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6. Mobile brain imaging in butoh dancers: from rehearsals to public performance

Author

Constantina Theofanopoulou, Sadye Paez, Derek Huber, Eric Todd, Mauricio A. Ramírez-Moreno, Badie Khaleghian, Alberto Muñoz Sánchez, Leah Barceló, Vangeline Gand, and José L. Contreras-Vidal

Subjects
Electroencephalography, Dance, Butoh, Hyperscanning, Interbrain synchrony, Dance therapy, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571, Neurophysiology and neuropsychology, QP351-495
Abstract

Abstract Background Dissecting the neurobiology of dance would shed light on a complex, yet ubiquitous, form of human communication. In this experiment, we sought to study, via mobile electroencephalography (EEG), the brain activity of five experienced dancers while dancing butoh, a postmodern dance that originated in Japan. Results We report the experimental design, methods, and practical execution of a highly interdisciplinary project that required the collaboration of dancers, engineers, neuroscientists, musicians, and multimedia artists, among others. We explain in detail how we technically validated all our EEG procedures (e.g., via impedance value monitoring) and minimized potential artifacts in our recordings (e.g., via electrooculography and inertial measurement units). We also describe the engineering details and hardware that enabled us to achieve synchronization between signals recorded at different sampling frequencies, along with a signal preprocessing and denoising pipeline that we used for data re-sampling and power line noise removal. As our experiment culminated in a live performance, where we generated a real-time visualization of the dancers’ interbrain synchrony on a screen via an artistic brain-computer interface, we outline all the methodology (e.g., filtering, time-windows, equation) we used for online bispectrum estimations. Additionally, we provide access to all the raw EEG data and codes we used in our recordings. We, lastly, discuss how we envision that the data could be used to address several hypotheses, such as that of interbrain synchrony or the motor theory of vocal learning. Conclusions Being, to our knowledge, the first study to report synchronous and simultaneous recording from five dancers, we expect that our findings will inform future art-science collaborations, as well as dance-movement therapies.

Published
2024
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17. Strong Solutions for PDE-Based Tomography by Unsupervised Learning

Author

Nir Sochen and Leah Bar

Subjects
Quantitative Biology::Neurons and Cognition, Artificial neural network, Computer science, Applied Mathematics, General Mathematics, Computer Science::Neural and Evolutionary Computation, 02 engineering and technology, Inverse problem, Solver, Grid, Mesh free, Mathematics::Numerical Analysis, Strong solutions, Computer Science::Mathematical Software, 0202 electrical engineering, electronic engineering, information engineering, Unsupervised learning, 020201 artificial intelligence & image processing, Tomography, Algorithm
Abstract

We introduce a novel neural network-based PDEs solver for forward and inverse problems. The solver is grid free, mesh free, and shape free, and the solution is approximated by a neural network. We ...

Published
2021
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24. The Global Law of Terror Organization Lifespan

Author

Leah Bar and Shlomo Ogen Goldman

Subjects
Geography, Sociology and Political Science, Life span, business.industry, media_common.quotation_subject, Political Science and International Relations, Longevity, Distribution (economics), Economic geography, Safety, Risk, Reliability and Quality, business, Safety Research, media_common
Abstract

The study addresses the question of whether there is a global pattern of terror organization (TO) lifespan. Based on two datasets which include hundreds of organizations, we show that there is a gl...

Published
2018
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25. Relational entitlement moderates the associations between support matching and perceived partner responsiveness

Author

Eshkol Rafaeli, Noa Vilchinsky, Eran Bar-Kalifa, Sivan George-Levi, and Leah Bar-Kalifa

Subjects
Matching (statistics), Social Psychology, media_common.quotation_subject, 05 social sciences, 050109 social psychology, Entitlement, Moderation, Developmental psychology, Personality factors, 050902 family studies, Perception, 0501 psychology and cognitive sciences, 0509 other social sciences, Psychology, Association (psychology), General Psychology, media_common
Abstract

Support often fails to lead to beneficial results. One personality factor which may differentiate between individuals’ responses to support is an excessive sense of relational entitlement (SRE; the perception of what one deserves within a romantic relationship). We examined SRE as a moderator of the association between support matching and daily perceived partner responsiveness (PPR). We found overall positive effects for support matching, negative effects for underprovision, and limited effects for overprovision. We also found that men (but not women) with an excessive SRE experienced a greater increase in their PPR when their supportive needs were met; additionally, both men and women with an excessive SRE experienced a greater decrease in PPR when their supportive needs were not met.

