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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Design and application of MEMS platforms for micromanipulation

Yallew, Teferi Sitotaw 22 March 2024 (has links)
The exploration of Microelectromechanical systems (MEMS) represents a crucial aspect in the advancement of modern science and technology. They offer low-cost solutions to miniaturize numerous devices. The increasing use of MEMS applications in biological research has created a pressing need for reliable micromanipulation tools. In this context, microgrippers have emerged as promising tools for the precise handling and characterization of biological samples. This thesis presents a novel biocompatible microgripper that utilizes electrothermal actuation integrated with a rotary capacitive position sensor. To overcome the limited displacement possibilities associated with electrothermal actuators, this microgripper incorporates conjugate surface flexure hinges (CSFH). These hinges enhance the desired tweezers output displacement. The designed microgripper can in principle manipulate biological samples ranging in size from 15 to 120 μm. Based on the sensitivity calculation of the rotary capacitive position sensors, the sensitivity of the displacement measurement is 102 fF/μm. By employing a kinematics modeling approach based on the pseudo-rigid-body method (PRBM), an equation for the displacement amplification factor is developed, and this equation is subsequently verified through FEM-based simulations. By comparing the amplification ratio value obtained from the analytical modeling and simulations, there is an excellent match, with a relative difference of only ~1%, thus demonstrating the effectiveness of the PRBM approach in modeling the kinematics of the structure under investigation. In addition to this, by using analytical modeling based on finite elements method (FEM), the design of the electrothermal actuator and the heat dissipation mechanism is optimized. FEM-based simulations are used to validate the theoretical modeling, demonstrating good agreement between the displacements derived from analytical modeling and simulations. The temperature difference (∆T) across a range from room temperature to 278°C exhibits a relative difference of ~2.8%. Moreover, underpass technology is implemented to ensure that electrical signals or disturbances from other parts of the device, such as the electrothermal actuation system, do not interfere with the operation and integrity of the gripping mechanism. Ultimately, the microgripper is fabricated using conventional MEMS technology from a silicon-on-insulator (SOI) wafer through the deep reactive ion etching (DRIE) technique. The integration of theoretical modeling, simulations, and practical fabrication highlights a compelling approach that has the potential for transformative applications in the field of micromanipulation and biological sample handling. Furthermore, we propose a C-shaped structure with a curved beam mechanism to improve the movement provided by the thermal actuators. The design of experiment (DOE) method is used to optimize the geometrical parameters of our proposed device. Analytical modeling based on Castigliano's second theorem and finite element method (FEM) simulations are used to predict the behavior of the symmetrical C-shaped structure; the results are in good agreement. The MEMS-based rotational structures are fabricated on silicon-on-insulator (SOI) wafers using bulk micromachining and deep reactive ion etching (DRIE). The fabricated devices are tested; our findings reveal that our proposed MEMS rotational structure outperforms the symmetrical lancet structure by 28% in terms of delivered displacement. Furthermore, the experimental results agree well with those obtained through numerical analysis.
2

