77 research outputs found
Vine Copula-Based Dependence Description for Multivariate Multimode Process Monitoring
A novel vine copula-based dependence
description (VCDD) process
monitoring approach is proposed. The main contribution is to extract
the complex dependence among process variables rather than perform
dimensionality reduction or other decoupling processes. For a multimode
chemical process, the C-vine copula model of each mode is initially
created, in which a multivariate optimization problem is simplified
as coping with a series of bivariate copulas listed in a sparse matrix.
To measure the distance of the process data from each non-Gaussian
mode, a generalized local probability (GLP) index is defined. Consequently,
the generalized Bayesian inference-based probability (GBIP) index
under a given control limit can be further calculated in real time
via searching the density quantile table created offline. The validity
and effectiveness of the proposed approach are illustrated using a
numerical example and the Tennessee Eastman benchmark process. The
results show that the proposed VCDD approach achieves good performance
in both monitoring results and computation load
Fault Detection and Diagnosis for Nonlinear and Non-Gaussian Processes Based on Copula Subspace Division
A novel copula subspace division
strategy is proposed for fault
detection and diagnosis. High-dimensional industrial data are analyzed
in two elemental subspaces: margin distribution subspace (MDS) modeled
by joint margin distribution, and dependence structure subspace (DSS)
modeled by copula. The highest density regions of two submodels are
introduced and quantified using probability indices. To improve the
robustness of the monitoring index, a hyperrectangular control boundary
in MDS is designed, and the equivalent univariate control limits are
estimated. Two associated contribution indices are also constructed
for fault diagnosis. The interactive relationships among the root-cause
variables are investigated via a proposed state chart. The effectiveness
and superiority of the proposed approaches (double-subspace and multisubspace)
are validated using a numerical example and the Tennessee Eastman
chemical process. Better monitoring performance is achieved compared
with some conventional approaches such as principal component analysis,
independent component analysis, kernel principal component analysis
and vine copula-based dependence description. The proposed multisubspace
approach fully utilizes univariate-based alarm data with a dependence
restriction modulus, which is promising for industrial application
Fault Detection and Diagnosis for Nonlinear and Non-Gaussian Processes Based on Copula Subspace Division
A novel copula subspace division
strategy is proposed for fault
detection and diagnosis. High-dimensional industrial data are analyzed
in two elemental subspaces: margin distribution subspace (MDS) modeled
by joint margin distribution, and dependence structure subspace (DSS)
modeled by copula. The highest density regions of two submodels are
introduced and quantified using probability indices. To improve the
robustness of the monitoring index, a hyperrectangular control boundary
in MDS is designed, and the equivalent univariate control limits are
estimated. Two associated contribution indices are also constructed
for fault diagnosis. The interactive relationships among the root-cause
variables are investigated via a proposed state chart. The effectiveness
and superiority of the proposed approaches (double-subspace and multisubspace)
are validated using a numerical example and the Tennessee Eastman
chemical process. Better monitoring performance is achieved compared
with some conventional approaches such as principal component analysis,
independent component analysis, kernel principal component analysis
and vine copula-based dependence description. The proposed multisubspace
approach fully utilizes univariate-based alarm data with a dependence
restriction modulus, which is promising for industrial application
Sequential Dependence Modeling Using Bayesian Theory and D‑Vine Copula and Its Application on Chemical Process Risk Prediction
An emerging kind of prediction model
for sequential data with multiple
time series is proposed. Because D-vine copula provides more flexibility
in dependence modeling, accounting for conditional dependence, asymmetries,
and tail dependence, it is employed to describe sequential dependence
between variables in the sample data. A D-vine model with the form
of a time window is created to fit the correlation of variables well.
To describe the randomness dynamically, Bayesian theory is also applied.
As an application, a detailed modeling of prediction of abnormal events
in a chemical process is given. Statistics (e.g., mean, variance,
skewness, kurtosis, confidence interval, etc.) of the posterior predictive
distribution are obtained by Markov chain Monte Carlo simulation.
