22 results
Search Results
2. Author Correction: Plasma microRNA markers of upper limb recovery following human stroke
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Edwardson, Matthew A, Zhong, Xiaogang, Fiandaca, Massimo S, Federoff, Howard J, Cheema, Amrita K, and Dromerick, Alexander W
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Allied Health and Rehabilitation Science ,Information and Computing Sciences ,Health Sciences - Abstract
An amendment to this paper has been published and can be accessed via a link at the top of the paper.
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- 2020
3. Publisher Correction: Brain-machine interface cursor position only weakly affects monkey and human motor cortical activity in the absence of arm movements
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Stavisky, Sergey D, Kao, Jonathan C, Nuyujukian, Paul, Pandarinath, Chethan, Blabe, Christine, Ryu, Stephen I, Hochberg, Leigh R, Henderson, Jaimie M, and Shenoy, Krishna V
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Information and Computing Sciences ,Machine Learning - Abstract
A correction to this article has been published and is linked from the HTML and PDF versions of this paper. The error has been fixed in the paper.
- Published
- 2019
4. Publisher Correction: Learning the value of information and reward over time when solving exploration-exploitation problems
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Cogliati Dezza, Irene, Yu, Angela J, Cleeremans, Axel, and Alexander, William
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Information and Computing Sciences ,Machine Learning - Abstract
A correction to this article has been published and is linked from the HTML and PDF versions of this paper. The error has been fixed in the paper.
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- 2018
5. Author Correction: Blocking Zika virus vertical transmission
- Author
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Mesci, Pinar, Macia, Angela, Moore, Spencer M, Shiryaev, Sergey A, Pinto, Antonella, Huang, Chun-Teng, Tejwani, Leon, Fernandes, Isabella R, Suarez, Nicole A, Kolar, Matthew J, Montefusco, Sandro, Rosenberg, Scott C, Herai, Roberto H, Cugola, Fernanda R, Russo, Fabiele B, Sheets, Nicholas, Saghatelian, Alan, Shresta, Sujan, Momper, Jeremiah D, Siqueira-Neto, Jair L, Corbett, Kevin D, Beltrão-Braga, Patricia CB, Terskikh, Alexey V, and Muotri, Alysson R
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Theory Of Computation ,Information and Computing Sciences ,Biomedical and Clinical Sciences ,Good Health and Well Being - Abstract
A correction to this article has been published and is linked from the HTML and PDF versions of this paper. The error has not been fixed in the paper.
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- 2018
6. Accounting for endogenous effects in decision-making with a non-linear diffusion decision model
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Hoxha, Isabelle, Chevallier, Sylvain, Ciarchi, Matteo, Glasauer, Stefan, Delorme, Arnaud, and Amorim, Michel-Ange
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Information and Computing Sciences ,Machine Learning ,Psychology ,Behavioral and Social Science ,Decision Making ,Choice Behavior ,Reaction Time ,Intuition - Abstract
The Drift-Diffusion Model (DDM) is widely accepted for two-alternative forced-choice decision paradigms thanks to its simple formalism and close fit to behavioral and neurophysiological data. However, this formalism presents strong limitations in capturing inter-trial dynamics at the single-trial level and endogenous influences. We propose a novel model, the non-linear Drift-Diffusion Model (nl-DDM), that addresses these issues by allowing the existence of several trajectories to the decision boundary. We show that the non-linear model performs better than the drift-diffusion model for an equivalent complexity. To give better intuition on the meaning of nl-DDM parameters, we compare the DDM and the nl-DDM through correlation analysis. This paper provides evidence of the functioning of our model as an extension of the DDM. Moreover, we show that the nl-DDM captures time effects better than the DDM. Our model paves the way toward more accurately analyzing across-trial variability for perceptual decisions and accounts for peri-stimulus influences.
