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28 results on '"Oberlaender, Marcel"'

1. BigNeuron: a resource to benchmark and predict performance of algorithms for automated tracing of neurons in light microscopy datasets

Author

Manubens-Gil, Linus, Zhou, Zhi, Chen, Hanbo, Ramanathan, Arvind, Liu, Xiaoxiao, Liu, Yufeng, Bria, Alessandro, Gillette, Todd, Ruan, Zongcai, Yang, Jian, Radojević, Miroslav, Zhao, Ting, Cheng, Li, Qu, Lei, Liu, Siqi, Bouchard, Kristofer E., Gu, Lin, Cai, Weidong, Ji, Shuiwang, Roysam, Badrinath, Wang, Ching-Wei, Yu, Hongchuan, Sironi, Amos, Iascone, Daniel Maxim, Zhou, Jie, Bas, Erhan, Conde-Sousa, Eduardo, Aguiar, Paulo, Li, Xiang, Li, Yujie, Nanda, Sumit, Wang, Yuan, Muresan, Leila, Fua, Pascal, Ye, Bing, He, Hai-yan, Staiger, Jochen F., Peter, Manuel, Cox, Daniel N., Simonneau, Michel, Oberlaender, Marcel, Jefferis, Gregory, Ito, Kei, Gonzalez-Bellido, Paloma, Kim, Jinhyun, Rubel, Edwin, Cline, Hollis T., Zeng, Hongkui, Nern, Aljoscha, Chiang, Ann-Shyn, Yao, Jianhua, Roskams, Jane, Livesey, Rick, Stevens, Janine, Liu, Tianming, Dang, Chinh, Guo, Yike, Zhong, Ning, Tourassi, Georgia, Hill, Sean, Hawrylycz, Michael, Koch, Christof, Meijering, Erik, Ascoli, Giorgio A., and Peng, Hanchuan

Published
2023
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2. Network-neuron interactions underlying sensory responses of layer 5 pyramidal tract neurons in barrel cortex.

Author

Bast, Arco, Fruengel, Rieke, de Kock, Christiaan P. J., and Oberlaender, Marcel

Subjects
PYRAMIDAL neurons, ACTION potentials, SENSORY stimulation, CEREBRAL cortex, MULTISCALE modeling, PYRAMIDAL tract
Abstract

Neurons in the cerebral cortex receive thousands of synaptic inputs per second from thousands of presynaptic neurons. How the dendritic location of inputs, their timing, strength, and presynaptic origin, in conjunction with complex dendritic physiology, impact the transformation of synaptic input into action potential (AP) output remains generally unknown for in vivo conditions. Here, we introduce a computational approach to reveal which properties of the input causally underlie AP output, and how this neuronal input-output computation is influenced by the morphology and biophysical properties of the dendrites. We demonstrate that this approach allows dissecting of how different input populations drive in vivo observed APs. For this purpose, we focus on fast and broadly tuned responses that pyramidal tract neurons in layer 5 (L5PTs) of the rat barrel cortex elicit upon passive single whisker deflections. By reducing a multi-scale model that we reported previously, we show that three features are sufficient to predict with high accuracy the sensory responses and receptive fields of L5PTs under these specific in vivo conditions: the count of active excitatory versus inhibitory synapses preceding the response, their spatial distribution on the dendrites, and the AP history. Based on these three features, we derive an analytically tractable description of the input-output computation of L5PTs, which enabled us to dissect how synaptic input from thalamus and different cell types in barrel cortex contribute to these responses. We show that the input-output computation is preserved across L5PTs despite morphological and biophysical diversity of their dendrites. We found that trial-to-trial variability in L5PT responses, and cell-to-cell variability in their receptive fields, are sufficiently explained by variability in synaptic input from the network, whereas variability in biophysical and morphological properties have minor contributions. Our approach to derive analytically tractable models of input-output computations in L5PTs provides a roadmap to dissect network-neuron interactions underlying L5PT responses across different in vivo conditions and for other cell types. Author summary: Revealing how synaptic inputs drive action potential output is one of the major challenges in neuroscience research. An increasing number of approaches therefore seek to combine detailed measurements at synaptic, cellular and network scales into biologically realistic brain models. Indeed, such models have started to make empirically testable predictions about the inputs that underlie in vivo observed activity patterns. However, the enormous complexity of these models generally prevents the derivation of interpretable descriptions that explain how neurons transform synaptic input into action potential output, and how these input-output computations depend on synaptic, cellular and network properties. Here we introduce an approach to reveal input-output computations that neurons in the cerebral cortex perform upon sensory stimulation. For this purpose, we reduce a realistic multi-scale model of the rat barrel cortex to the minimal description that accounts for in vivo observed responses to whisker stimuli. Thereby, we identify the input-output computation that these cortical neurons perform under this in vivo condition, and we show that this computation is preserved across neurons despite morphological and biophysical diversity. Our approach provides analytically tractable and hence interpretable descriptions of neuronal input-output computations during specific in vivo conditions. [ABSTRACT FROM AUTHOR]

