Your search keyword '"Vladimirov, Nikita"' showing total 15 results

1. Dynamic and rapid deep synthesis of chemical exchange saturation transfer and semisolid magnetization transfer MRI signals.

Author

Nagar, Dinor, Vladimirov, Nikita, Farrar, Christian T., and Perlman, Or

Subjects

*MAGNETIZATION transfer, *CHEMICAL synthesis, *MAGNETIC resonance imaging, *STANDARD deviations, *MAGNETIC particle imaging, *NONLINEAR oscillators

Abstract

Model-driven analysis of biophysical phenomena is gaining increased attention and utility for medical imaging applications. In magnetic resonance imaging (MRI), the availability of well-established models for describing the relations between the nuclear magnetization, tissue properties, and the externally applied magnetic fields has enabled the prediction of image contrast and served as a powerful tool for designing the imaging protocols that are now routinely used in the clinic. Recently, various advanced imaging techniques have relied on these models for image reconstruction, quantitative tissue parameter extraction, and automatic optimization of acquisition protocols. In molecular MRI, however, the increased complexity of the imaging scenario, where the signals from various chemical compounds and multiple proton pools must be accounted for, results in exceedingly long model simulation times, severely hindering the progress of this approach and its dissemination for various clinical applications. Here, we show that a deep-learning-based system can capture the nonlinear relations embedded in the molecular MRI Bloch–McConnell model, enabling a rapid and accurate generation of biologically realistic synthetic data. The applicability of this simulated data for in-silico, in-vitro, and in-vivo imaging applications is then demonstrated for chemical exchange saturation transfer (CEST) and semisolid macromolecule magnetization transfer (MT) analysis and quantification. The proposed approach yielded 63–99% acceleration in data synthesis time while retaining excellent agreement with the ground truth (Pearson's r > 0.99, p < 0.0001, normalized root mean square error < 3%). [ABSTRACT FROM AUTHOR]

Published

2023

2. Molecular MRI-Based Monitoring of Cancer Immunotherapy Treatment Response.

Author

Vladimirov, Nikita and Perlman, Or

Subjects

*CANCER treatment, *MAGNETIC resonance imaging, *NUCLEAR magnetic resonance spectroscopy, *DIAGNOSTIC imaging, *ARTIFICIAL intelligence

Abstract

Immunotherapy constitutes a paradigm shift in cancer treatment. Its FDA approval for several indications has yielded improved prognosis for cases where traditional therapy has shown limited efficiency. However, many patients still fail to benefit from this treatment modality, and the exact mechanisms responsible for tumor response are unknown. Noninvasive treatment monitoring is crucial for longitudinal tumor characterization and the early detection of non-responders. While various medical imaging techniques can provide a morphological picture of the lesion and its surrounding tissue, a molecular-oriented imaging approach holds the key to unraveling biological effects that occur much earlier in the immunotherapy timeline. Magnetic resonance imaging (MRI) is a highly versatile imaging modality, where the image contrast can be tailored to emphasize a particular biophysical property of interest using advanced engineering of the imaging pipeline. In this review, recent advances in molecular-MRI based cancer immunotherapy monitoring are described. Next, the presentation of the underlying physics, computational, and biological features are complemented by a critical analysis of the results obtained in preclinical and clinical studies. Finally, emerging artificial intelligence (AI)-based strategies to further distill, quantify, and interpret the image-based molecular MRI information are discussed in terms of perspectives for the future. [ABSTRACT FROM AUTHOR]

Published

2023

3. Mapping brain activity at scale with cluster computing.

Author

Freeman, Jeremy, Vladimirov, Nikita, Kawashima, Takashi, Mu, Yu, Sofroniew, Nicholas J, Bennett, Davis V, Rosen, Joshua, Yang, Chao-Tsung, Looger, Loren L, and Ahrens, Misha B

Subjects

*NEURAL circuitry, *BRAIN physiology, *DISTRIBUTED computing, *ZEBRA danio, *OPEN source intelligence