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- 2023
7. Exact Gaussian processes for massive datasets via non-stationary sparsity-discovering kernels
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Noack, Marcus M, Krishnan, Harinarayan, Risser, Mark D, and Reyes, Kristofer G
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Machine Learning ,Information and Computing Sciences ,Computer Vision and Multimedia Computation - Abstract
A Gaussian Process (GP) is a prominent mathematical framework for stochastic function approximation in science and engineering applications. Its success is largely attributed to the GP's analytical tractability, robustness, and natural inclusion of uncertainty quantification. Unfortunately, the use of exact GPs is prohibitively expensive for large datasets due to their unfavorable numerical complexity of [Formula: see text] in computation and [Formula: see text] in storage. All existing methods addressing this issue utilize some form of approximation-usually considering subsets of the full dataset or finding representative pseudo-points that render the covariance matrix well-structured and sparse. These approximate methods can lead to inaccuracies in function approximations and often limit the user's flexibility in designing expressive kernels. Instead of inducing sparsity via data-point geometry and structure, we propose to take advantage of naturally-occurring sparsity by allowing the kernel to discover-instead of induce-sparse structure. The premise of this paper is that the data sets and physical processes modeled by GPs often exhibit natural or implicit sparsities, but commonly-used kernels do not allow us to exploit such sparsity. The core concept of exact, and at the same time sparse GPs relies on kernel definitions that provide enough flexibility to learn and encode not only non-zero but also zero covariances. This principle of ultra-flexible, compactly-supported, and non-stationary kernels, combined with HPC and constrained optimization, lets us scale exact GPs well beyond 5 million data points.
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- 2023
8. A new approach for microstructure imaging
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Plancoulaine, Benoît, Rasmusson, Allan, Labbé, Christophe, Levenson, Richard, and Laurinavicius, Arvydas
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Information and Computing Sciences ,Graphics ,Augmented Reality and Games ,Biological Sciences ,Algorithms ,Lighting ,Imaging ,Three-Dimensional - Abstract
A recurring issue with microstructure studies is specimen lighting. In particular, microscope lighting must be deployed in such a way as to highlight biological elements without enhancing caustic effects and diffraction. We describe here a high frequency technique due to address this lighting issue. First, an extensive study is undertaken concerning asymptotic equations in order to identify the most promising algorithm for 3D microstructure analysis. Ultimately, models based on virtual light rays are discarded in favor of a model that considers the joint computation of phase and irradiance. This paper maintains the essential goal of the study concerning biological microstructures but offers several supplementary notes on computational details which provide perspectives on analyses of the arrangements of numerous objects in biological tissues.
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- 2022
9. Detecting damaged buildings using real-time crowdsourced images and transfer learning
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Chachra, Gaurav, Kong, Qingkai, Huang, Jim, Korlakunta, Srujay, Grannen, Jennifer, Robson, Alexander, and Allen, Richard M
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Civil Engineering ,Information and Computing Sciences ,Engineering ,Crowdsourcing ,Earthquakes ,Humans ,Machine Learning ,Smartphone ,Social Media - Abstract
After significant earthquakes, we can see images posted on social media platforms by individuals and media agencies owing to the mass usage of smartphones these days. These images can be utilized to provide information about the shaking damage in the earthquake region both to the public and research community, and potentially to guide rescue work. This paper presents an automated way to extract the damaged buildings images after earthquakes from social media platforms such as Twitter and thus identify the particular user posts containing such images. Using transfer learning and ~ 6500 manually labelled images, we trained a deep learning model to recognize images with damaged buildings in the scene. The trained model achieved good performance when tested on newly acquired images of earthquakes at different locations and when ran in near real-time on Twitter feed after the 2020 M7.0 earthquake in Turkey. Furthermore, to better understand how the model makes decisions, we also implemented the Grad-CAM method to visualize the important regions on the images that facilitate the decision.
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- 2022
10. A probabilistic computational framework for the prediction of corrosion-induced cracking in large structures
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Qian, Guofeng, Tantratian, Karnpiwat, Chen, Lei, Hu, Zhen, and Todd, Michael D
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Civil Engineering ,Information and Computing Sciences ,Engineering - Abstract
Corrosion can initiate cracking that leads to structural integrity reduction. Quantitative corrosion assessment is challenging, and the modeling of corrosion-induced crack initiation is essential for model-based corrosion reliability analysis of various structures. This paper proposes a probabilistic computational analysis framework for corrosion-to-crack transitions by integrating a phase-field model with machine learning and uncertainty quantification. An electro-chemo-mechanical phase-field model is modified to predict pitting corrosion evolution, in which stress is properly coupled into the electrode chemical potential. A crack initiation criterion based on morphology is proposed to quantify the pit-to-cracking transition. A spatiotemporal surrogate modeling method is developed to facilitate this, consisting of a Convolution Neural Network (CNN) to map corrosion morphology to latent spaces, and a Gaussian Process regression model with a nonlinear autoregressive exogenous model (NARX) architecture for prediction of corrosion dynamics in the latent space over time. It enables the real-time prediction of corrosion morphology and crack initiation behaviors (whether, when, and where the corrosion damage triggers the crack initiation), and thus makes it possible for probabilistic analysis, with uncertainty quantified. Examples at various stress and corrosion conditions are presented to demonstrate the proposed computational framework.