Published
2024
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5. Simulation-based inference for efficient identification of generative models in computational connectomics.

Author

Boelts, Jan, Harth, Philipp, Gao, Richard, Udvary, Daniel, Yáñez, Felipe, Baum, Daniel, Hege, Hans-Christian, Oberlaender, Marcel, and Macke, Jakob H.

Subjects
DEEP learning, DISTRIBUTION (Probability theory), BAYESIAN field theory, INFERENTIAL statistics, MACHINE learning, NEURAL circuitry
Abstract

Recent advances in connectomics research enable the acquisition of increasing amounts of data about the connectivity patterns of neurons. How can we use this wealth of data to efficiently derive and test hypotheses about the principles underlying these patterns? A common approach is to simulate neuronal networks using a hypothesized wiring rule in a generative model and to compare the resulting synthetic data with empirical data. However, most wiring rules have at least some free parameters, and identifying parameters that reproduce empirical data can be challenging as it often requires manual parameter tuning. Here, we propose to use simulation-based Bayesian inference (SBI) to address this challenge. Rather than optimizing a fixed wiring rule to fit the empirical data, SBI considers many parametrizations of a rule and performs Bayesian inference to identify the parameters that are compatible with the data. It uses simulated data from multiple candidate wiring rule parameters and relies on machine learning methods to estimate a probability distribution (the 'posterior distribution over parameters conditioned on the data') that characterizes all data-compatible parameters. We demonstrate how to apply SBI in computational connectomics by inferring the parameters of wiring rules in an in silico model of the rat barrel cortex, given in vivo connectivity measurements. SBI identifies a wide range of wiring rule parameters that reproduce the measurements. We show how access to the posterior distribution over all data-compatible parameters allows us to analyze their relationship, revealing biologically plausible parameter interactions and enabling experimentally testable predictions. We further show how SBI can be applied to wiring rules at different spatial scales to quantitatively rule out invalid wiring hypotheses. Our approach is applicable to a wide range of generative models used in connectomics, providing a quantitative and efficient way to constrain model parameters with empirical connectivity data. Author summary: The brain is composed of an intricately connected network of cells—what are the principles that contribute to constructing these patterns of connectivity, and how? To answer these questions, amassing connectivity data alone is not enough. We must also be able to efficiently develop and test our ideas about the underlying connectivity principles. For example, we could simulate a hypothetical wiring rule like "neurons near each other are more likely to form connections" in a computational model and generate corresponding synthetic data. If the synthetic, simulated data resembles the real, measured data, then we have some confidence that our hypotheses might be correct. However, the proposed wiring rules usually have unknown parameters that we need to "tune" such that simulated data matches the measurements. The central challenge thus lies in finding all the potential parametrizations of a wiring rule that can reproduce the measured data, as this process is often idiosyncratic and labor-intensive. To tackle this challenge, we introduce an approach combining computational modeling in connectomics, deep learning, and Bayesian statistical inference to automatically infer a probability distribution over the model parameters likely to explain the data. We demonstrate our approach by inferring the parameters of a wiring rule in a detailed model of the rat barrel cortex and find that the inferred distribution identifies multiple data-compatible model parameters, reveals biologically plausible parameter interactions, and allows us to make experimentally testable predictions. [ABSTRACT FROM AUTHOR]