Abstract

Understanding brain function requires monitoring and interpreting the activity of large networks of neurons during behavior. Advances in recording technology are greatly increasing the size and complexity of neural data. Analyzing such data will pose a fundamental bottleneck for neuroscience. We present a library of analytical tools called Thunder built on the open-source Apache Spark platform for large-scale distributed computing. The library implements a variety of univariate and multivariate analyses with a modular, extendable structure well-suited to interactive exploration and analysis development. We demonstrate how these analyses find structure in large-scale neural data, including whole-brain light-sheet imaging data from fictively behaving larval zebrafish, and two-photon imaging data from behaving mouse. The analyses relate neuronal responses to sensory input and behavior, run in minutes or less and can be used on a private cluster or in the cloud. Our open-source framework thus holds promise for turning brain activity mapping efforts into biological insights. [ABSTRACT FROM AUTHOR]

Published

2014

4. Imprecision of Adaptation in Escherichia coli Chemotaxis.

Author

Neumann, Silke, Vladimirov, Nikita, Krembel, Anna K., Wingreen, Ned S., and Sourjik, Victor

Subjects

*ESCHERICHIA coli, *CHEMOTAXIS, *CHEMORECEPTORS, *BIOACCUMULATION, *CHEMOTACTIC factors, *METHYLATION, *SATURATION (Chemistry)

Abstract

Adaptability is an essential property of many sensory systems, enabling maintenance of a sensitive response over a range of background stimulus levels. In bacterial chemotaxis, adaptation to the preset level of pathway activity is achieved through an integral feedback mechanism based on activity-dependent methylation of chemoreceptors. It has been argued that this architecture ensures precise and robust adaptation regardless of the ambient ligand concentration, making perfect adaptation a celebrated property of the chemotaxis system. However, possible deviations from such ideal adaptive behavior and its consequences for chemotaxis have not been explored in detail. Here we show that the chemotaxis pathway in Escherichia coli shows increasingly imprecise adaptation to higher concentrations of attractants, with a clear correlation between the time of adaptation to a step-like stimulus and the extent of imprecision. Our analysis suggests that this imprecision results from a gradual saturation of receptor methylation sites at high levels of stimulation, which prevents full recovery of the pathway activity by violating the conditions required for precise adaptation. We further use computer simulations to show that limited imprecision of adaptation has little effect on the rate of chemotactic drift of a bacterial population in gradients, but hinders precise accumulation at the peak of the gradient. Finally, we show that for two major chemoeffectors, serine and cysteine, failure of adaptation at concentrations above 1 mM might prevent bacteria from accumulating at toxic concentrations of these amino acids. [ABSTRACT FROM AUTHOR]

Published

2014

5. Synaptic gating at axonal branches, and sharp-wave ripples with replay: a simulation study.

Author

Vladimirov, Nikita, Tu, Yuhai, and Traub, Roger D.

Subjects

*SYNAPSES, *AXONAL transport, *KUPFFER cells, *GAP junctions (Cell biology), *EXCITATORY postsynaptic potential, *HIPPOCAMPUS (Brain), *ACTION potentials

Abstract

Mechanisms of place cell replay occurring during sharp-wave ripples ( SPW- Rs) remain obscure due to the fact that ripples in vitro depend on non-synaptic mechanisms, presumably via axo-axonal gap junctions between pyramidal cells. We suggest a model of in vivo SPW- Rs in which synaptic excitatory post-synaptic potentials ( EPSPs) control the axonal spiking of cells in SPW- Rs: ripple activity remains hidden in the network of axonal collaterals (connected by gap junctions) due to conduction failures, unless there is a sufficient dendritic EPSP. The EPSP brings the axonal branching point to threshold, and action potentials from the collateral start to propagate to the soma and to the distal axon. The model coherently explains multiple experimental data on SPW- Rs, both in vitro and in vivo. The mechanism of synaptic gating leads to the following implication: a sequence of pyramidal cells can be replayed at ripple frequency by the superposition of subthreshold dendritic EPSPs and ripple activity in the axonal plexus. Replay is demonstrated in both forward and reverse directions. We discuss several testable predictions. In general, the mechanism of synaptic gating suggests that pyramidal cells under certain conditions can act like a transistor. [ABSTRACT FROM AUTHOR]

Published

2013

6. Wave Speed in Excitable Random Networks with Spatially Constrained Connections.

Author

Vladimirov, Nikita, Traub, Roger D., and Yuhai Tu

Subjects

*NEOCORTEX, *PEOPLE with epilepsy, *SPATIO-temporal variation, *MEAN field theory, *BRAIN stimulation, *CELLULAR automata, *DEVELOPMENTAL neurobiology, *NEURAL circuitry