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- 2022
11. The field of human building interaction for convergent research and innovation for intelligent built environments
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Becerik-Gerber, Burcin, Lucas, Gale, Aryal, Ashrant, Awada, Mohamad, Bergés, Mario, Billington, Sarah, Boric-Lubecke, Olga, Ghahramani, Ali, Heydarian, Arsalan, Höelscher, Christoph, Jazizadeh, Farrokh, Khan, Azam, Langevin, Jared, Liu, Ruying, Marks, Frederick, Mauriello, Matthew Louis, Murnane, Elizabeth, Noh, Haeyoung, Pritoni, Marco, Roll, Shawn, Schaumann, Davide, Seyedrezaei, Mirmahdi, Taylor, John E, Zhao, Jie, and Zhu, Runhe
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Information and Computing Sciences ,Architecture ,Built Environment and Design ,Humans ,Consensus ,Forecasting ,Built Environment - Abstract
Human-Building Interaction (HBI) is a convergent field that represents the growing complexities of the dynamic interplay between human experience and intelligence within built environments. This paper provides core definitions, research dimensions, and an overall vision for the future of HBI as developed through consensus among 25 interdisciplinary experts in a series of facilitated workshops. Three primary areas contribute to and require attention in HBI research: humans (human experiences, performance, and well-being), buildings (building design and operations), and technologies (sensing, inference, and awareness). Three critical interdisciplinary research domains intersect these areas: control systems and decision making, trust and collaboration, and modeling and simulation. Finally, at the core, it is vital for HBI research to center on and support equity, privacy, and sustainability. Compelling research questions are posed for each primary area, research domain, and core principle. State-of-the-art methods used in HBI studies are discussed, and examples of original research are offered to illustrate opportunities for the advancement of HBI research.
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- 2022
12. Validating deep learning inference during chest X-ray classification for COVID-19 screening
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Sadre, Robbie, Sundaram, Baskaran, Majumdar, Sharmila, and Ushizima, Daniela
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Information and Computing Sciences ,Biomedical and Clinical Sciences ,Clinical Sciences ,Prevention ,Infectious Diseases ,Algorithms ,COVID-19 ,Deep Learning ,Humans ,Lung ,Neural Networks ,Computer ,Pandemics ,Radiography ,Thoracic ,Reproducibility of Results ,SARS-CoV-2 ,Sensitivity and Specificity ,X-Rays - Abstract
The new coronavirus unleashed a worldwide pandemic in early 2020, and a fatality rate several times that of the flu. As the number of infections soared, and capabilities for testing lagged behind, chest X-ray (CXR) imaging became more relevant in the early diagnosis and treatment planning for patients with suspected or confirmed COVID-19 infection. In a few weeks, proposed new methods for lung screening using deep learning rapidly appeared, while quality assurance discussions lagged behind. This paper proposes a set of protocols to validate deep learning algorithms, including our ROI Hide-and-Seek protocol, which emphasizes or hides key regions of interest from CXR data. Our protocol allows assessing the classification performance for anomaly detection and its correlation to radiological signatures, an important issue overlooked in several deep learning approaches proposed so far. By running a set of systematic tests over CXR representations using public image datasets, we demonstrate the weaknesses of current techniques and offer perspectives on the advantages and limitations of automated radiography analysis when using heterogeneous data sources.