Published
2016
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26. Pore sizes and directionality in microcapillaries from angular double-pulsed-field-gradient NMR

Author

Yoram Cohen, Darya Morozov, Nir Sochen, and Leah Bar

Subjects
Ground truth, Opacity, Chemistry, Mixing (process engineering), Analytical chemistry, General Chemistry, Condensed Matter Physics, 01 natural sciences, Signal, Molecular physics, 030218 nuclear medicine & medical imaging, Quantitative Biology::Subcellular Processes, Azimuth, 03 medical and health sciences, 0302 clinical medicine, Mechanics of Materials, 0103 physical sciences, Directionality, Polar, General Materials Science, 010306 general physics, Pulsed field gradient
Abstract

Angular double-pulsed-field gradient (d-PFG) MR methodology is increasingly used to non-invasively obtain pore sizes in opaque chemical and biological systems. In such MR experiments, the angular dependency of the signal at zero mixing time, through modeling, can be used to extract the pore size. In many systems not only the pore sizes but also their directions are of importance. Before applying d-PFG NMR to complex systems, it is of value to challenge the ability of the methodology to extract these microstructural parameters in samples where the ground truth is known. In the present study we explored whether modeling of the signal in angular d-PFG NMR experiments at zero mixing time, can simultaneously provide the size and the direction of tilted compartments with little prior knowledge. We showed that the angular d-PFG MR methodology enables simultaneous extraction of the pore size and the direction of mono-dispersed phantoms and of phantoms where the restricted compartments have different pore sizes. However, we found that in phantoms with two or more pore sizes, only averaged pore sizes were extracted for large azimuthal and polar angles.

Published
2016
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27. A spectral framework for NMR signal with restricted diffusion

Author

Leah Bar and Nir Sochen

Subjects
Magnetization, Formalism (philosophy of mathematics), Spins, Restricted Diffusion, Mathematical analysis, Multiple correlation, Laplace operator, Spectroscopy, Diffusion MRI, Mathematics, Magnetic field
Abstract

By the multiple correlation function (MCF) formalism, the nuclear magnetic resonance magnetization of diffusing spins can be represented for simple pore geometries. It may be used to infer geometric structure at the scale of microns. This is to be compared to the diffusion tensor imaging, which provides geometric information at the scale of millimeters. The MCF formulation was derived to special cases in which the gradients of the magnetic field are oriented in specific directions. A generalized approach allowing an arbitrary magnetic field direction was introduced by Ozarslan. In this article, we present a complete account of the generalized MCF mathematical derivation starting from Bloch–Torrey equations. It is aimed to the experts and novices alike. We present two approaches—the indirect derivation is based on Ozarslan's work, where the standard MCF equations are adopted to arbitrary gradient directions. Our alternative approach is based on direct calculations of the MCF matrices for specified gradient directions. We prove that the two approaches lead to the same equations. Finally, we revise Mitra's microscopic approach and show the relation to the macroscopic MCF approach. We prove that in some limit conditions the two signal equations coincide © 2015 Wiley Periodicals, Inc. Concepts Magn Reson Part A 43A: 16–53, 2015.

Published
2015
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29. Blind Space-Variant Single-Image Restoration of Defocus Blur

Author

Nahum Kiryati, Leah Bar, and Nir Sochen

Subjects
Blind deconvolution, Deblurring, Computer science, business.industry, 020207 software engineering, 02 engineering and technology, Space (mathematics), Image (mathematics), Computer Science::Graphics, Computer Science::Computer Vision and Pattern Recognition, 0202 electrical engineering, electronic engineering, information engineering, Piecewise, 020201 artificial intelligence & image processing, Computer vision, Depth of field, Artificial intelligence, Single image, business
Abstract

We address the problem of blind piecewise space-variant image deblurring where only part of the image is sharp, assuming a shallow depth of field which imposes significant defocus blur.

Published
2017
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30. Microstructural information from angular double-pulsed-field-gradient NMR: From model systems to nerves

Author

Leah Bar, Darya Morozov, Nir Sochen, and Yoram Cohen

Subjects
Ground truth, Nuclear magnetic resonance, Materials science, A priori and a posteriori, Radiology, Nuclear Medicine and imaging, Diffusion (business), Pulsed field gradient, Signal, Biomedical engineering
Abstract

Purpose To evaluate the ability of angular double-pulsed-field gradient (d-PFG) MR to provide microstructural information in complex phantoms and fixed nerves. Methods We modeled the signal in angular d-PFG MR experiments performed on phantoms of increasing complexity where the ground truth is known a priori. After analyzing the microstructural features of such phantoms the same methodology was used to study microstructural features in fixed nerves. Results We found that our modeling is able to determine with high accuracy and with very little prior knowledge the sizes and relative fractions of the restricted components as well as the fraction of the free diffusing water molecules. The same approach was used to study nerve microstructure. We found the apparent averaged axonal diameter (AAD) to be 2.3 ± 0.2 μm. However, here the results depended, to some extent, on the parameters used to collect the data and were affected by the diffusion time. Conclusion Modeling of the angular d-PFG MR signal provides a means to obtain accurate microstructural information in complex phantoms where the ground truth is known. This approach also seems to be suitable for obtaining microstructural features in fixed nerves. Magn Reson Med 74:25–32, 2015. © 2014 Wiley Periodicals, Inc.