Abstract

Very fast oscillations (VFO) in neocortex are widely observed before epileptic seizures, and there is growing evidence that they are caused by networks of pyramidal neurons connected by gap junctions between their axons. We are motivated by the spatio-temporal waves of activity recorded using electrocorticography (ECoG), and study the speed of activity propagation through a network of neurons axonally coupled by gap junctions. We simulate wave propagation by excitable cellular automata (CA) on random (Erdö s-Rényi) networks of special type, with spatially constrained connections. From the cellular automaton model, we derive a mean field theory to predict wave propagation. The governing equation resolved by the Fisher-Kolmogorov PDE fails to describe wave speed. A new (hyperbolic) PDE is suggested, which provides adequate wave speed v(〈k〉) that saturates with network degree 〈k〉, in agreement with intuitive expectations and CA simulations. We further show that the maximum length of connection is a much better predictor of the wave speed than the mean length. When tested in networks with various degree distributions, wave speeds are found to strongly depend on the ratio of network moments 〈k2〉=〈k〉 rather than on mean degree SkT, which is explained by general network theory. The wave speeds are strikingly similar in a diverse set of networks, including regular, Poisson, exponential and power law distributions, supporting our theory for various network topologies. Our results suggest practical predictions for networks of electrically coupled neurons, and our mean field method can be readily applied for a wide class of similar problems, such as spread of epidemics through spatial networks [ABSTRACT FROM AUTHOR]

Published

2011

7. Predicted Auxiliary Navigation Mechanism of Peritrichously Flagellated Chemotactic Bacteria.

Author

Vladimirov, Nikita, Lebiedz, Dirk, and Sourjik, Victor

Subjects

*ESCHERICHIA coli, *CHEMOTAXIS, *BACTERIAL evolution, *COMPUTER simulation, *COMPUTATIONAL biology

Abstract

Chemotactic movement of Escherichia coli is one of the most thoroughly studied paradigms of simple behavior. Due to significant competitive advantage conferred by chemotaxis and to high evolution rates in bacteria, the chemotaxis system is expected to be strongly optimized. Bacteria follow gradients by performing temporal comparisons of chemoeffector concentrations along their runs, a strategy which is most efficient given their size and swimming speed. Concentration differences are detected by a sensory system and transmitted to modulate rotation of flagellar motors, decreasing the probability of a tumble and reorientation if the perceived concentration change during a run is positive. Such regulation of tumble probability is of itself sufficient to explain chemotactic drift of a population up the gradient, and is commonly assumed to be the only navigation mechanism of chemotactic E. coli. Here we use computer simulations to predict existence of an additional mechanism of gradient navigation in E. coli. Based on the experimentally observed dependence of cell tumbling angle on the number of switching motors, we suggest that not only the tumbling probability but also the degree of reorientation during a tumble depend on the swimming direction along the gradient. Although the difference in mean tumbling angles up and down the gradient predicted by our model is small, it results in a dramatic enhancement of the cellular drift velocity along the gradient. We thus demonstrate a new level of optimization in E. coli chemotaxis, which arises from the switching of several flagellar motors and a resulting fine tuning of tumbling angle. Similar strategy is likely to be used by other peritrichously flagellated bacteria, and indicates yet another level of evolutionary development of bacterial chemotaxis. [ABSTRACT FROM AUTHOR]

Published

2010

8. Chemotaxis: how bacteria use memory.

Author

Vladimirov, Nikita and Sourjik, Victor

Subjects

*BACTERIA, *CHEMOTAXIS, *ESCHERICHIA coli, *BIOLOGICAL adaptation, *BIOCHEMISTRY

Abstract

Bacterial chemotaxis represents one of the simplest and best studied examples of unicellular behavior. Chemotaxis allows swimming bacterial cells to follow chemical gradients in the environment by performing temporal comparisons of ligand concentrations. The process of chemotaxis in the model bacterium Escherichia coli has been studied in great molecular detail over the past 40 years, using a large range of experimental tools to investigate physiology, genetics and biochemistry of the system. The abundance of quantitative experimental data enabled detailed computational modeling of the pathway and theoretical analyses of such properties as robustness and signal amplification. Because of the temporal mode of gradient sensing in bacterial chemotaxis, molecular memory is an essential component of the chemotaxis pathway. Recent studies suggest that the memory time scale has been evolutionary optimized to perform optimal comparisons of stimuli while swimming in the gradient. Moreover, noise in the adaptation system, which results from variations of the adaptation rate both over time and among cells, might be beneficial for the overall chemotactic performance of the population. [ABSTRACT FROM AUTHOR]