Computational Gene Expression Deconvolution

Otto, Dominik 23 August 2021 (has links)
Technologies such as micro-expression arrays and high-throughput sequenc- ing assays have accelerated research of genetic transcription in biological cells. Furthermore, many links between the gene expression levels and the pheno- typic characteristics of cells have been discovered. Our current understanding of transcriptomics as an intermediate regulatory layer between genomics and proteomics raises hope that we will soon be able to decipher many more cel- lular mechanisms through the exploration of gene transcription. However, although large amounts of expression data are measured, only lim- ited information can be extracted. One general problem is the large set of considered genomic features. Expression levels are often analyzed individually because of limited computational resources and unknown statistical dependen- cies among the features. This leads to multiple testing issues or can lead to overfitting models, commonly referred to as the “curse of dimensionality.” Another problem can arise from ignorance of measurement uncertainty. In particular, approaches that consider statistical significance can suffer from underestimating uncertainty for weakly expressed genes and consequently re- quire subjective manual measures to produce consistent results (e.g., domain- specific gene filters). In this thesis, we lay out a theoretical foundation for a Bayesian interpretation of gene expression data based on subtle assumptions. Expression measure- ments are related to latent information (e.g., the transcriptome composition), which we formulate as a probability distribution that represents the uncer- tainty over the composition of the original sample. Instead of analyzing univariate gene expression levels, we use the multivari- ate transcriptome composition space. To realize computational feasibility, we develop a scalable dimensional reduction that aims to produce the best approximation that can be used with the computational resources available. To enable the deconvolution of gene expression, we describe subtissue specific probability distributions of expression profiles. We demonstrate the suitabil- ity of our approach with two deconvolution applications: first, we infer the composition of immune cells, and second we reconstruct tumor-specific ex- pression patterns from bulk-RNA-seq data of prostate tumor tissue samples.:1 Introduction 1 1.1 State of the Art and Motivation 2 1.2 Scope of this Thesis 5 2 Notation and Abbreviations 7 2.1 Notations 7 2.2 Abbreviations 9 3 Methods 10 3.1 The Convolution Assumption 10 3.2 Principal Component Analysis 11 3.3 Expression Patterns 11 3.4 Bayes’ Theorem 12 3.5 Inference Algorithms 13 3.5.1 Inference Through Sampling 13 3.5.2 Variationa lInference 14 4 Prior and Conditional Probabilities 16 4.1 Mixture Coefficients 16 4.2 Distribution of Tumor Cell Content 18 4.2.1 Optimal Tumor Cell Content Drawing 20 4.3 Transcriptome Composition Distribution 21 4.3.1 Sequencing Read Distribution 21 4.3.1.1 Empirical Plausibility Investigation 25 4.3.2 Dirichletand Normality 29 4.3.3 Theta◦logTransformation 29 4.3.4 Variance Stabilization 32 4.4 Cell and Tissue-Type-Specific Expression Pattern Distributions 32 4.4.1 Method of Moments and Factor Analysis 33 4.4.1.1 Tumor Free Cells 33 4.4.1.2 Tumor Cells 34 4.4.2 Characteristic Function 34 4.4.3 Gaussian Mixture Model 37 4.5 Prior Covariance Matrix Distribution 37 4.6 Bayesian Survival Analysis 38 4.7 Demarcation from Existing Methods 40 4.7.1 Negative Binomial Distribution 40 4.7.2 Steady State Assumption 41 4.7.3 Partial Correlation 41 4.7.4 Interaction Networks 42 5 Feasibility via Dimensional Reduction 43 5.1 DR for Deconvolution of Expression Patterns 44 5.1.1 Systematically Differential Expression 45 5.1.2 Internal Distortion 46 5.1.3 Choosinga DR 46 5.1.4 Testing the DR 47 5.2 Transformed Density Functions 49 5.3 Probability Distribution of Mixtures in DR Space 50 5.3.1 Likelihood Gradient 51 5.3.2 The Theorem 52 5.3.3 Implementation 52 5.4 DR for Inference of Cell Composition 53 5.4.1 Problem Formalization 53 5.4.2 Naive PCA 54 5.4.3 Whitening 55 5.4.3.1 Covariance Inflation 56 5.4.4 DR Through Optimization 56 5.4.4.1 Starting Point 57 5.4.4.2 The Optimization Process 58 5.4.5 Results 59 5.5 Interpretation of DR 61 5.6 Comparison to Other DRs 62 5.6.1 Weighted Correlation Network Analysis 62 5.6.2 t-Distributed Stochastic Neighbor Embedding 65 5.6.3 Diffusion Map 66 5.6.4 Non-negativeMatrix Factorization 66 5.7 Conclusion 67 6 Data for Example Application 68 6.1 Immune Cell Data 68 6.1.1 Provided List of Publicly Available Data 68 6.1.2 Obtaining the Publicly Available RNA-seq Data 69 6.1.3 Obtaining the Publicly Available Expression Microarray Data 71 6.1.4 Data Sanitization 71 6.1.4.1 A Tagging Tool 72 6.1.4.2 Tagging Results 73 6.1.4.3 Automatic Sanitization 74 6.1.5 Data Unification 75 6.1.5.1 Feature Mapping 76 6.1.5.2 Feature Selection 76 6.2 Examples of Mixtures with Gold Standard 79 6.2.1 Expression Microarray Data 81 6.2.2 Normalized Expression 81 6.2.3 Composition of the Gold Standard 82 6.3 Tumor Expression Data 82 6.3.1 Tumor Content 82 6.4 Benchmark Reference Study 83 6.4.1 Methodology 83 6.4.2 Reproduction 84 6.4.3 Reference Hazard Model 85 7 Bayesian Models in Example Applications 87 7.1 Inference of Cell Composition 87 7.1.1 The Expression Pattern Distributions (EPDs) 88 7.1.2 The Complete Model 89 7.1.3 Start Values 89 7.1.4 Resource Limits 90 7.2 Deconvolution of Expression Patterns 91 7.2.1 The Distribution of Expression Pattern Distribution 91 7.2.2 The Complete Model 92 7.2.3 SingleSampleDeconvolution 93 7.2.4 A Simplification 94 7.2.5 Start Values 94 8 Results of Example Applications 96 8.1 Inference of Cell Composition 96 8.1.1 Single Composition Output 96 8.1.2 ELBO Convergence in Variational Inference 97 8.1.3 Difficulty-Divergence 97 8.1.3.1 Implementing an Alternative Stick-Breaking 98 8.1.3.2 Using MoreGeneral Inference Methods 99 8.1.3.3 UsingBetterData 100 8.1.3.4 Restriction of Variance of Cell-Type-Specific EPDs 100 8.1.3.5 Doing Fewer Iterations 100 8.1.4 Difficulty-Bias 101 8.1.5 Comparison to Gold Standard 101 8.1.6 Comparison to Competitors 101 8.1.6.1 Submission-Aginome-XMU 105 8.1.6.2 Submission-Biogem 105 8.1.6.3 Submission-DA505 105 8.1.6.4 Submission-AboensisIV 105 8.1.6.5 Submission-mittenTDC19 106 8.1.6.6 Submission-CancerDecon 106 8.1.6.7 Submission-CCB 106 8.1.6.8 Submission-D3Team 106 8.1.6.9 Submission-ICTD 106 8.1.6.10 Submission-Patrick 107 8.1.6.11 Conclusion for the Competitor Review 107 8.1.7 Implementation 107 8.1.8 Conclusion 108 8.2 Deconvolution of Expression Patterns 108 8.2.1 Difficulty-Multimodality 109 8.2.1.1 Order of Kernels 109 8.2.1.2 Posterior EPD Complexity 110 8.2.1.3 Tumor Cell Content Estimate 110 8.2.2 Difficulty-Time 110 8.2.3 The Inference Process 111 8.2.3.1 ELBO Convergence in Variational Inference 111 8.2.4 Posterior of Tumor Cell Content 112 8.2.5 Posterior of Tissue Specific Expression 112 8.2.6 PosteriorHazardModel 113 8.2.7 Gene Marker Study with Deconvoluted Tumor Expression 115 8.2.8 Hazard Model Comparison Overview 116 8.2.9 Implementation 116 9 Discussion 117 9.1 Limitations 117 9.1.1 Simplifying Assumptions 117 9.1.2 Computation Resources 118 9.1.3 Limited Data and Suboptimal Format 118 9.1.4 ItIsJustConsistency 119 9.1.5 ADVI Uncertainty Estimation 119 9.2 Outlook 119 9.3 Conclusion 121 A Appendix 123 A.1 Optimalα 123 A.2 Digamma Function and Logarithm 123 A.3 Common Normalization 124 A.3.1 CPMNormalization 124 A.3.2 TPMNormalization 124 A.3.3 VSTNormalization 125 A.3.4 PCA After Different Normalizations 125 A.4 Mixture Prior Per Tissue Source 125 A.5 Data 125 A.6 Cell Type Characterization without Whitening 133 B Proofs 137 Bibliography 140
3

