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18 results on '"Pierre-Olivier Bagnaninchi"'

7. MMV-Net: A Multiple Measurement Vector Network for Multifrequency Electrical Impedance Tomography

Author

Zhou Chen, Jinxi Xiang, Pierre-Olivier Bagnaninchi, and Yunjie Yang

Subjects
Conductivity, EIT, multifrequency, Computer Networks and Communications, Image and Video Processing (eess.IV), MMV, Deep learning, Electrical Engineering and Systems Science - Image and Video Processing, image reconstruction, multiple measurement vector (MMV), Correlation, Computer Science Applications, Biomedical imaging, Electrical impedance tomography, Artificial Intelligence, Electrical impedance tomography (EIT), multiple measurement vectors, Frequency measurement, FOS: Electrical engineering, electronic engineering, information engineering, Software
Abstract

Multi-frequency Electrical Impedance Tomography (mfEIT) is an emerging biomedical imaging modality to reveal frequency-dependent conductivity distributions in biomedical ap-plications. Conventional model-based image reconstruction meth-ods suffer from low spatial resolution, unconstrained frequency correlation and high computational cost. Deep learning has been extensively applied in solving the EIT inverse problem in biomed-ical and industrial process imaging. However, most existing learning-based approaches deal with the single-frequency setup, which is inefficient and ineffective when extended to the multi-frequency setup. This paper presents a Multiple Measurement Vector (MMV) model based learning algorithm named MMV-Net to solve the mfEIT image reconstruction problem. MMV-Net considers the correlations between mfEIT images and unfolds the update steps of the Alternating Direction Method of Multipliers for the MMV problem (MMV-ADMM). The non-linear shrinkage operator associated with the weighted l2,1 regularization term of MMV-ADMM is generalized in MMV-Net with a cascade of a Spatial Self-Attention module and a Convolutional Long Short-Term Memory (ConvLSTM) module to better capture intra- and inter-frequency dependencies. The proposed MMV-Net was validated on our Edinburgh mfEIT Dataset and a series of comprehensive experiments. The results show superior image quality, convergence performance, noise robustness and computational efficiency against the conventional MMV-ADMM and the state-of-the-art deep learning methods.

Published
2022
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10. Enhanced Multi-Scale Feature Cross-Fusion Network for Impedance-optical Dual-modal Imaging

Author

Zhe Liu, Renjie Zhao, Graham Anderson, Pierre-Olivier Bagnaninchi, and Yunjie Yang

Subjects
Conductivity, Electrical impedance tomography, Sensors, Image reconstruction, information fusion, deep learning, Feature extraction, Dual-modal imaging, mask image correction, Voltage, Electrical and Electronic Engineering, Instrumentation, Imaging
Abstract

The intrinsic issue of low spatial resolution of Electrical Impedance Tomography (EIT) is a long-standing challenge that hinders the capability of performing quantitative analysis based on EIT image. Our recent work demonstrates an impedance-optical dual-modal imaging framework and a deep learning model named Multi-Scale Feature Cross Fusion Network (MSFCF-Net) to realize information fusion and high-quality EIT image reconstruction. However, this framework’s performance is limited by the accuracy of the mask image obtained from an auxiliary imaging modality. This paper further proposes a two-stage deep neural network, which is the enhanced version of the MSFCF-Net (named En-MSFCF-Net), to automatically improve mask image and conduct information fusion and image reconstruction. Compared to MSFCF-Net, En-MSFCF-Net demonstrates the superior ability to correct the inaccurate mask image, leading to a more accurate conductivity estimation. Furthermore, the En-MSFCF-Net also maintains the best shape preservation and conductivity prediction accuracy among given learning-based and model-based algorithms. Both qualitative and quantitative results indicate that En-MSFCF-Net could make dual-modal imaging more robust in real-world situations.

Published
2022
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11. Hybrid Learning-Based Cell Aggregate Imaging With Miniature Electrical Impedance Tomography

Author

Yunjie Yang, Pierre-Olivier Bagnaninchi, and Zhou Chen

Subjects
Artificial neural network, Computer science, business.industry, Image quality, Deep learning, 020208 electrical & electronic engineering, Pattern recognition, 02 engineering and technology, Iterative reconstruction, Regularization (mathematics), Tissue engineering, 0202 electrical engineering, electronic engineering, information engineering, Artificial intelligence, Sensitivity (control systems), Tomography, Electrical and Electronic Engineering, business, Instrumentation, Electrical impedance tomography, Human breast
Abstract