It is shown that the model created in this paper achieves a prediction
performance better than that of some other system identification methods,
e.g., autoregressive moving average model and back propagation neural
network
Nanobody-Based Apolipoprotein E Immunosensor for Point-of-Care Testing
Alzheimer’s disease (AD) biomarkers
can reflect the neurochemical
indicators used to estimate the risk in clinical nephrology. Apolipoprotein
E (ApoE) is an early biomarker for AD in clinical diagnosis. In this
research, through bactrian camel immunization, lymphocyte isolation,
RNA extraction, and library construction, ApoE-specific Nbs with high
affinity were successfully separated from an immune phage display
nanobody library. Herein, a colorimetric immunosensor was developed
for the point-of-care testing of ApoE by layer-by-layer nanoassembly
techniques and novel nanobodies (Nbs). Using highly oriented Nbs as
the capture and detection antibodies, an on-site immunosensor was
developed by detecting the mean gray value of fade color due to the
glutaraldehyde@3-aminopropyltrimethoxysilane oxidation by H<sub>2</sub>O<sub>2</sub>. The detection limit of AopE is 0.42 pg/mL, and the
clinical analysis achieves a good performance. The novel easily operated
immunosensor may have potential application in the clinical diagnosis
and real-time monitoring for AD
Single-Cell Mechanical Characteristics Analyzed by Multiconstriction Microfluidic Channels
A microfluidic
device composed of variable numbers of multiconstriction
channels is reported in this paper to differentiate a human breast
cancer cell line, MDA-MB-231, and a nontumorigenic human breast cell
line, MCF-10A. Differences between their mechanical properties were
assessed by comparing the effect of single or multiple relaxations
on their velocity profiles which is a novel measure of their deformation
ability. Videos of the cells were recorded via a microscope using
a smartphone, and imported to a tracking software to gain the position
information on the cells. Our results indicated that a multiconstriction
channel design with five deformation (50 μm in length, 10 μm
in width, and 8 μm in height) separated by four relaxation (50
μm in length, 40 μm in width, and 30 μm in height)
regions was superior to a single deformation design in differentiating
MDA-MB-231 and MCF-10A cells. Velocity profile criteria can achieve
a differentiation accuracy around 95% for both MDA-MB-231 and MCF-10A
cells
Full Water Splitting Electrocatalyzed by NiWO<sub>4</sub> Nanowire Array
It is attractive
to develop an effective bifunctional electrocatalyst
for full water splitting. In this Letter, we report that a NiWO<sub>4</sub> nanowire array on a Ti mesh (NiWO<sub>4</sub>/TM) is a high-performance
and stable water-splitting electrocatalyst at alkaline pH. As a 3D
electrocatalyst, such a NiWO<sub>4</sub>/TM attains 20 mA cm<sup>–2</sup> under overpotentials of 101 mV for cathodic water reduction and
322 mV for anodic water oxidation. We also demonstrate the use of
NiWO<sub>4</sub>/TM to make a two-electrode electrolyzer capable of
driving 20 mA cm<sup>–2</sup> at a cell voltage of 1.65 V
Nanoporous CoP<sub>3</sub> Nanowire Array: Acid Etching Preparation and Application as a Highly Active Electrocatalyst for the Hydrogen Evolution Reaction in Alkaline Solution
Transition-metal
phosphides have been intensively and extensively
studied as earth-abundant catalysts for effective hydrogen evolution
electrocatalysis, but it is highly desired to explore a new strategy
to improve the catalytic activity. In this work, a nanoporous CoP<sub>3</sub> nanowire array on Ti mesh (np-CoP<sub>3</sub>/TM) was derived
from MnO<sub>2</sub>–CoP<sub>3</sub>/TM by acid etching of
MnO<sub>2</sub> that acts as a pore-forming agent. As a non-noble-metal
catalyst for the hydrogen evolution reaction, the resulting np-CoP<sub>3</sub>/TM demonstrates enhanced performance with the need of an
overpotential of 76 mV (<i>j</i> = 10 mV cm<sup>–2</sup>), 45 mV less than that needed by MnO<sub>2</sub>–CoP<sub>3</sub>/TM. Moreover, it also shows a good durability for at least
60 h
Image1_EZH2-mediated H3K27me3 is a predictive biomarker and therapeutic target in uveal melanoma.PNG
Although gene mutations and aberrant chromosomes are associated with the pathogenesis and prognosis of uveal melanoma (UM), potential therapeutic targets still need to be explored. We aim to determine the predictive value and potential therapeutic target of EZH2 in uveal melanoma. Eighty-five uveal melanoma samples were recruited in our study, including 19 metastatic and 66 nonmetastatic samples. qRT-PCR, immunohistochemistry staining, and western blotting were applied to detect the expression of EZH2 and H3K27me3. We found that EZH2 (41/85, 48.24%) and H3K27me3 (49/85, 57.65%) were overexpressed in uveal melanoma. The expression of EZH2 was not significantly associated with metastasis. High H3K27me3 expression was correlated with poor patient prognosis. UNC 1999, an EZH2 inhibitor, can downregulate H3K27me3 expression and has the most potency to inhibit OMM1 cell growth by the cell cycle and ferroptosis pathway. These results indicate that H3K27me3 can be a biomarker predicting a poor prognosis of UM. EZH2 is the potential therapeutic target for UM.</p
Table4_EZH2-mediated H3K27me3 is a predictive biomarker and therapeutic target in uveal melanoma.XLSX
Although gene mutations and aberrant chromosomes are associated with the pathogenesis and prognosis of uveal melanoma (UM), potential therapeutic targets still need to be explored. We aim to determine the predictive value and potential therapeutic target of EZH2 in uveal melanoma. Eighty-five uveal melanoma samples were recruited in our study, including 19 metastatic and 66 nonmetastatic samples. qRT-PCR, immunohistochemistry staining, and western blotting were applied to detect the expression of EZH2 and H3K27me3. We found that EZH2 (41/85, 48.24%) and H3K27me3 (49/85, 57.65%) were overexpressed in uveal melanoma. The expression of EZH2 was not significantly associated with metastasis. High H3K27me3 expression was correlated with poor patient prognosis. UNC 1999, an EZH2 inhibitor, can downregulate H3K27me3 expression and has the most potency to inhibit OMM1 cell growth by the cell cycle and ferroptosis pathway. These results indicate that H3K27me3 can be a biomarker predicting a poor prognosis of UM. EZH2 is the potential therapeutic target for UM.</p
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