharide (LPS)-induced inflammation could be abrogated through activation of the receptor Fpr2, known to play an important role in peripheral inflammatory resolution. Immortalised murine microglia (BV2 cell line) were stimulated with LPS (50ng/ml) for 1 hour prior to the treatment with one of two Fpr2 ligands, either Cpd43 or Quin-C1 (both 100nM), and production of nitric oxide (NO), tumour necrosis factor alpha (TNFα) and interleukin-10 (IL-10) were monitored after 24h and 48h. Treatment with either Fpr2 ligand significantly suppressed LPS-induced production of NO or TNFα after both 24h and 48h exposure, moreover Fpr2 ligand treatment significantly enhanced production of IL-10 48h post-LPS treatment. As we have previously shown Fpr2 to be coupled to a number of intracellular signaling pathways (Cooray et al. 2013), we investigated potential signaling responses. Western blot analysis revealed no activation of ERK1/2, but identified a rapid and potent activation of p38 MAP kinase in BV2 microglia following stimulation with Fpr2 ligands. Together, these data indicate the possibility of exploiting immunomodulatory strategies for the treatment of neurological diseases, and highlight in particular the important potential of resolution mechanisms as novel therapeutic targets in neuroinflammation. References Cooray SN et al. (2013). Proc Natl Acad Sci U S A 110: 18232-7. Cunningham C (2013). Glia 61: 71-90. Heneka MT et al. (2015). Lancet Neurol 14: 388-40

Early postnatal development of neocortex-wide activity patterns in GABAergic and pyramidal neurons

Before the onset of sensory experience, developing circuits generate synchronised activity that will not only influence its wiring, but ultimately contribute to behaviour. These complex functions rely on widely distributed cortical that simultaneously operate at multiple spatiotemporal scales. The timing of GABAergic maturation appears to align with the developmental trajectories of cortical regions, playing a crucial role in the functional development of individual brain areas. While local connectivity in cortical microcircuits has been extensively studied, the dynamics of brain-wide functional maturation, especially for GABAergic populations, remain underexplored. In this project, a dual-colour widefield calcium imaging approach was developed to examine the neocortex-wide dynamics of cortical GABAergic and excitatory neurons simultaneously across early postnatal development. This study provides the first broad description of neocortex-wide GABAergic developmental trajectories and their cross-talk with excitatory dynamics during the second and third postnatal weeks. The observed spontaneous activity revealed discrete activity domains, reflecting the modular organisation of the cortex. Both excitatory and GABAergic population exhibited an increase in the size and frequency of activity motifs, as well as changes in motif variability. However, as they matured, the distribution of these spatiotemporal properties displayed divergent trajectories across populations and regions. These findings suggest fundamental differences in the spatial organisation of both populations, indicating potential distinct roles in cortical network function development. Moreover, while excitatory and GABAergic dynamics exhibited high correlations, brief deviations from perfect timing were observed. This correlation patterns changed significantly during development and across regions, with the two populations gradually becoming more correlated as they matured. Manipulating inhibition in vivo disrupted these fluctuations, impacting both local activity and the wider functional network.These findings provide valuable insights into the developmental trajectories of spontaneous activity patterns in excitatory and GABAergic cell populations during early postnatal development. The interplay between both neuronal populations plays a critical role in shaping activity patterns, and understanding the underlying mechanisms of their development can provide valuable insights into neurodevelopmental disorders

Neural Bursting Activity Mediates Subtype-Specific Neural Regeneration by an L-type Calcium Channel

Axons are injured after stroke, spinal cord injury, or neurodegenerative disease such as ALS. Most axons do not regenerate. A recent report suggests that not all neurons are poor regenerators, but rather a small subset can regenerate robustly. What intrinsic property of these regenerating neurons allows them to regenerate, but not their neighbors, remains a mystery. This subtype-specific regeneration has also been observed in Drosophila larvae sensory neurons. We exploited this powerful genetic system to unravel the intrinsic mechanism of subtype-specific neuron regeneration. We found that neuron bursting activity after axotomy correlates with regeneration ability. Furthermore, neuron bursting activity is necessary for regeneration of a regenerative neuron subtype, and sufficient for regeneration of a non-regenerative neuron subtype. This optogenetically-induced regeneration is dependent on a bursting pattern, not simply overall activity increase. We conclude that neuron bursting activity is an intrinsic mechanism of subtype-specific regeneration. We then discovered through a reverse genetic screen that an L-type voltage gated calcium channel (VGCC) promotes neuron bursting and subsequent regeneration. This VGCC has high expression in the regenerative neuron and weak expression in the non-regenerative neuron. This suggests that VGCC expression level is the molecular mechanism of subtype-specific neuron regeneration. Together, our findings identify a cellular and molecular intrinsic mechanism of subtype-specific regeneration, which is why some neurons are able to regenerate while the majority of neurons do not. Perhaps VGCC activation or neuron activity pattern modulation could be used therapeutically for patients with nerve injury