Published
2014
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31. Modeling of the diffusion MR signal in calibrated model systems and nerves

Author

Yoram Cohen, Nir Sochen, Leah Bar, and Darya Morozov

Subjects
Work (thermodynamics), education.field_of_study, Ground truth, Opacity, Chemistry, Diffusion, Population, Signal, law.invention, Nuclear magnetic resonance, law, Restricted Diffusion, Micrometer, Molecular Medicine, Radiology, Nuclear Medicine and imaging, education, Biological system, Spectroscopy
Abstract

Diffusion NMR is a powerful tool for gleaning microstructural information on opaque systems. In this work, the signal decay in single-pulsed-field gradient diffusion NMR experiments performed on a series of phantoms of increasing complexity, where the ground truth is known a priori, was modeled and used to identify microstructural features of these complex phantoms. We were able to demonstrate that, without assuming the number of components or compartments, the modeling can identify the number of restricted components, detect their sizes with an accuracy of a fraction of a micrometer, determine their relative populations, and identify and characterize free diffusion when present in addition to the components exhibiting restricted diffusion. After the accuracy of the modeling had been demonstrated, this same approach was used to study fixed nerves under different experimental conditions. It seems that this approach is able to characterize both the averaged axon diameter and the relative population of the different diffusing components in the neuronal tissues examined.

Published
2013
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32. Caregivers’ Experiences With a Web- and Mobile-Based Platform for Children With Medical Complexity and the Role of a Live Platform Coach: Thematic Analysis

Author

Ainslie Claire Shouldice, Madison Beatty, Sherri Adams, Blossom Dharmaraj, Clara Moore, Jennifer Nan Stinson, Arti Desai, Leah Bartlett, Erin Culbert, Eyal Cohen, and Julia Orkin

Subjects
Pediatrics, RJ1-570
Abstract

BackgroundChildren with medical complexity (CMC) are individuals with complex chronic conditions who have substantial health care needs, functional limitations, and significant use of health care. By nature of their health status, they have many care providers across multiple settings, making information sharing critical to their health and safety. Connecting2gether (C2), a web- and mobile-based patient-facing platform, was codeveloped with families to support and empower parental caregivers, improve information sharing, and facilitate care delivery. C2 also provided a live platform coach to conduct parental feedback and coaching sessions, which included answering questions, providing advice on usage, and addressing technological issues. ObjectiveThis study was conducted to understand the experience of parental caregivers using the C2 platform and the role of the live platform coach. This study is a subset of a larger study assessing the feasibility of C2 in the care of CMC. MethodsParental caregivers (n=33) participated in biweekly sessions to provide feedback and receive real-time platform use support from a trained research team member acting as a live platform coach. Parental caregivers were asked about the utility and usability of C2’s features. Questions, platform issues, and feedback were recorded on a standardized electronic data collection tool. A thematic analysis was performed to analyze parental comments, and codes were categorized into key themes. The number of comments corresponding with each code was quantified. ResultsA total of 166 parental feedback and coaching sessions were conducted, with an average of 5 sessions per parental caregiver (range 1-7). There were 33 (85%) parental caregivers that participated in at least one coaching session. Technical issues and difficulties navigating C2 were addressed in real time during the sessions to encourage platform engagement. Four key themes were identified: (1) live platform coach, (2) barriers to platform usage and technical challenges, (3) platform requests and modifications, and (4) parent partnership and empowerment. ConclusionsParental caregivers describe C2 as a valuable tool, acting as a facilitator for enhanced care coordination and communication. Parental caregiver feedback showed that the live platform coach was a critical tool in educating on platform use and addressing technological concerns. Further study of the use of the C2 platform and its role in the care of CMC is needed to understand the possible benefits and cost-effectiveness of this technology.

Published
2023
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33. Mapping apparent eccentricity and residual ensemble anisotropy in the gray matter using angular double-pulsed-field-gradient MRI

Author

Ofer Sadan, Yaniv Assaf, Yoram Cohen, Yael Barhum, Daniel Offen, Daniel Barazany, Noam Shemesh, Yuval Zur, Leah Bar, and Nir Sochen

Subjects
Male, Residual, Sensitivity and Specificity, Diffusion Anisotropy, Pattern Recognition, Automated, White matter, Nuclear magnetic resonance, Image Interpretation, Computer-Assisted, medicine, Animals, Radiology, Nuclear Medicine and imaging, Rats, Wistar, Anisotropy, Neurons, Physics, Pixel, Brain, Reproducibility of Results, Signal Processing, Computer-Assisted, Image Enhancement, Rat brain, Magnetic Resonance Imaging, Rats, medicine.anatomical_structure, Pulsed field gradient, Algorithms, Diffusion MRI
Abstract