Real-time, non-destructive and label-free imaging of 3-D cell culture process using miniature Electrical Impedance Tomography (mEIT) is an emerging topic in tissue engineering. Image reconstruction of mEIT for cell culture is challenging due to weak sensing signals and increased sensitivity to sensor imperfection.Conventional regularization based image reconstruction methods can not always achieve satisfactory performance in terms of image quality and computational efficiency for this particular setup. Recent advances of deep learning have pointed out a promising alternative. However, with a single neural network, it is still difficult to reconstruct multiple objects with varying conductivity levels, which cases are widespread in the application of cell imaging. Aiming at this challenge, in this paper we propose a deep learning and group sparsity regularization based hybrid algorithm for cell imaging with mEIT. A deep neural network is proposed to estimate the structural information in form of binarymasks given the limited amount of data sets. Then the structural information is encoded in group sparsity regularization to obtain the final estimation of conductivity. The proposed approach is validated by both simulation and experimental data on MCF-7 human breast cancer cell aggregates, which demonstrates its superior performance and generalization ability compared witha number of existing algorithms.

Published
2021
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12. Scaffold-Based 3-D Cell Culture Imaging Using a Miniature Electrical Impedance Tomography Sensor

Author

Jiabin Jia, Pierre-Olivier Bagnaninchi, Yunjie Yang, and Hancong Wu

Subjects
Scaffold, Materials science, 010401 analytical chemistry, Iterative reconstruction, Solid modeling, 01 natural sciences, 0104 chemical sciences, Planar, Electrode, Tomography, Electrical and Electronic Engineering, Image sensor, Instrumentation, Electrical impedance tomography, Biomedical engineering
Abstract

A 3-D electrical impedance tomography (EIT) is an emerging technique for real-time and non-destructive 3-D cell culture imaging. This paper presents a pioneering study of scaffold-based 3-D cell culture imaging using a miniature planar EIT sensor. A 17-electrode miniature-planar EIT sensor equipped with a regular-shape 3-D printed scaffold was manufactured, modeled, and characterized. In addition, an efficient 3-D image reconstruction method based on 3-D isotropic total variation and ${l}$ 1 joint regularization was proposed. The numerical simulation on scaffold phantoms and the experimental study on time-varying distribution of MCF-7 cancer cell suspension within the scaffold were performed. Both the simulation and experiment results suggest that using the miniature EIT sensor and the developed 3-D image reconstruction algorithms are able to achieve high quality, non-destructive scaffold-based 3-D cell culture imaging.

Published
2019
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13. Calibrated Frequency-Difference Electrical Impedance Tomography for 3D Tissue Culture Monitoring

Author

Yunjie Yang, Pierre-Olivier Bagnaninchi, Hancong Wu, and Jiabin Jia

Subjects
current measurement, Monitoring, Image quality, Computer science, Acoustics, 01 natural sciences, equivalent circuit analysis, Electrical and Electronic Engineering, Tomography, calibrated frequency-difference EIT, Instrumentation, Electrical impedance, Electrical impedance tomography, 3D tissue culture imaging, Leakage (electronics), Total variation, Observational error, Sensors, long-term monitoring, 010401 analytical chemistry, Impedance, Voltage measurement, 0104 chemical sciences, Integrated circuit modeling, Equivalent circuit, Biological imaging, Voltage
Abstract

Electrical impedance tomography (EIT) has the potential to be an alternative technique to microscopy for many biological applications. It is a novel approach to monitor cell viability, proliferation, or drug response with high temporal resolution in a label-free, non-toxic, and non-destructive way. To limit measurement errors, only time-difference EIT is currently used for biological imaging. Still, the need for constant background reference limits its uses in long-term imaging. A novel equivalent circuit model was developed to analyze the errors in frequency-difference EIT (FDEIT) measurements. Based on the circuit model, the calibrated FDEIT (CFDEIT) method has been derived to compensate the measurement errors. The simulation results show that the voltage variations introduced by the leakage current are correctly modeled by the equivalent circuit. Significant improvements in the image quality are observed in both simulation and experimental results after the application of CFDEIT. It indicates that this paper improves the accuracy of FDEIT and makes it feasible for 3D tissue culture monitoring.