Published
2023
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12. Morphological characterization of HVC projection neurons in the zebra finch (<italic>Taeniopygia guttata</italic>).

Author

Benezra, Sam E., Narayanan, Rajeevan T., Egger, Robert, Oberlaender, Marcel, and Long, Michael A.

Abstract

Abstract: Singing behavior in the adult male zebra finch is dependent upon the activity of a cortical region known as HVC (proper name). The vast majority of HVC projection neurons send primary axons to either the downstream premotor nucleus RA (robust nucleus of the arcopallium, or primary motor cortex) or Area X (basal ganglia), which play important roles in song production or song learning, respectively. In addition to these long‐range outputs, HVC neurons also send local axon collaterals throughout that nucleus. Despite their implications for a range of circuit models, these local processes have never been completely reconstructed. Here, we use in vivo single‐neuron Neurobiotin fills to examine 40 projection neurons across 31 birds with somatic positions distributed across HVC. We show that HVC(RA) and HVC(X) neurons have categorically distinct dendritic fields. Additionally, these cell classes send axon collaterals that are either restricted to a small portion of HVC (“local neurons”) or broadly distributed throughout the entire nucleus (“broadcast neurons”). Overall, these processes within HVC offer a structural basis for significant local processing underlying behaviorally relevant population activity. [ABSTRACT FROM AUTHOR]

Published
2018
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13. Cell Type-Specific Structural Organization of the Six Layers in Rat Barrel Cortex.

Author

Narayanan, Rajeevan T., Udvary, Daniel, and Oberlaender, Marcel

Subjects
CYTOARCHITECTONICS, NEOCORTEX, BRAIN imaging, NEUROPHYSIOLOGY, EXCITATORY amino acids, DISEASES
Abstract

The cytoarchitectonic subdivision of the neocortex into six layers is often used to describe the organization of the cortical circuitry, sensory-evoked signal flow or cortical functions. However, each layer comprises neuronal cell types that have different genetic, functional and/or structural properties. Here, we reanalyze structural data from some of our recent work in the posterior-medial barrel-subfield of the vibrissal part of rat primary somatosensory cortex (vS1). We quantify the degree to which somata, dendrites and axons of the 10 major excitatory cell types of the cortex are distributed with respect to the cytoarchitectonic organization of vS1.We show that within each layer, somata of multiple cell types intermingle, but that each cell type displays dendrite and axon distributions that are aligned to specific cytoarchitectonic landmarks. The resultant quantification of the structural composition of each layer in terms of the cell type-specific number of somata, dendritic and axonal path lengths will aid future studies to bridge between layer- and cell type-specific analyses. [ABSTRACT FROM AUTHOR]

Published
2017
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14. Relationships between structure, in vivo function and long-range axonal target of cortical pyramidal tract neurons.