Conventional diffusion MRI methods are mostly capable of portraying microarchitectural elements such as fiber orientation in white matter from detection of diffusion anisotropy, which arises from the coherent organization of anisotropic compartments. Double-pulsed-field-gradient MR methods provide a means for obtaining microstructural information such as compartment shape and microscopic anisotropies even in scenarios where macroscopic organization is absent. Here, we apply angular double-pulsed-gradient-spin-echo MRI in the rat brain both ex vivo and in vivo for the first time. Robust angular dependencies are detected in the brain at long mixing time (t(m) ). In many pixels, the oscillations seem to originate from residual directors in randomly oriented media, i.e., from residual ensemble anisotropy, as corroborated by quantitative simulations. We then developed an analysis scheme that enables one to map of structural indices such as apparent eccentricity (aE) and residual phase (φ) that enables characterization of the rat brain in general, and especially the rat gray matter. We conclude that double-pulsed-gradient-spin-echo MRI may in principle become important in characterizing gray matter morphological features and pathologies in both basic and applied neurosciences.

Published
2011
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34. A Continuum Mechanical Approach to Geodesics in Shape Space

Author

Benedikt Wirth, Martin Rumpf, Leah Bar, and Guillermo Sapiro

Subjects
Spacetime, Discretization, Continuum mechanics, Geodesic, Mathematical analysis, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Rigid body, Scale space, Motion field, Artificial Intelligence, Computer Vision and Pattern Recognition, Software, ComputingMethodologies_COMPUTERGRAPHICS, Shape analysis (digital geometry), Mathematics
Abstract

In this paper concepts from continuum mechanics are used to define geodesic paths in the space of shapes, where shapes are implicitly described as boundary contours of objects. The proposed shape metric is derived from a continuum mechanical notion of viscous dissipation. A geodesic path is defined as the family of shapes such that the total amount of viscous dissipation caused by an optimal material transport along the path is minimized. The approach can easily be generalized to shapes given as segment contours of multi-labeled images and to geodesic paths between partially occluded objects. The proposed computational framework for finding such a minimizer is based on the time discretization of a geodesic path as a sequence of pairwise matching problems, which is strictly invariant with respect to rigid body motions and ensures a 1---1 correspondence along the induced flow in shape space. When decreasing the time step size, the proposed model leads to the minimization of the actual geodesic length, where the Hessian of the pairwise matching energy reflects the chosen Riemannian metric on the underlying shape space. If the constraint of pairwise shape correspondence is replaced by the volume of the shape mismatch as a penalty functional, one obtains for decreasing time step size an optical flow term controlling the transport of the shape by the underlying motion field. The method is implemented via a level set representation of shapes, and a finite element approximation is employed as spatial discretization both for the pairwise matching deformations and for the level set representations. The numerical relaxation of the energy is performed via an efficient multi-scale procedure in space and time. Various examples for 2D and 3D shapes underline the effectiveness and robustness of the proposed approach.

Published
2010
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35. Convergence of an Iterative Method for Variational Deconvolution and Impulsive Noise Removal

Author

Nir Sochen, Leah Bar, and Nahum Kiryati

Subjects
Iterative method, Ecological Modeling, Mathematical analysis, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, General Physics and Astronomy, General Chemistry, Inverse problem, Computer Science Applications, Discontinuity (linguistics), Noise, Fixed-point iteration, Computer Science::Computer Vision and Pattern Recognition, Modeling and Simulation, Convergence (routing), Applied mathematics, Deconvolution, Image restoration, Mathematics
Abstract

Image restoration, i.e., the recovery of images that have been degraded by blur and noise, is a challenging inverse problem. A unified variational approach to edge-preserving image deconvolution and impulsive noise removal has recently been suggested by the authors and shown to be effective. It leads to a minimization problem that is iteratively solved by alternate minimization for both the recovered image and the discontinuity set. The variational formulation yields a nonlinear integro-differential equation. This equation was linearized by fixed point iteration. In this paper, we analyze and prove the convergence of the iterative method.

Published
2007
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36. Image Deblurring in the Presence of Impulsive Noise

Author

Nir Sochen, Nahum Kiryati, and Leah Bar

Subjects
Deblurring, Anisotropic diffusion, Salt-and-pepper noise, Impulse noise, Gradient noise, symbols.namesake, Artificial Intelligence, Gaussian noise, Computer Science::Computer Vision and Pattern Recognition, Calculus, Median filter, symbols, Computer Vision and Pattern Recognition, Value noise, Algorithm, Software, Mathematics
Abstract

Consider the problem of image deblurring in the presence of impulsive noise. Standard image deconvolution methods rely on the Gaussian noise model and do not perform well with impulsive noise. The main challenge is to deblur the image, recover its discontinuities and at the same time remove the impulse noise. Median-based approaches are inadequate, because at high noise levels they induce nonlinear distortion that hampers the deblurring process. Distinguishing outliers from edge elements is difficult in current gradient-based edge-preserving restoration methods. The suggested approach integrates and extends the robust statistics, line process (half quadratic) and anisotropic diffusion points of view. We present a unified variational approach to image deblurring and impulse noise removal. The objective functional consists of a fidelity term and a regularizer. Data fidelity is quantified using the robust modified L 1 norm, and elements from the Mumford-Shah functional are used for regularization. We show that the Mumford-Shah regularizer can be viewed as an extended line process. It reflects spatial organization properties of the image edges, that do not appear in the common line process or anisotropic diffusion. This allows to distinguish outliers from edges and leads to superior experimental results.