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- 2021
13. Autonomous materials discovery driven by Gaussian process regression with inhomogeneous measurement noise and anisotropic kernels
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Noack, Marcus M, Doerk, Gregory S, Li, Ruipeng, Streit, Jason K, Vaia, Richard A, Yager, Kevin G, and Fukuto, Masafumi
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Information and Computing Sciences ,Machine Learning - Abstract
A majority of experimental disciplines face the challenge of exploring large and high-dimensional parameter spaces in search of new scientific discoveries. Materials science is no exception; the wide variety of synthesis, processing, and environmental conditions that influence material properties gives rise to particularly vast parameter spaces. Recent advances have led to an increase in the efficiency of materials discovery by increasingly automating the exploration processes. Methods for autonomous experimentation have become more sophisticated recently, allowing for multi-dimensional parameter spaces to be explored efficiently and with minimal human intervention, thereby liberating the scientists to focus on interpretations and big-picture decisions. Gaussian process regression (GPR) techniques have emerged as the method of choice for steering many classes of experiments. We have recently demonstrated the positive impact of GPR-driven decision-making algorithms on autonomously-steered experiments at a synchrotron beamline. However, due to the complexity of the experiments, GPR often cannot be used in its most basic form, but rather has to be tuned to account for the special requirements of the experiments. Two requirements seem to be of particular importance, namely inhomogeneous measurement noise (input-dependent or non-i.i.d.) and anisotropic kernel functions, which are the two concepts that we tackle in this paper. Our synthetic and experimental tests demonstrate the importance of both concepts for experiments in materials science and the benefits that result from including them in the autonomous decision-making process.
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- 2020
14. Probabilistic variable-length segmentation of protein sequences for discriminative motif discovery (DiMotif) and sequence embedding (ProtVecX)
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Asgari, Ehsaneddin, McHardy, Alice C, and Mofrad, Mohammad RK
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Biochemistry and Cell Biology ,Bioinformatics and Computational Biology ,Biological Sciences ,Information and Computing Sciences ,Machine Learning ,Networking and Information Technology R&D (NITRD) ,Amino Acid Motifs ,Amino Acid Sequence ,Computational Biology ,Proteins ,Sequence Analysis - Abstract
In this paper, we present peptide-pair encoding (PPE), a general-purpose probabilistic segmentation of protein sequences into commonly occurring variable-length sub-sequences. The idea of PPE segmentation is inspired by the byte-pair encoding (BPE) text compression algorithm, which has recently gained popularity in subword neural machine translation. We modify this algorithm by adding a sampling framework allowing for multiple ways of segmenting a sequence. PPE segmentation steps can be learned over a large set of protein sequences (Swiss-Prot) or even a domain-specific dataset and then applied to a set of unseen sequences. This representation can be widely used as the input to any downstream machine learning tasks in protein bioinformatics. In particular, here, we introduce this representation through protein motif discovery and protein sequence embedding. (i) DiMotif: we present DiMotif as an alignment-free discriminative motif discovery method and evaluate the method for finding protein motifs in three different settings: (1) comparison of DiMotif with two existing approaches on 20 distinct motif discovery problems which are experimentally verified, (2) classification-based approach for the motifs extracted for integrins, integrin-binding proteins, and biofilm formation, and (3) in sequence pattern searching for nuclear localization signal. The DiMotif, in general, obtained high recall scores, while having a comparable F1 score with other methods in the discovery of experimentally verified motifs. Having high recall suggests that the DiMotif can be used for short-list creation for further experimental investigations on motifs. In the classification-based evaluation, the extracted motifs could reliably detect the integrins, integrin-binding, and biofilm formation-related proteins on a reserved set of sequences with high F1 scores. (ii) ProtVecX: we extend k-mer based protein vector (ProtVec) embedding to variablelength protein embedding using PPE sub-sequences. We show that the new method of embedding can marginally outperform ProtVec in enzyme prediction as well as toxin prediction tasks. In addition, we conclude that the embeddings are beneficial in protein classification tasks when they are combined with raw amino acids k-mer features.
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- 2019
15. Imaging beyond ultrasonically-impenetrable objects
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Ilovitsh, Tali, Ilovitsh, Asaf, Foiret, Josquin, and Ferrara, Katherine W
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Data Management and Data Science ,Information and Computing Sciences ,Physical Sciences ,Biomedical Imaging ,Bioengineering ,Cancer ,Animals ,Humans ,Phantoms ,Imaging ,Ultrasonography - Abstract
Ultrasound images are severely degraded by the presence of obstacles such as bones and air gaps along the beam path. This paper describes a method for imaging structures that are distal to obstacles that are otherwise impenetrable to ultrasound. The method uses an optically-inspired holographic algorithm to beam-shape the emitted ultrasound field in order to bypass the obstacle and place the beam focus beyond the obstruction. The resulting performance depends on the transducer aperture, the size and position of the obstacle, and the position of the target. Improvement compared to standard ultrasound imaging is significant for obstacles for which the width is larger than one fourth of the transducer aperture and the depth is within a few centimeters of the transducer. For such cases, the improvement in focal intensity at the location of the target reaches 30-fold, and the improvement in peak-to-side-lobe ratio reaches 3-fold. The method can be implemented in conventional ultrasound systems, and the entire process can be performed in real time. This method has applications in the fields of cancer detection, abdominal imaging, imaging of vertebral structure and ultrasound tomography. Here, its effectiveness is demonstrated using wire targets, tissue mimicking phantoms and an ex vivo biological sample.