Author

Rojas-Piloni, Gerardo, Guest, Jason M., Egger, Robert, Johnson, Andrew S., Sakmann, Bert, and Oberlaender, Marcel

Abstract

Pyramidal tract neurons (PTs) represent the major output cell type of the neocortex. To investigate principles of how the results of cortical processing are broadcasted to different downstream targets thus requires experimental approaches, which provide access to the in vivo electrophysiology of PTs, whose subcortical target regions are identified. On the example of rat barrel cortex (vS1), we illustrate that retrograde tracer injections into multiple subcortical structures allow identifying the long-range axonal targets of individual in vivo recorded PTs. Here we report that soma depth and dendritic path lengths within each cortical layer of vS1, as well as spiking patterns during both periods of ongoing activity and during sensory stimulation, reflect the respective subcortical target regions of PTs. We show that these cellular properties result in a structure–function parameter space that allows predicting a PT’s subcortical target region, without the need to inject multiple retrograde tracers. [ABSTRACT FROM AUTHOR]

Published
2017
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16. Circuit-selective cell-autonomous regulation of inhibition in pyramidal neurons by Ste20-like kinase.

Author

Royero, Pedro, Quatraccioni, Anne, Früngel, Rieke, Silva, Mariella Hurtado, Bast, Arco, Ulas, Thomas, Beyer, Marc, Opitz, Thoralf, Schultze, Joachim L., Graham, Mark E., Oberlaender, Marcel, Becker, Albert, Schoch, Susanne, and Beck, Heinz

Abstract

Maintaining an appropriate balance between excitation and inhibition is critical for neuronal information processing. Cortical neurons can cell-autonomously adjust the inhibition they receive to individual levels of excitatory input, but the underlying mechanisms are unclear. We describe that Ste20-like kinase (SLK) mediates cell-autonomous regulation of excitation-inhibition balance in the thalamocortical feedforward circuit, but not in the feedback circuit. This effect is due to regulation of inhibition originating from parvalbumin-expressing interneurons, while inhibition via somatostatin-expressing interneurons is unaffected. Computational modeling shows that this mechanism promotes stable excitatory-inhibitory ratios across pyramidal cells and ensures robust and sparse coding. Patch-clamp RNA sequencing yields genes differentially regulated by SLK knockdown, as well as genes associated with excitation-inhibition balance participating in transsynaptic communication and cytoskeletal dynamics. These data identify a mechanism for cell-autonomous regulation of a specific inhibitory circuit that is critical to ensure that a majority of cortical pyramidal cells participate in information coding. [Display omitted] • SLK regulates excitation-inhibition balance cell-autonomously • SLK in cortical neurons regulates feedforward but not feedback inhibition • SLK selectively regulates inhibition by parvalbumin-expressing interneurons Royero et al. identify a mechanism relying on Ste20-like kinase that allows single cortical neurons to cell-autonomously adjust feedforward inhibition they receive to the cell-specific levels of excitatory input. They propose that this mechanism is critical to ensure that a majority of cortical pyramidal cells participate in information coding. [ABSTRACT FROM AUTHOR]

Published
2022
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18. Generation of dense statistical connectomes from sparse morphological data.

Author

Egger, Robert, Dercksen, Vincent J., Udvary, Daniel, Hege, Hans-Christian, and Oberlaender, Marcel

Subjects
BRAIN mapping, NEURAL circuitry, SYNAPSES, CEREBRAL cortex, THALAMUS, AXONS, DENDRITES
Abstract

Sensory-evoked signal flow, at cellular and network levels, is primarily determined by the synaptic wiring of the underlying neuronal circuitry. Measurements of synaptic innervation, connection probabilities and subcellular organization of synaptic inputs are thus among the most active fields of research in contemporary neuroscience. Methods to measure these quantities range from electrophysiological recordings over reconstructions of dendrite-axon overlap at light-microscopic levels to dense circuit reconstructions of small volumes at electron-microscopic resolution. However, quantitative and complete measurements at subcellular resolution and mesoscopic scales to obtain all local and long-range synaptic in/outputs for any neuron within an entire brain region are beyond present methodological limits. Here, we present a novel concept, implemented within an interactive software environment called NeuroNet, which allows (i) integration of sparsely sampled (sub)cellular morphological data into an accurate anatomical reference frame of the brain region(s) of interest, (ii) up-scaling to generate an average dense model of the neuronal circuitry within the respective brain region(s) and (iii) statistical measurements of synaptic innervation between all neurons within the model. We illustrate our approach by generating a dense average model of the entire rat vibrissal cortex, providing the required anatomical data, and illustrate how to measure synaptic innervation statistically. Comparing our results with data from paired recordings in vitro and in vivo, as well as with reconstructions of synaptic contact sites at light- and electron-microscopic levels, we find that our in silico measurements are in line with previous results. [ABSTRACT FROM AUTHOR]

Published
2014
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19. The impact of neuron morphology on cortical network architecture.