Published
2006
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37. Semi-blind image restoration via Mumford-Shah regularization

Author

Nahum Kiryati, Nir Sochen, and Leah Bar

Subjects
Blind deconvolution, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Information Storage and Retrieval, Scale-space segmentation, Image processing, Pattern Recognition, Automated, Artificial Intelligence, Image Interpretation, Computer-Assisted, Computer Simulation, Segmentation, Image restoration, Mathematics, Models, Statistical, Segmentation-based object categorization, business.industry, Signal Processing, Computer-Assisted, Pattern recognition, Image segmentation, Image Enhancement, Computer Graphics and Computer-Aided Design, Subtraction Technique, Computer Science::Computer Vision and Pattern Recognition, Artificial intelligence, Deconvolution, business, Algorithms, Software
Abstract

Image restoration and segmentation are both classical problems, that are known to be difficult and have attracted major research efforts. This paper shows that the two problems are tightly coupled and can be successfully solved together. Mutual support of image restoration and segmentation processes within a joint variational framework is theoretically motivated, and validated by successful experimental results. The proposed variational method integrates semi-blind image deconvolution (parametric blur-kernel), and Mumford-Shah segmentation. The functional is formulated using the /spl Gamma/-convergence approximation and is iteratively optimized via the alternate minimization method. While the major novelty of this work is in the unified treatment of the semi-blind restoration and segmentation problems, the important special case of known blur is also considered and promising results are obtained.

Published
2006
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38. Evaluation of a Secure Messaging System in the Care of Children With Medical Complexity: Mixed Methods Study

Author

Camilla Parpia, Clara Moore, Madison Beatty, Susan Miranda, Sherri Adams, Jennifer Stinson, Arti Desai, Leah Bartlett, Erin Culbert, Eyal Cohen, and Julia Orkin

Subjects
Medicine
Abstract

BackgroundThe Connecting2gether (C2) platform is a web and mobile–based information-sharing tool that aims to improve care for children with medical complexity and their families. A key feature of C2 is secure messaging, which enables parental caregivers (PCs) to communicate with their child’s care team members (CTMs) in a timely manner. ObjectiveThe objectives of this study were to (1) evaluate the use of a secure messaging system, (2) examine and compare the content of messages to email and phone calls, and (3) explore PCs’ and CTMs’ perceptions and experiences using secure messaging as a method of communication. MethodsThis is a substudy of a larger feasibility evaluation of the C2 platform. PCs of children with medical complexity were recruited from a tertiary-level complex care program to use the C2 platform for 6 months. PCs could invite CTMs involved in their child’s care to register on the platform. Messages were extracted from C2, and phone and email data were extracted from electronic medical records. Quantitative data from the use of C2 were analyzed using descriptive statistics. Messaging content codes were iteratively developed through a review of the C2 messages and phone and email communication. Semistructured interviews were completed with PCs and CTMs. Communication and interview data were analyzed using thematic analysis. ResultsA total of 36 PCs and 66 CTMs registered on the C2 platform. A total of 1861 messages were sent on C2, with PCs and nurse practitioners sending a median of 30 and 74 messages, respectively. Of all the C2 messages, 85.45% (1257/1471) were responded to within 24 hours. Email and phone calls focused primarily on clinical concerns and medications, whereas C2 messaging focused more on parent education, proactive check-ins, and nonmedical aspects of the child’s life. Four themes emerged from the platform user interviews related to C2 messaging: (1) connection to the care team, (2) efficient communication, (3) clinical uses of secure messaging, and (4) barriers to use. ConclusionsOverall, our study provides valuable insight into the benefits of secure messaging in the care of children with medical complexity. Secure messaging provided the opportunity for continued family teaching, proactive check-ins from health care providers, and casual conversations about family and child life, which contributed to PCs feeling an improved sense of connection with their child’s health care team. Secure messaging can be a beneficial additional communication method to improve communication between PCs and their care team, reducing the associated burden of care coordination and ultimately enhancing the experience of care delivery. Future directions include the evaluation of secure messaging when integrated into electronic medical records, as this has the potential to work well with CTM workflow, reduce redundancy, and allow for new features of secure messaging.