Published

2009

9. Dependence of Bacterial Chemotaxis on Gradient Shape and Adaptation Rate.

Author

Vladimirov, Nikita, Løvdok, Linda, Lebiedz, Dirk, and Sourjik, Victor

Subjects

*CHEMOTAXIS, *ESCHERICHIA coli physiology, *CELL populations, *CHEMORECEPTORS, *PHOSPHORYLATION, *SIMULATION methods & models

Abstract

Simulation of cellular behavior on multiple scales requires models that are sufficiently detailed to capture central intracellular processes but at the same time enable the simulation of entire cell populations in a computationally cheap way. In this paper we present RapidCell, a hybrid model of chemotactic Escherichia coli that combines the Monod-Wyman- Changeux signal processing by mixed chemoreceptor clusters, the adaptation dynamics described by ordinary differential equations, and a detailed model of cell tumbling. Our model dramatically reduces computational costs and allows the highly efficient simulation of E. coli chemotaxis. We use the model to investigate chemotaxis in different gradients, and suggest a new, constant-activity type of gradient to systematically study chemotactic behavior of virtual bacteria. Using the unique properties of this gradient, we show that optimal chemotaxis is observed in a narrow range of CheA kinase activity, where concentration of the response regulator CheY-P falls into the operating range of flagellar motors. Our simulations also confirm that the CheB phosphorylation feedback improves chemotactic efficiency by shifting the average CheY-P concentration to fit the motor operating range. Our results suggest that in liquid media the variability in adaptation times among cells may be evolutionary favorable to ensure coexistence of subpopulations that will be optimally tactic in different gradients. However, in a porous medium (agar) such variability appears to be less important, because agar structure poses mainly negative selection against subpopulations with low levels of adaptation enzymes. RapidCell is available from the authors upon request. [ABSTRACT FROM AUTHOR]

Published

2008

10. Light-sheet functional imaging in fictively behaving zebrafish.

Author

Vladimirov, Nikita, Mu, Yu, Kawashima, Takashi, Bennett, Davis V, Yang, Chao-Tsung, Looger, Loren L, Keller, Philipp J, Freeman, Jeremy, and Ahrens, Misha B

Subjects

*MICROSCOPY, *ELECTRONIC excitation, *LASER beams, *BRAIN research, *MOTOR neurons

Abstract

The article discusses research on a light-sheet microscopy system consisting of two excitation laser beams, developed to scan the brain while avoiding direct exposure of the zebrafish retina to the excitation laser. Topics discussed include the scanning coverage of each of the beams, monitoring of motor neuron axons in the tail of paralyzed larval zebrafish, and evaluation of the forward optomotor response (OMR) and fictive motor adaptation.

Published

2014

11. Gap junction networks can generate both ripple-like and fast ripple-like oscillations.

Author

Simon, Anna, Traub, Roger D., Vladimirov, Nikita, Jenkins, Alistair, Nicholson, Claire, Whittaker, Roger G., Schofield, Ian, Clowry, Gavin J., Cunningham, Mark O., and Whittington, Miles A.

Subjects

*GAP junctions (Cell biology), *SPASMS, *IN vitro studies, *NEURAL stimulation, *AXONS, *CONNEXINS