Published
2019
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14. Blue-light induced breakdown of barrier function on human retinal epithelial cells is mediated by PKC-ζ over-activation and oxidative stress

Author

Ege Kaan Ozkaya, Baljean Dhillon, Graham Anderson, and Pierre-Olivier Bagnaninchi

Subjects
0301 basic medicine, Light, Cell Count, Retinal Pigment Epithelium, medicine.disease_cause, Cell Line, law.invention, Macular Degeneration, 03 medical and health sciences, Cellular and Molecular Neuroscience, chemistry.chemical_compound, Imaging, Three-Dimensional, 0302 clinical medicine, Electrical resistance and conductance, law, medicine, Humans, Impedance sensing, Protein Kinase C, Barrier function, Blue light, Retinal pigment epithelium, Epithelial Cells, Retinal, Sensory Systems, Oxidative Stress, Ophthalmology, 030104 developmental biology, medicine.anatomical_structure, chemistry, 030221 ophthalmology & optometry, Biophysics, Reactive Oxygen Species, Oxidative stress, Signal Transduction, Light-emitting diode
Abstract

We aimed to study the time course decrease of human retinal pigment epithelium (RPE) barrier function when exposed to blue light. To this end, we cultured ARPE-19 cells on Electrical Cell-substrate Impedance Sensing (ECIS) multi-well arrays. Using an ad hoc light emitting diode (LED) array illumination system together with a set of neutral density filters and a 3-dimensional (3D) printed filter holder, cells were exposed to a gradient of irradiances of blue-light with a measured peak at 468 nm. The electrical resistance between 4 kHz and 64 kHz was recorded during the exposure. Blue light exposure induced a dose-dependent decrease in the resistances at 4 kHz, however the time course resistance at 64 kHz did not show any decrease before t = 52 h. Quantification of the barrier function using mathematical model integrated in the ECIS software showed that blue-light exposure induced a dose-dependent decrease in the barrier function associated with tight junction formation (P 0.05). This was confirmed by the immunostaining of the tight-junction associated structural protein, Zonula occludens-1 (ZO-1). The detection of reactive oxygen species by carboxy-H2DCFDA confirmed that the blue light induced dose-dependent decrease in the barrier function is mediated by oxidative stress. On a separate experiment, blue-light exposed ARPE-19 cells were treated with 100 nM Protein Kinase C zeta (PKC-ζ) pseudo substrate inhibitor to identify underlying pathway for blue-light induced damage on the barrier function. The treatment with 100 nM PKC-ζ pseudo substrate inhibitor induced faster recovery of the barrier function compared to no treatment. Altogether our results document that blue LED light exposure decreased RPE barrier function in-vitro in a dose-dependent manner, before any cell death occurred. This damage induced by blue-light on tight junctions is mediated by oxidative stress through PKC-ζ activation. The quantification of the healing effect observed by inhibition of PKC-ζ might lead to development of high throughput wound healing assays through ECIS in the future.

Published
2019
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15. A Miniature Electrical Impedance Tomography Sensor and 3-D Image Reconstruction for Cell Imaging

Author

Nadira Jamil, Yunjie Yang, Stewart Smith, Pierre-Olivier Bagnaninchi, Jiabin Jia, and Wesam Gamal

Subjects
Standard cell, Engineering, Image quality, image sensors, 02 engineering and technology, Iterative reconstruction, tomography, 01 natural sciences, Regularization (mathematics), medical image processing, Phantoms, Planar, miniature sensor, 0202 electrical engineering, electronic engineering, information engineering, Image Reconstruction, Computer vision, Electrical and Electronic Engineering, Image sensor, cellular biophysics, Instrumentation, Electrical impedance tomography, Cancer, 3D image reconstruction, business.industry, Sensors, 020208 electrical & electronic engineering, 010401 analytical chemistry, Electrical impedance imaging, 0104 chemical sciences, electrodes, Three-dimensional displays, Artificial intelligence, Tomography, Cell culture, business, Biomedical engineering
Abstract

Real-time quantitative imaging is becoming highly desirable to study nondestructively the biological behavior of 3-D cell culture systems. In this paper, we investigate the feasibility of quantitative imaging/monitoring of 3-D cell culture processes via electrical impedance tomography (EIT), which is capable of generating conductivity images in a non-destructive manner with high temporal resolution. To this end, a planar miniature EIT sensor amenable to standard cell culture format is designed, and a 3-D forward model for the sensor is developed for 3-D imaging. Furthermore, a novel 3-D-Laplacian and sparsity joint regularization algorithm is proposed for enhanced 3-D image reconstruction. Simulation phantoms with spheres at various vertical and horizontal positions were imaged for 3-D performance evaluation. In addition, experiments on human breast cancer cell spheroid and a triangular breast cancer cell pellet were carried out for experimental verification. The results have shown that the stable measurement on high conductive cell culture medium and the significant improvement of image quality based on the proposed regularization method are achieved. It demonstrates the feasibility of using the miniature EIT sensor and 3-D image reconstruction algorithm to visualize 3-D cell cultures, such as spheroids or artificial tissues and organs. The established work would expedite real-time quantitative imaging of 3-D cell culture for assessment of cellular dynamics.