Author

Udvary, Daniel, Harth, Philipp, Macke, Jakob H., Hege, Hans-Christian, de Kock, Christiaan P.J., Sakmann, Bert, and Oberlaender, Marcel

Abstract

The neurons in the cerebral cortex are not randomly interconnected. This specificity in wiring can result from synapse formation mechanisms that connect neurons, depending on their electrical activity and genetically defined identity. Here, we report that the morphological properties of the neurons provide an additional prominent source by which wiring specificity emerges in cortical networks. This morphologically determined wiring specificity reflects similarities between the neurons' axo-dendritic projections patterns, the packing density, and the cellular diversity of the neuropil. The higher these three factors are, the more recurrent is the topology of the network. Conversely, the lower these factors are, the more feedforward is the network's topology. These principles predict the empirically observed occurrences of clusters of synapses, cell type-specific connectivity patterns, and nonrandom network motifs. Thus, we demonstrate that wiring specificity emerges in the cerebral cortex at subcellular, cellular, and network scales from the specific morphological properties of its neuronal constituents. [Display omitted] • Neuronal network architectures reflect the morphologies of their constituents • Morphology predicts nonrandom connectivity from subcellular to network scales • Morphology predicts connectivity patterns consistent with those observed empirically • Neuron morphology is a major source for wiring specificity in the cerebral cortex Udvary et al. reveal four basic principles by which the morphological properties of the neurons shape the specific architecture of the networks they form. These principles can account for nonrandom connectivity patterns that are observed empirically between the neurons in the cerebral cortex at subcellular, cellular, and network scales. [ABSTRACT FROM AUTHOR]

Published
2022
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20. 3D Reconstruction and Standardization of the Rat Vibrissal Cortex for Precise Registration of Single Neuron Morphology.

Author

Egger, Robert, Narayanan, Rajeevan T., Helmstaedter, Moritz, de Kock, Christiaan P. J., and Oberlaender, Marcel

Subjects
NEURONS, CEREBRAL cortex, THREE-dimensional imaging, WHISKERS, IMAGE reconstruction, WHITE matter (Nerve tissue), LABORATORY rats, ANATOMY
Abstract

The three-dimensional (3D) structure of neural circuits is commonly studied by reconstructing individual or small groups of neurons in separate preparations. Investigation of structural organization principles or quantification of dendritic and axonal innervation thus requires integration of many reconstructed morphologies into a common reference frame. Here we present a standardized 3D model of the rat vibrissal cortex and introduce an automated registration tool that allows for precise placement of single neuron reconstructions. We (1) developed an automated image processing pipeline to reconstruct 3D anatomical landmarks, i.e., the barrels in Layer 4, the pia and white matter surfaces and the blood vessel pattern from high-resolution images, (2) quantified these landmarks in 12 different rats, (3) generated an average 3D model of the vibrissal cortex and (4) used rigid transformations and stepwise linear scaling to register 94 neuron morphologies, reconstructed from in vivo stainings, to the standardized cortex model. We find that anatomical landmarks vary substantially across the vibrissal cortex within an individual rat. In contrast, the 3D layout of the entire vibrissal cortex remains remarkably preserved across animals. This allows for precise registration of individual neuron reconstructions with approximately 30 μm accuracy. Our approach could be used to reconstruct and standardize other anatomically defined brain areas and may ultimately lead to a precise digital reference atlas of the rat brain. [ABSTRACT FROM AUTHOR]

Published
2012
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21. Sensory Experience Restructures Thalamocortical Axons during Adulthood

Author

Oberlaender, Marcel, Ramirez, Alejandro, and Bruno, Randy M.