Abstract

Fast ripples ( FRs) are network oscillations, defined variously as having frequencies of > 150 to > 250 Hz, with a controversial mechanism. FRs appear to indicate a propensity of cortical tissue to originate seizures. Here, we demonstrate field oscillations, at up to 400 Hz, in spontaneously epileptic human cortical tissue in vitro, and present a network model that could explain FRs themselves, and their relation to 'ordinary' (slower) ripples. We performed network simulations with model pyramidal neurons, having axons electrically coupled. Ripples (< 250 Hz) were favored when conduction of action potentials, axon to axon, was reliable. Whereas ripple population activity was periodic, firing of individual axons varied in relative phase. A switch from ripples to FRs took place when an ectopic spike occurred in a cell coupled to another cell, itself multiply coupled to others. Propagation could then start in one direction only, a condition suitable for re-entry. The resulting oscillations were > 250 Hz, were sustained or interrupted, and had little jitter in the firing of individual axons. The form of model FR was similar to spontaneously occurring FRs in excised human epileptic tissue. In vitro, FRs were suppressed by a gap junction blocker. Our data suggest that a given network can produce ripples, FRs, or both, via gap junctions, and that FRs are favored by clusters of axonal gap junctions. If axonal gap junctions indeed occur in epileptic tissue, and are mediated by connexin 26 (recently shown to mediate coupling between immature neocortical pyramidal cells), then this prediction is testable. [ABSTRACT FROM AUTHOR]

Published

2014

12. Thermal Robustness of Signaling in Bacterial Chemotaxis

Author

Oleksiuk, Olga, Jakovljevic, Vladimir, Vladimirov, Nikita, Carvalho, Ricardo, Paster, Eli, Ryu, William S., Meir, Yigal, Wingreen, Ned S., Kollmann, Markus, and Sourjik, Victor

Subjects

*ROBUST control, *CHEMOTAXIS, *TEMPERATURE effect, *ESCHERICHIA coli, *CELLULAR signal transduction, *ENZYMES, *CHEMICAL synthesis

Abstract

Summary: Temperature is a global factor that affects the performance of all intracellular networks. Robustness against temperature variations is thus expected to be an essential network property, particularly in organisms without inherent temperature control. Here, we combine experimental analyses with computational modeling to investigate thermal robustness of signaling in chemotaxis of Escherichia coli, a relatively simple and well-established model for systems biology. We show that steady-state and kinetic pathway parameters that are essential for chemotactic performance are indeed temperature-compensated in the entire physiological range. Thermal robustness of steady-state pathway output is ensured at several levels by mutual compensation of temperature effects on activities of individual pathway components. Moreover, the effect of temperature on adaptation kinetics is counterbalanced by preprogrammed temperature dependence of enzyme synthesis and stability to achieve nearly optimal performance at the growth temperature. Similar compensatory mechanisms are expected to ensure thermal robustness in other systems. PaperClip: Display Omitted [Copyright &y& Elsevier]

Published

2011

13. Role of Translational Coupling in Robustness of Bacterial Chemotaxis Pathway.

Author

Løvdok, Linda, Bentele, Kajetan, Vladimirov, Nikita, Müller, Anette, Pop, Ferencz S., Lebiedz, Dirk, Kollmann, Markus, and Sourjik, Victor

Subjects

*CHEMOTAXIS, *BACTERIA, *PROTEINS, *ESCHERICHIA coli, *GENES, *AFFERENT pathways, *BIOINFORMATICS, *NOISE pollution

Abstract

Chemotaxis allows bacteria to colonize their environment more efficiently and to find optimal growth conditions, and is consequently under strong evolutionary selection. Theoretical and experimental analyses of bacterial chemotaxis suggested that the pathway has been evolutionarily optimized to produce robust output under conditions of such physiological perturbations as stochastic intercellular variations in protein levels while at the same time minimizing complexity and cost of protein expression. Pathway topology in Escherichia coli apparently evolved to produce an invariant output under concerted variations in protein levels, consistent with experimentally observed transcriptional coupling of chemotaxis genes. Here, we show that the pathway robustness is further enhanced through the pairwise translational coupling of adjacent genes. Computer simulations predicted that the robustness of the pathway against the uncorrelated variations in protein levels can be enhanced by a selective pairwise coupling of individual chemotaxis genes on one mRNA, with the order of genes in E. coli ranking among the best in terms of noise compensation. Translational coupling between chemotaxis genes was experimentally confirmed, and coupled expression of these genes was shown to improve chemotaxis. Bioinformatics analysis further revealed that E. coli gene order corresponds to consensus in sequenced bacterial genomes, confirming evolutionary selection for noise reduction. Since polycistronic gene organization is common in bacteria, translational coupling between adjacent genes may provide a general mechanism to enhance robustness of their signaling and metabolic networks. Moreover, coupling between expression of neighboring genes is also present in eukaryotes, and similar principles of noise reduction might thus apply to all cellular networks. [ABSTRACT FROM AUTHOR]