Published
2023
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39. Intramuscular mRNA BNT162b2 vaccine against SARS-CoV-2 induces neutralizing salivary IgA

Author

Miri Stolovich-Rain, Sujata Kumari, Ahuva Friedman, Saveliy Kirillov, Yakov Socol, Maria Billan, Ritesh Ranjan Pal, Kathakali Das, Peretz Golding, Esther Oiknine-Djian, Salim Sirhan, Michal Bejerano Sagie, Einav Cohen-Kfir, Naama Gold, Jamal Fahoum, Manoj Kumar, Maya Elgrably-Weiss, Bing Zhou, Miriam Ravins, Yair E. Gatt, Saurabh Bhattacharya, Orly Zelig, Reuven Wiener, Dana G. Wolf, Hila Elinav, Jacob Strahilevitz, Dan Padawer, Leah Baraz, and Alexander Rouvinski

Subjects
secretory IgA, mucosal immunity, secretory component, BNT162b2 vaccine, SARS-CoV-2 neutralizing Abs, Immunologic diseases. Allergy, RC581-607
Abstract

Intramuscularly administered vaccines stimulate robust serum neutralizing antibodies, yet they are often less competent in eliciting sustainable “sterilizing immunity” at the mucosal level. Our study uncovers a strong temporary neutralizing mucosal component of immunity, emanating from intramuscular administration of an mRNA vaccine. We show that saliva of BNT162b2 vaccinees contains temporary IgA targeting the receptor-binding domain (RBD) of severe acute respiratory syndrome coronavirus-2 spike protein and demonstrate that these IgAs mediate neutralization. RBD-targeting IgAs were found to associate with the secretory component, indicating their bona fide transcytotic origin and their polymeric multivalent nature. The mechanistic understanding of the high neutralizing activity provided by mucosal IgA, acting at the first line of defense, will advance vaccination design and surveillance principles and may point to novel treatment approaches and new routes of vaccine administration and boosting.

Published
2023
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41. Microstructural information from angular double-pulsed-field-gradient NMR: From model systems to nerves

Author

Darya, Morozov, Leah, Bar, Nir, Sochen, and Yoram, Cohen

Abstract

To evaluate the ability of angular double-pulsed-field gradient (d-PFG) MR to provide microstructural information in complex phantoms and fixed nerves.We modeled the signal in angular d-PFG MR experiments performed on phantoms of increasing complexity where the ground truth is known a priori. After analyzing the microstructural features of such phantoms the same methodology was used to study microstructural features in fixed nerves.We found that our modeling is able to determine with high accuracy and with very little prior knowledge the sizes and relative fractions of the restricted components as well as the fraction of the free diffusing water molecules. The same approach was used to study nerve microstructure. We found the apparent averaged axonal diameter (AAD) to be 2.3 ± 0.2 μm. However, here the results depended, to some extent, on the parameters used to collect the data and were affected by the diffusion time.Modeling of the angular d-PFG MR signal provides a means to obtain accurate microstructural information in complex phantoms where the ground truth is known. This approach also seems to be suitable for obtaining microstructural features in fixed nerves. Magn Reson Med 74:25-32, 2015. © 2014 Wiley Periodicals, Inc.

Published
2013

42. Modeling of the diffusion MR signal in calibrated model systems and nerves

Author

Darya, Morozov, Leah, Bar, Nir, Sochen, and Yoram, Cohen

Subjects
Diffusion Magnetic Resonance Imaging, Phantoms, Imaging, Calibration, Sus scrofa, Animals, Optic Nerve, Signal Processing, Computer-Assisted, Models, Biological
Abstract

Diffusion NMR is a powerful tool for gleaning microstructural information on opaque systems. In this work, the signal decay in single-pulsed-field gradient diffusion NMR experiments performed on a series of phantoms of increasing complexity, where the ground truth is known a priori, was modeled and used to identify microstructural features of these complex phantoms. We were able to demonstrate that, without assuming the number of components or compartments, the modeling can identify the number of restricted components, detect their sizes with an accuracy of a fraction of a micrometer, determine their relative populations, and identify and characterize free diffusion when present in addition to the components exhibiting restricted diffusion. After the accuracy of the modeling had been demonstrated, this same approach was used to study fixed nerves under different experimental conditions. It seems that this approach is able to characterize both the averaged axon diameter and the relative population of the different diffusing components in the neuronal tissues examined.

Published
2013

43. Left-right asymmetry of visual evoked potentials in brain-damaged patients: A mathematical model and experimental results

Author

Leah Bar, Itzhak Glass, Shimon Abboud, Haim Ring, and Moshe Rosenfeld

Subjects
media_common.quotation_subject, Models, Neurological, Biomedical Engineering, Poison control, Brain damage, Electroencephalography, Asymmetry, Functional Laterality, Nuclear magnetic resonance, medicine, Humans, Evoked potential, media_common, Physics, Scalp, medicine.diagnostic_test, Electric Conductivity, Signal Processing, Computer-Assisted, Cerebrovascular Disorders, Amplitude, medicine.anatomical_structure, Anesthesia, Evoked Potentials, Visual, medicine.symptom, Tomography, X-Ray Computed, Head, Electrocardiography
Abstract