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- 2018
16. Sigmoidal Acquisition Curves Are Good Indicators of Conformist Transmission
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Smaldino, Paul E, Aplin, Lucy M, and Farine, Damien R
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Information and Computing Sciences ,Machine Learning ,Psychology ,Behavioral and Social Science ,Animals ,Humans ,Learning ,Social Behavior ,Social Conformity - Abstract
The potential for behaviours to spread via cultural transmission has profound implications for our understanding of social dynamics and evolution. Several studies have provided empirical evidence that local traditions can be maintained in animal populations via conformist learning (i.e. copying the majority). A conformist bias can be characterized by a sigmoidal relationship between a behavior's prevalence in the population and an individual's propensity to adopt that behavior. For this reason, the presence of conformist learning in a population is often inferred from a sigmoidal acquisition curve in which the overall rate of adoption for the behavior is taken as the dependent variable. However, the validity of sigmoidal acquisition curves as evidence for conformist learning has recently been challenged by models suggesting that such curves can arise via alternative learning rules that do not involve conformity. We review these models, and find that the proposed alternative learning mechanisms either rely on faulty or unrealistic assumptions, or apply only in very specific cases. We therefore recommend that sigmoidal acquisition curves continue to be taken as evidence for conformist learning. Our paper also highlights the importance of understanding the generative processes of a model, rather than only focusing solely on the patterns produced. By studying these processes, our analysis suggests that current practices by empiricists have provided robust evidence for conformist transmission in both humans and non-human animals.Arising from: Acerbi, A. et al. Sci. Rep. 6, 36068 (2016); https://doi.org/10.1038/srep36068 .
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- 2018
17. Magnetoresistive biosensors with on-chip pulsed excitation and magnetic correlated double sampling
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Kim, Kyunglok, Hall, Drew A, Yao, Chengyang, Lee, Jung-Rok, Ooi, Chin C, Bechstein, Daniel JB, Guo, Yue, and Wang, Shan X
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Engineering ,Biomedical Engineering ,Information and Computing Sciences ,Electrical Engineering ,Electronics ,Sensors and Digital Hardware ,Data Management and Data Science ,Bioengineering ,4.1 Discovery and preclinical testing of markers and technologies ,Detection ,screening and diagnosis ,Algorithms ,Biosensing Techniques ,Equipment Design ,Lab-On-A-Chip Devices ,Magnetics ,Models ,Theoretical ,Point-of-Care Systems ,Temperature - Abstract
Giant magnetoresistive (GMR) sensors have been shown to be among the most sensitive biosensors reported. While high-density and scalable sensor arrays are desirable for achieving multiplex detection, scalability remains challenging because of long data acquisition time using conventional readout methods. In this paper, we present a scalable magnetoresistive biosensor array with an on-chip magnetic field generator and a high-speed data acquisition method. The on-chip field generators enable magnetic correlated double sampling (MCDS) and global chopper stabilization to suppress 1/f noise and offset. A measurement with the proposed system takes only 20 ms, approximately 50× faster than conventional frequency domain analysis. A corresponding time domain temperature correction technique is also presented and shown to be able to remove temperature dependence from the measured signal without extra measurements or reference sensors. Measurements demonstrate detection of magnetic nanoparticles (MNPs) at a signal level as low as 6.92 ppm. The small form factor enables the proposed platform to be portable as well as having high sensitivity and rapid readout, desirable features for next generation diagnostic systems, especially in point-of-care (POC) settings.