Subjects
*THALAMOCORTICAL system, *AXONS, *NEURONS, *ADULTS, *BRAIN physiology, *NEUROPLASTICITY
Abstract

Summary: The brain''s capacity to rewire is thought to diminish with age. It is widely believed that development stabilizes the synapses from thalamus to cortex and that adult experience alters only synaptic connections between cortical neurons. Here we show that thalamocortical (TC) inputs themselves undergo massive plasticity in adults. We combined whole-cell recording from individual thalamocortical neurons in adult rats with a recently developed automatic tracing technique to reconstruct individual axonal trees. Whisker trimming substantially reduced thalamocortical axon length in barrel cortex but not the density of TC synapses along a fiber. Thus, sensory experience alters the total number of TC synapses. After trimming, sensory stimulation evoked more tightly time-locked responses among thalamorecipient layer 4 cortical neurons. These findings indicate that thalamocortical input itself remains plastic in adulthood, raising the possibility that the axons of other subcortical structures might also remain in flux throughout life. [Copyright &y& Elsevier]

Published
2012
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22. Large-Scale Automated Histology in the Pursuit of Connectomes.

Author

Kleinfeld, David, Bharioke, Arjun, Blinder, Pablo, Bock, Davi D., Briggman, Kevin L., Chklovskii, Dmitri B., Denk, Winfried, Helmstaedter, Moritz, Kaufhold, John P., Wei-Chung Allen Lee, Meyer, Hanno S., Micheva, Kristina D., Oberlaender, Marcel, Prohaska, Steffen, Reid, R. Clay, Smith, Stephen J., Takemura, Shinya, Tsai, Philbert S., and Sakmann, Bert

Subjects
HISTOLOGY, NEUROPLASTICITY, NEURAL circuitry, BRAIN function localization, DATA analysis, VISUALIZATION, NEURONS
Abstract

How does the brain compute? Answering this question necessitates neuronal connectomes, annotated graphs of aU synaptic connections within defined brain areas. Further, understanding the energetics of the brain's computations require vascular graphs. The a embly of a connectomc requires sensitive hardware tools to measure neuronal and neurovascular features in all three dimensions, as weU as software and machine learning for data analysis and visualization. We present the state of the art on the reconstruction of circuits and vasculature that link brain anatomy and function. Analysis at the scale of tens of nanometers yields connections between identified neurons, while analysis at the micrometer scale yields probabilistic rules of connection between neurons and exact vascular connectivity. [ABSTRACT FROM AUTHOR]

Published
2011
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23. Automated three-dimensional detection and counting of neuron somata

Author

Oberlaender, Marcel, Dercksen, Vincent J., Egger, Robert, Gensel, Maria, Sakmann, Bert, and Hege, Hans-Christian

Subjects
*SOMATOSENSORY evoked potentials, *BRAIN imaging, *NEURONS, *GAUSSIAN distribution, *BRAIN function localization, *NEUROSCIENCES
Abstract

Abstract: We present a novel approach for automated detection of neuron somata. A three-step processing pipeline is described on the example of confocal image stacks of NeuN-stained neurons from rat somato-sensory cortex. It results in a set of position landmarks, representing the midpoints of all neuron somata. In the first step, foreground and background pixels are identified, resulting in a binary image. It is based on local thresholding and compensates for imaging and staining artifacts. Once this pre-processing guarantees a standard image quality, clusters of touching neurons are separated in the second step, using a marker-based watershed approach. A model-based algorithm completes the pipeline. It assumes a dominant neuron population with Gaussian distributed volumes within one microscopic field of view. Remaining larger objects are hence split or treated as a second neuron type. A variation of the processing pipeline is presented, showing that our method can also be used for co-localization of neurons in multi-channel images. As an example, we process 2-channel stacks of NeuN-stained somata, labeling all neurons, counterstained with GAD67, labeling GABAergic interneurons, using an adapted pre-processing step for the second channel. The automatically generated landmark sets are compared to manually placed counterparts. A comparison yields that the deviation in landmark position is negligible and that the difference between the numbers of manually and automatically counted neurons is less than 4%. In consequence, this novel approach for neuron counting is a reliable and objective alternative to manual detection. [Copyright &y& Elsevier]