Published
2017
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16. Towards on-line monitoring of cell growth in microporous scaffolds: Utilization and interpretation of complex permittivity measurements

Author

Pierre-Olivier Bagnaninchi, Teodor Veres, Maryam Tabrizian, and Maria Dikeakos

Subjects
Permittivity, Materials science, Cell Count, Chitin, Bioengineering, Nanotechnology, Dielectric, Electric Capacitance, Models, Biological, Online Systems, Sensitivity and Specificity, Applied Microbiology and Biotechnology, Chitosan, Mice, chemistry.chemical_compound, Tissue engineering, Culture Techniques, Electric Impedance, Electrochemistry, Animals, Computer Simulation, Porosity, chemistry.chemical_classification, Tissue Engineering, Cell growth, Macrophages, Reproducibility of Results, Membranes, Artificial, Polymer, Microporous material, Extracellular Matrix, chemistry, Algorithms, Cell Division, Biotechnology, Biomedical engineering
Abstract

Here we demonstrate the ability to characterize microporous scaffolds and evaluate cell concentration variation via the utilization and interpretation of complex permittivity measurements (CP), a direct and nondestructive method. Polymer-based microporous scaffolds are of importance to tissue engineering, particularly in the promotion of cell adhesion, proliferation, and differentiation in predefined shapes. Chitosan gel scaffolds were seeded with increasing concentrations of macrophages to simulate cell growth. Complex permittivity measurements were performed using a dielectric probe and a vector network analyzer over a frequency ranging from 200 MHz to 2 GHz. An effective medium theory was applied to interpret the data obtained; respectively, Looyenga and Maxwell-Wagner-Hanai functions were used to retrieve the porosity and the variation of the cell concentration from the CP measurements. Calculated porosities were in agreement with experimental evaluation—porosity ranged from 81–96%. Changes in cell concentration inside the scaffolds upon injection of differing cell concentrations into the scaffold were detected distinguishably. Variations resulting from the cumulative injection of 400–1800 μL of 106 cells/mL solution into the scaffold were monitored. Results suggest that CP measurements in combination with an appropriate effective medium approximation can enable on-line monitoring of cell growth within scaffolds. © 2003 Wiley Periodicals, Inc. Biotechnol Bioeng 84: 343–350, 2003.

Published
2003
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18. Doppler optical coherence tomography imaging of local fluid flow and shear stress within microporous scaffolds

Author

Yali Jia, Pierre-Olivier Bagnaninchi, Monica T. Hinds, Alicia J. El Haj, Sean J. Kirkpatrick, Ruikang K. Wang, and Ying Yang

Subjects
3D PERFUSION CULTURE, Materials science, INCREASES, Flow (psychology), Microfluidics, Biomedical Engineering, Interconnectivity, ANGIOGRAPHY, Article, shear stress, Biomaterials, Optical coherence tomography, medicine, Shear stress, Fluid dynamics, Optical tomography, interconnectivity, Porosity, porous scaffold, Doppler optical coherence tomography (DOCT), Chitosan, ARCHITECTURE, medicine.diagnostic_test, Tissue Engineering, Tissue Scaffolds, Phantoms, Imaging, local fluid flow, CHONDROCYTES, Doppler Effect, Equipment Design, IN-VITRO, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, Volumetric flow rate, TISSUE, tissue engineering, Stress, Mechanical, SENSITIVITY, Shear Strength, BONE-CELLS, Tomography, Optical Coherence, Biomedical engineering, MINERALIZED MATRIX DEPOSITION
Abstract

Establishing a relationship between perfusion rate and fluid shear stress in a 3D cell culture environment is an ongoing and challenging task faced by tissue engineers. We explore Doppler optical coherence tomography (DOCT) as a potential imaging tool for in situ monitoring of local fluid flow profiles inside porous chitosan scaffolds. From the measured fluid flow profiles, the fluid shear stresses are evaluated. We examine the localized fluid flow and shear stress within low-and high-porosity chitosan scaffolds, which are subjected to a constant input flow rate of 0.5 ml l min(-1). The DOCT results show that the behavior of the fluid flow and shear stress in micropores is strongly dependent on the micropore interconnectivity, porosity, and size of pores within the scaffold. For low-porosity and high-porosity chitosan scaffolds examined, the measured local fluid flow and shear stress varied from micropore to micropore, with a mean shear stress of 0.49 +/- 0.3 dyn.cm(-2) and 0.38 +/- 0.2 dyn.cm(-2), respectively. In addition, we show that the scaffold's porosity and interconnectivity can be quantified by combining analyses of the 3D structural and flow images obtained from DOCT. (C) 2009 Society of Photo-Optical Instrumentation Engineers. [DOI: 10.1117/1.3130345]

Published
2009
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