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- 2018
18. Multimodal and Multiscale Deep Neural Networks for the Early Diagnosis of Alzheimer’s Disease using structural MR and FDG-PET images
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Lu, Donghuan, Popuri, Karteek, Ding, Gavin Weiguang, Balachandar, Rakesh, Beg, Mirza Faisal, and Alzheimer’s Disease Neuroimaging Initiative
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Information and Computing Sciences ,Biochemistry and Cell Biology ,Biological Sciences ,Neurodegenerative ,Aging ,Prevention ,Alzheimer's Disease ,Neurosciences ,Dementia ,Brain Disorders ,Bioengineering ,Biomedical Imaging ,Acquired Cognitive Impairment ,Machine Learning and Artificial Intelligence ,Networking and Information Technology R&D (NITRD) ,Clinical Research ,Alzheimer's Disease including Alzheimer's Disease Related Dementias (AD/ADRD) ,4.1 Discovery and preclinical testing of markers and technologies ,4.2 Evaluation of markers and technologies ,Neurological ,Aged ,Aged ,80 and over ,Alzheimer Disease ,Brain ,Case-Control Studies ,Cognitive Dysfunction ,Deep Learning ,Early Diagnosis ,Fluorodeoxyglucose F18 ,Humans ,Magnetic Resonance Imaging ,Middle Aged ,Multimodal Imaging ,Neural Networks ,Computer ,Positron-Emission Tomography ,Radiopharmaceuticals ,Sensitivity and Specificity ,Alzheimer’s Disease Neuroimaging Initiative - Abstract
Alzheimer's Disease (AD) is a progressive neurodegenerative disease where biomarkers for disease based on pathophysiology may be able to provide objective measures for disease diagnosis and staging. Neuroimaging scans acquired from MRI and metabolism images obtained by FDG-PET provide in-vivo measurements of structure and function (glucose metabolism) in a living brain. It is hypothesized that combining multiple different image modalities providing complementary information could help improve early diagnosis of AD. In this paper, we propose a novel deep-learning-based framework to discriminate individuals with AD utilizing a multimodal and multiscale deep neural network. Our method delivers 82.4% accuracy in identifying the individuals with mild cognitive impairment (MCI) who will convert to AD at 3 years prior to conversion (86.4% combined accuracy for conversion within 1-3 years), a 94.23% sensitivity in classifying individuals with clinical diagnosis of probable AD, and a 86.3% specificity in classifying non-demented controls improving upon results in published literature.
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- 2018
19. Hardware emulation of stochastic p-bits for invertible logic
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Pervaiz, Ahmed Zeeshan, Ghantasala, Lakshmi Anirudh, Camsari, Kerem Yunus, and Datta, Supriyo
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Information and Computing Sciences ,Machine Learning ,cs.ET - Abstract
The common feature of nearly all logic and memory devices is that they make use of stable units to represent 0's and 1's. A completely different paradigm is based on three-terminal stochastic units which could be called "p-bits", where the output is a random telegraphic signal continuously fluctuating between 0 and 1 with a tunable mean. p-bits can be interconnected to receive weighted contributions from others in a network, and these weighted contributions can be chosen to not only solve problems of optimization and inference but also to implement precise Boolean functions in an inverted mode. This inverted operation of Boolean gates is particularly striking: They provide inputs consistent to a given output along with unique outputs to a given set of inputs. The existing demonstrations of accurate invertible logic are intriguing, but will these striking properties observed in computer simulations carry over to hardware implementations? This paper uses individual micro controllers to emulate p-bits, and we present results for a 4-bit ripple carry adder with 48 p-bits and a 4-bit multiplier with 46 p-bits working in inverted mode as a factorizer. Our results constitute a first step towards implementing p-bits with nano devices, like stochastic Magnetic Tunnel Junctions.