Published
2009
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24. Shack-Hartmann wave front measurements in cortical tissue for deconvolution of large three-dimensional mosaic transmitted light brightfield micrographs.

Author

Oberlaender, Marcel, Broser, P. J., Sakmann, B., and Hippler, S.

Subjects
*THREE-dimensional imaging, *NEURONS, *MICROSCOPY, *OPTICAL aberrations, *REFRACTIVE index
Abstract

We present a novel approach for deconvolution of 3D image stacks of cortical tissue taken by mosaic/optical-sectioning technology, using a transmitted light brightfield microscope. Mosaic/optical-sectioning offers the possibility of imaging large volumes (e.g. from cortical sections) on a millimetre scale at sub-micrometre resolution. However, a blurred contribution from out-of-focus light results in an image quality that usually prohibits 3D quantitative analysis. Such quantitative analysis is only possible after deblurring by deconvolution. The resulting image quality is strongly dependent on how accurate the point spread function used for deconvolution resembles the properties of the imaging system. Since direct measurement of the true point spread function is laborious and modelled point spread functions usually deviate from measured ones, we present a method of optimizing the microscope until it meets almost ideal imaging conditions. These conditions are validated by measuring the aberration function of the microscope and tissue using a Shack-Hartmann sensor. The analysis shows that cortical tissue from rat brains embedded in Mowiol and imaged by an oil-immersion objective can be regarded as having a homogeneous index of refraction. In addition, the amount of spherical aberration that is caused by the optics or the specimen is relatively low. Consequently the image formation is simplified to refraction between the embedding and immersion medium and to 3D diffraction at the finite entrance pupil of the objective. The resulting model point spread function is applied to the image stacks by linear or iterative deconvolution algorithms. For the presented dataset of large 3D images the linear approach proves to be superior. The linear deconvolution yields a significant improvement in signal-to-noise ratio and resolution. This novel approach allows a quantitative analysis of the cortical image stacks such as the reconstruction of biocytin-stained neuronal dendrites and axons. [ABSTRACT FROM AUTHOR]

Published
2009
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26. 3D reconstruction and standardization of the rat facial nucleus for precise mapping of vibrissal motor networks.

Author

Guest, Jason M., Seetharama, Mythreya M., Wendel, Elizabeth S., Strick, Peter L., and Oberlaender, Marcel

Subjects
*FACIAL motor nucleus, *MOTOR neurons, *TACTILE sensors, *WHISKERS, *BRAIN stem
Abstract

The rodent facial nucleus (FN) comprises motoneurons (MNs) that control the facial musculature. In the lateral part of the FN, populations of vibrissal motoneurons (vMNs) innervate two groups of muscles that generate movements of the whiskers. Vibrissal MNs thus represent the terminal point of the neuronal networks that generate rhythmic whisking during exploratory behaviors and that modify whisker movements based on sensory–motor feedback during tactile-based perception. Here, we combined retrograde tracer injections into whisker-specific muscles, with large-scale immunohistochemistry and digital reconstructions to generate an average model of the rat FN. The model incorporates measurements of the FN geometry, its cellular organization and a whisker row-specific map formed by vMNs. Furthermore, the model provides a digital 3D reference frame that allows registering structural data – obtained across scales and animals – into a common coordinate system with a precision of ∼60 µm. We illustrate the registration method by injecting replication competent rabies virus into the muscle of a single whisker. Retrograde transport of the virus to vMNs enabled reconstruction of their dendrites. Subsequent trans-synaptic transport enabled mapping the presynaptic neurons of the reconstructed vMNs. Registration of these data to the FN reference frame provides a first account of the morphological and synaptic input variability within a population of vMNs that innervate the same muscle. [ABSTRACT FROM AUTHOR]