The left-right asymmetry in the potential amplitude on the scalp was studied in poststroke patients by using flash visual evoked potential (VEP) and a numerical two-dimensional model of the head. The left-right asymmetry of the VEP was measured in three patients after thrombosis, in one after hemorrhage, and in one healthy subject. The numerical model used computed tomography images to define the different compartments of the head. The volume conductor equation for the potential distribution created by a dipole source in the occipital region was solved numerically with use of a finite volume method. Left-right asymmetry was calculated with several values of conductivity of the damaged region. The experimental results revealed a negative asymmetry in the three patients after thrombosis (i.e., the potential amplitude over the ischemic hemisphere was smaller than that over the intact hemisphere), whereas, in the patient after hemorrhage, a positive asymmetry was found. Nonsignificant left-right asymmetry was found in the healthy subject. The numerical model revealed that the electrical conductivity of the damaged tissue has a major effect on the left-right asymmetry. Negative asymmetry, such as that found for patients after thrombosis, was obtained when the conductivity of the damaged region was greater than that of the brain, whereas positive asymmetry (hemorrhage patient) was obtained when that conductivity was smaller than that of the brain. This finding indicates that the left-right asymmetry in the scalp VEP of patients after brain damage may be a result of changes in the conductivity of the volume conductor (the ischemic region) between the source and the electrodes.

Published
1995
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44. Measuring small compartments with relatively weak gradients by angular double-pulsed-field-gradient NMR

Author

Nir Sochen, Leah Bar, Darya Morozov, and Yoram Cohen

Subjects
Magnetic Resonance Spectroscopy, Chemistry, Microchemistry, Biomedical Engineering, Biophysics, Analytical chemistry, Signal Processing, Computer-Assisted, Nuclear magnetic resonance spectroscopy, Microstructure, Magnetic susceptibility, Molecular physics, Restricted Diffusion, Radiology, Nuclear Medicine and imaging, Signal intensity, Compartment (pharmacokinetics), Pulsed field gradient, Anisotropy, Algorithms
Abstract

article NMR diffusion-diffraction patterns observed in compartments in which restricted diffusion occurs are a useful tool for direct extraction of compartment sizes. Such diffusion-diffraction patterns may be observed when the signal intensity E(q,Δ) is plotted against the wave-vector q (when q=(2π) −1 γδG). However, the smaller the compartment sizes are, the higher are the q-values needed to observe such diffractions. Moreover, these q-values should be achieved using short gradient pulses requiring extremely strong gradient systems. The angular double-pulsed-field gradient (d-PFG) NMR methodology has been proposed as a tool to extract compartment sizes using relatively low q-values. In this study, we have used single-PFG (s-PFG) NMR and angular d-PFG NMR to characterize the size of microcapillaries of about 2±1 μm in diameter. We found that these microcapillaries are characterized by relatively strong background gradients that completely masked the effects of the microscopic anisotropy (μA) of the sample, resulting in a completely unexpected E(φ )p rofile in the angular d-PFG NMR experiments. We also show that bipolar angular d-PFG NMR experiments can largely suppress the effect of these background gradients resulting in the expected E(φ) profile from which the compartment dimensions could be obtained with relatively weak gradient pulses. These results demonstrate that the above methodology provides a quick, reliable, non-invasive means for estimating small pore sizes with relatively weak gradients in the presence of large magnetic susceptibility.

Published
2012

45. The Beltrami-Mumford-Shah Functional

Author

Leah Bar and Nir Sochen

Subjects
Set (abstract data type), Flow (mathematics), Square root, Generalization, Anisotropic diffusion, Metric (mathematics), Mathematical analysis, Applied mathematics, Function (mathematics), Mumford–Shah functional, Mathematics
Abstract

We present in this paper a unifying generalization of the Mumford-Shah functional, in the Ambrosio-Totorelli set up, and the Beltrami framework. The generalization of the Ambrosio-Tortorelli is in using a diffusion tensor as an indicator of the edge set instead of a function. The generalization of the Beltrami framework is in adding a penalty term on the metric such that it is defined dynamically from minimization of the functional. We show that we are able, in this way, to have the benefits of true anisotropic diffusion together with a dynamically tuned metric/diffusion tensor. The functional is naturally defined in terms of the vielbein-the metric's square root. Preliminary results show improvement on both the Beltrami flow and the Mumford-Shah flow.

Published
2012
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47. Hierarchical dictionary learning for invariant classification

Author

Guillermo Sapiro and Leah Bar

Subjects
Training set, K-SVD, business.industry, Computer science, Feature extraction, Image processing, Pattern recognition, Sparse approximation, Invariant (physics), Statistical classification, Robustness (computer science), Artificial intelligence, Invariant (mathematics), Neural coding, business
Abstract

Sparse representation theory has been increasingly used in the fields of signal processing and machine learning. The standard sparse models are not invariant to spatial transformations such as image rotations, and the representation is very sensitive even under small such distortions. Most studies addressing this problem proposed algorithms which either use transformed data as part of the training set, or are invariant or robust only under minor transformations. In this paper we suggest a framework which extracts sparse features invariant under significant rotations and scalings. The algorithm is based on a hierarchical architecture of dictionary learning for sparse coding in a cortical (log-polar) space. The proposed model is tested in supervised classification applications and proved to be robust under transformed data.