- Published
- 2017
20. Pattern Discovery in Brain Imaging Genetics via SCCA Modeling with a Generic Non-convex Penalty
- Author
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Du, Lei, Liu, Kefei, Yao, Xiaohui, Yan, Jingwen, Risacher, Shannon L, Han, Junwei, Guo, Lei, Saykin, Andrew J, Shen, Li, and Alzheimer’s Disease Neuroimaging Initiative
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Information and Computing Sciences ,Computer Vision and Multimedia Computation ,Neurosciences ,Alzheimer's Disease ,Genetics ,Alzheimer's Disease including Alzheimer's Disease Related Dementias (AD/ADRD) ,Dementia ,Biomedical Imaging ,Brain Disorders ,Neurodegenerative ,Aging ,Acquired Cognitive Impairment ,Aged ,Algorithms ,Alzheimer Disease ,Female ,Humans ,Image Processing ,Computer-Assisted ,Male ,Models ,Statistical ,Multivariate Analysis ,Neuroimaging ,Pattern Recognition ,Automated ,Phenotype ,Polymorphism ,Single Nucleotide ,Alzheimer’s Disease Neuroimaging Initiative - Abstract
Brain imaging genetics intends to uncover associations between genetic markers and neuroimaging quantitative traits. Sparse canonical correlation analysis (SCCA) can discover bi-multivariate associations and select relevant features, and is becoming popular in imaging genetic studies. The L1-norm function is not only convex, but also singular at the origin, which is a necessary condition for sparsity. Thus most SCCA methods impose [Formula: see text]-norm onto the individual feature or the structure level of features to pursuit corresponding sparsity. However, the [Formula: see text]-norm penalty over-penalizes large coefficients and may incurs estimation bias. A number of non-convex penalties are proposed to reduce the estimation bias in regression tasks. But using them in SCCA remains largely unexplored. In this paper, we design a unified non-convex SCCA model, based on seven non-convex functions, for unbiased estimation and stable feature selection simultaneously. We also propose an efficient optimization algorithm. The proposed method obtains both higher correlation coefficients and better canonical loading patterns. Specifically, these SCCA methods with non-convex penalties discover a strong association between the APOE e4 rs429358 SNP and the hippocampus region of the brain. They both are Alzheimer's disease related biomarkers, indicating the potential and power of the non-convex methods in brain imaging genetics.
- Published
- 2017
21. Perceptual Modalities Guiding Bat Flight in a Native Habitat
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Kong, Zhaodan, Fuller, Nathan, Wang, Shuai, Özcimder, Kayhan, Gillam, Erin, Theriault, Diane, Betke, Margrit, and Baillieul, John
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Information and Computing Sciences ,Biological Sciences ,Ecology ,Neurosciences ,Animals ,Behavior ,Animal ,Chiroptera ,Echolocation ,Ecosystem ,Flight ,Animal ,Robotics ,Space Perception ,Spatial Memory ,Vision ,Ocular - Abstract
Flying animals accomplish high-speed navigation through fields of obstacles using a suite of sensory modalities that blend spatial memory with input from vision, tactile sensing, and, in the case of most bats and some other animals, echolocation. Although a good deal of previous research has been focused on the role of individual modes of sensing in animal locomotion, our understanding of sensory integration and the interplay among modalities is still meager. To understand how bats integrate sensory input from echolocation, vision, and spatial memory, we conducted an experiment in which bats flying in their natural habitat were challenged over the course of several evening emergences with a novel obstacle placed in their flight path. Our analysis of reconstructed flight data suggests that vision, echolocation, and spatial memory together with the possible exercise of an ability in using predictive navigation are mutually reinforcing aspects of a composite perceptual system that guides flight. Together with the recent development in robotics, our paper points to the possible interpretation that while each stream of sensory information plays an important role in bat navigation, it is the emergent effects of combining modalities that enable bats to fly through complex spaces.
- Published
- 2016
22. Three-dimensional fluorescent microscopy via simultaneous illumination and detection at multiple planes
- Author
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Ma, Qian, Khademhosseinieh, Bahar, Huang, Eric, Qian, Haoliang, Bakowski, Malina A, Troemel, Emily R, and Liu, Zhaowei
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Information and Computing Sciences ,Graphics ,Augmented Reality and Games ,Bioengineering - Abstract
The conventional optical microscope is an inherently two-dimensional (2D) imaging tool. The objective lens, eyepiece and image sensor are all designed to capture light emitted from a 2D 'object plane'. Existing technologies, such as confocal or light sheet fluorescence microscopy have to utilize mechanical scanning, a time-multiplexing process, to capture a 3D image. In this paper, we present a 3D optical microscopy method based upon simultaneously illuminating and detecting multiple focal planes. This is implemented by adding two diffractive optical elements to modify the illumination and detection optics. We demonstrate that the image quality of this technique is comparable to conventional light sheet fluorescent microscopy with the advantage of the simultaneous imaging of multiple axial planes and reduced number of scans required to image the whole sample volume.
- Published
- 2016
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