Published
2018
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27. The Impact of Structural Heterogeneity on Excitation-Inhibition Balance in Cortical Networks.

Author

Landau, Itamar D., Egger, Robert, Dercksen, Vincent J., Oberlaender, Marcel, and Sompolinsky, Haim

Subjects
*NEURAL physiology, *NEUROPLASTICITY, *NEURAL inhibition, *NEURAL circuitry, *EXCITATION (Physiology)
Abstract

Summary Models of cortical dynamics often assume a homogeneous connectivity structure. However, we show that heterogeneous input connectivity can prevent the dynamic balance between excitation and inhibition, a hallmark of cortical dynamics, and yield unrealistically sparse and temporally regular firing. Anatomically based estimates of the connectivity of layer 4 (L4) rat barrel cortex and numerical simulations of this circuit indicate that the local network possesses substantial heterogeneity in input connectivity, sufficient to disrupt excitation-inhibition balance. We show that homeostatic plasticity in inhibitory synapses can align the functional connectivity to compensate for structural heterogeneity. Alternatively, spike-frequency adaptation can give rise to a novel state in which local firing rates adjust dynamically so that adaptation currents and synaptic inputs are balanced. This theory is supported by simulations of L4 barrel cortex during spontaneous and stimulus-evoked conditions. Our study shows how synaptic and cellular mechanisms yield fluctuation-driven dynamics despite structural heterogeneity in cortical circuits. [ABSTRACT FROM AUTHOR]

Published
2016
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28. Cortical Output Is Gated by Horizontally Projecting Neurons in the Deep Layers.

Author

Egger, Robert, Narayanan, Rajeevan T., Guest, Jason M., Bast, Arco, Udvary, Daniel, Messore, Luis F., Das, Suman, de Kock, Christiaan P.J., and Oberlaender, Marcel

Subjects
*THALAMOCORTICAL system, *NEURONS, *PYRAMIDAL neurons, *PYRAMIDAL tract, *MULTISCALE modeling
Abstract

Pyramidal tract neurons (PTs) represent the major output cell type of the mammalian neocortex. Here, we report the origins of the PTs' ability to respond to a broad range of stimuli with onset latencies that rival or even precede those of their intracortical input neurons. We find that neurons with extensive horizontally projecting axons cluster around the deep-layer terminal fields of primary thalamocortical axons. The strategic location of these corticocortical neurons results in high convergence of thalamocortical inputs, which drive reliable sensory-evoked responses that precede those in other excitatory cell types. The resultant fast and horizontal stream of excitation provides PTs throughout the cortical area with input that acts to amplify additional inputs from thalamocortical and other intracortical populations. The fast onsets and broadly tuned characteristics of PT responses hence reflect a gating mechanism in the deep layers, which assures that sensory-evoked input can be reliably transformed into cortical output. • Simulations predict in vivo responses for major output cell type of the neocortex • Simulations reveal strategy how to test the origins of cortical output empirically • Manipulations confirm that deep-layer corticocortical neurons gate cortical output • Gating of cortical output originates from deep-layer thalamocortical input stratum Egger, Narayanan, et al. describe the cellular and circuit mechanisms underlying the transformation of sensory-evoked thalamocortical input into fast and broadly tuned cortical output. The study provides a comprehensive multi-scale cortex model for studying streams of sensory-evoked excitation in silico. [ABSTRACT FROM AUTHOR]

Published
2020
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