Published

2009

14. Prox2 and Runx3 vagal sensory neurons regulate esophageal motility.

Author

Lowenstein, Elijah D., Ruffault, Pierre-Louis, Misios, Aristotelis, Osman, Kate L., Li, Huimin, Greenberg, Rachel S., Thompson, Rebecca, Song, Kun, Dietrich, Stephan, Li, Xun, Vladimirov, Nikita, Woehler, Andrew, Brunet, Jean-François, Zampieri, Niccolò, Kühn, Ralf, Liberles, Stephen D., Jia, Shiqi, Lewin, Gary R., Rajewsky, Nikolaus, and Lever, Teresa E.

Subjects

*SENSORY neurons, *ESOPHAGEAL motility, *ESOPHAGEAL motility disorders, *GASTROINTESTINAL system, *ESOPHAGUS diseases

Abstract

Vagal sensory neurons monitor mechanical and chemical stimuli in the gastrointestinal tract. Major efforts are underway to assign physiological functions to the many distinct subtypes of vagal sensory neurons. Here, we use genetically guided anatomical tracing, optogenetics, and electrophysiology to identify and characterize vagal sensory neuron subtypes expressing Prox2 and Runx3 in mice. We show that three of these neuronal subtypes innervate the esophagus and stomach in regionalized patterns, where they form intraganglionic laminar endings. Electrophysiological analysis revealed that they are low-threshold mechanoreceptors but possess different adaptation properties. Lastly, genetic ablation of Prox2 and Runx3 neurons demonstrated their essential roles for esophageal peristalsis in freely behaving mice. Our work defines the identity and function of the vagal neurons that provide mechanosensory feedback from the esophagus to the brain and could lead to better understanding and treatment of esophageal motility disorders. [Display omitted] • Prox2/Runx3 vagal sensory neurons form intraganglionic laminar endings in the esophagus • Prox2/Runx3 vagal sensory neurons function as mechanoreceptors • Prox2/Runx3 vagal sensory neurons are required for swallowing in freely behaving mice The vagal sensory neurons that monitor esophageal stretch and distension belong to the MM2 and MM8 subtypes of Prox2/Runx3 neurons. These two subtypes are key for swallowing in vivo , as their ablation causes severe esophageal dysmotility. Knowledge about their molecular makeup might help treat esophageal disease. [ABSTRACT FROM AUTHOR]

Published

2023

15. A brainstem integrator for self-location memory and positional homeostasis in zebrafish.

Author

Yang, En, Zwart, Maarten F., James, Ben, Rubinov, Mikail, Wei, Ziqiang, Narayan, Sujatha, Vladimirov, Nikita, Mensh, Brett D., Fitzgerald, James E., and Ahrens, Misha B.

Subjects

*BRACHYDANIO, *ANIMAL mechanics, *LOCOMOTOR control, *HOMEOSTASIS, *ACTION theory (Psychology), *BRAIN stem

Abstract

To track and control self-location, animals integrate their movements through space. Representations of self-location are observed in the mammalian hippocampal formation, but it is unknown if positional representations exist in more ancient brain regions, how they arise from integrated self-motion, and by what pathways they control locomotion. Here, in a head-fixed, fictive-swimming, virtual-reality preparation, we exposed larval zebrafish to a variety of involuntary displacements. They tracked these displacements and, many seconds later, moved toward their earlier location through corrective swimming ("positional homeostasis"). Whole-brain functional imaging revealed a network in the medulla that stores a memory of location and induces an error signal in the inferior olive to drive future corrective swimming. Optogenetically manipulating medullary integrator cells evoked displacement-memory behavior. Ablating them, or downstream olivary neurons, abolished displacement corrections. These results reveal a multiregional hindbrain circuit in vertebrates that integrates self-motion and stores self-location to control locomotor behavior. [Display omitted] • Larval zebrafish can remember self-location to control their position in space • Control theory models place algorithmic constraints on the neural controller • Neurons in brainstem and cerebellum encode the memory and control algorithm • Perturbation experiments causally link these neurons to goal-directed behavior Whole-brain functional imaging of larval zebrafish reveals a multiregional brainstem and cerebellar circuit that integrates self-motion and stores self-location to control corrective fictive swimming in response to involuntary displacements. [ABSTRACT FROM AUTHOR]

Published

2022