Published
2010
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48. Geodesics in Shape Space via Variational Time Discretization

Author

Martin Rumpf, Benedikt Wirth, Leah Bar, and Guillermo Sapiro

Subjects
Hessian matrix, Geodesic, Spacetime, Discretization, Mathematical analysis, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Topology, Rigid body, symbols.namesake, Motion field, symbols, Invariant (mathematics), ComputingMethodologies_COMPUTERGRAPHICS, Shape analysis (digital geometry), Mathematics
Abstract

A variational approach to defining geodesics in the space of implicitly described shapes is introduced in this paper. The proposed framework is based on the time discretization of a geodesic path as a sequence of pairwise matching problems, which is strictly invariant with respect to rigid body motions and ensures a 1-1 property of the induced flow in shape space. For decreasing time step size, the proposed model leads to the minimization of the actual geodesic length, where the Hessian of the pairwise matching energy reflects the chosen Riemannian metric on the shape space. Considering shapes as boundary contours, the proposed shape metric is identical to a physical dissipation in a viscous fluid model of optimal transportation. If the pairwise shape correspondence is replaced by the volume of the shape mismatch as a penalty functional, for decreasing time step size one obtains an additional optical flow term controlling the transport of the shape by the underlying motion field. The implementation of the proposed approach is based on a level set representation of shapes, which allows topological transitions along the geodesic path. For the spatial discretization a finite element approximation is employed both for the pairwise deformations and for the level set representation. The numerical relaxation of the energy is performed via an efficient multi---scale procedure in space and time. Examples for 2D and 3D shapes underline the effectiveness and robustness of the proposed approach.

Published
2009
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49. Perspectives on team communication challenges in caring for children with medical complexity

Author

Sherri Adams, Madison Beatty, Clara Moore, Arti Desai, Leah Bartlett, Erin Culbert, Eyal Cohen, Jennifer Stinson, and Julia Orkin

Subjects
Children with medical complexity, Communication challenges, Communication solutions, Shared decision making, Universal health record, Family centered care, Public aspects of medicine, RA1-1270
Abstract

Abstract Background Children with medical complexity (CMC) require the expertise of many care providers spanning different disciplines, institutions, and settings of care. This leads to duplicate health records, breakdowns in communication, and limited opportunities to provide comprehensive, collaborative care. The objectives of this study were to explore communication challenges and solutions/recommendations from multiple perspectives including (i) parents, (ii) HCPs – hospital and community providers, and (iii) teachers of CMC with a goal of informing patient care. Methods This qualitative study utilized an interpretive description methodology. In-depth semi-structured interviews were conducted with parents and care team members of CMC. The interview guides targeted questions surrounding communication, coordination, access to information and roles in the health system. Interviews were conducted until thematic saturation was reached. Interviews were audio-recorded, transcribed verbatim, and coded and analyzed using thematic analysis. Results Thirty-two individual interviews were conducted involving parents (n = 16) and care team members (n = 16). Interviews revealed 2 main themes and several associated subthemes (in parentheses): (1) Communication challenges in the care of CMC (organizational policy and technology systems barriers, inadequate access to health information, and lack of partnership in care) (2) Communication solutions (shared systems that can be accessed in real-time, universal access to health information, and partnered contribution to care). Conclusion Parents, HCPs, and teachers face multiple barriers to communication and information accessibility in their efforts to care for CMC. Parents and care providers in this study suggested potential strategies to improve communication including facilitating communication in real-time, universal access to health information and meaningful partnerships.

Published
2021
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50. Generalized Newton methods for energy formulations in image procesing

Author

Guillermo Sapiro and Leah Bar

Subjects
Hessian matrix, Trust region, Mathematical optimization, symbols.namesake, Discrete optimization, symbols, Descent direction, Gradient descent, Condition number, Newton's method, Newton's method in optimization, Mathematics
Abstract

Many problems in image processing are solved via the minimization of a cost functional. The most widely used optimization technique is the gradient descent, often used due to its simplicity and applicability where other optimization techniques, e.g., those coming from discrete optimization, can not be used. Yet, gradient descent suffers from a slow convergence, and often to just local minima which highly depends on the condition number of the functional Hessian. Newton- type methods, on the other hand, are known to have a rapid (quadratic) convergence. In its classical form, the Newton method relies on the L2-type norm to define the descent direction. In this paper, we generalize and reformulate this very important optimization method by introducing a novel Newton method based on general norms. This generalization opens up new possibilities in the extraction of the Newton step, including benefits such as mathematical stability and smoothness constraints. We first present the derivation of the modified Newton step in the calculus of variation framework. Then we demonstrate the method with two common objective functionals: variational image deblurring and geodesic active contours. We show that in addition to the fast convergence, different selections norm yield different and superior results.

Published
2008
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