Multi-parameter Fluorescent Analysis of Magnetically Enriched Circulating Tumor Cells

Wu, Yongqi January 2014 (has links)
No description available.
4

Development and Characterisation of Cathode Materials for the Molten Carbonate Fuel Cell

Wijayasinghe, Athula January 2004 (has links)
Among the obstacles for the commercialization of the MoltenCarbonate Fuel Cell (MCFC), the dissolution of thestate-of-the-art lithiated NiO cathode is considered as aprimary lifetime limiting constraint. Development ofalternative cathode materials is considered as a main strategyfor solving the cathode dissolution problem. LiFeO2and LiCoO2had earlier been reported as the most promisingalternative materials; however, they could not satisfactorilysubstitute the lithiated NiO. On the other hand, ternarycompositions of LiFeO2, LiCoO2and NiO are expected to combine some desirableproperties of each component. The aim of this work was todevelop alternative cathode materials for MCFC in the LiFeO2-LiCoO2-NiO ternary system. It was carried out byinvestigating electronic conductivity of the materials, firstin the form of bulk pellets and then in ex-situ sinteredporous-gas-diffusion cathodes, and evaluating theirelectrochemical performance by short-time laboratory-scale celloperations. Materials in the LiFeO2-NiO binary system and five ternary sub-systems,each with a constant molar ratio of LiFeO2:NiO while varying LiCoO2content, were studied. Powders withcharacteristics appropriate for MCFC cathode fabrication couldbe obtained by the Pechini method. The particle size of LiFeO2-LiCoO2-NiO powders considerably depends on thecalcination temperature and the material composition. Theelectrical conductivity study reveals the ability of preparingLiFeO2-LiCoO2-NiO materials with adequate electricalconductivity for MCFC cathode application. A bimodal pore structure, appropriate for the MCFC cathode,could be achieved in sintered cathodes prepared usingporeformers and sub-micron size powder. Further, this studyindicates the nature of the compromise to be made between theelectrical conductivity, phase purity, pore structure andporosity in optimization of cathodes for MCFC application. Cellperformance comparable to that expected for the cathode in acommercial MCFC could be achieved with cathodes prepared from20 mole% LiFeO2- 20 mole% LiCoO2- 60 mole% NiO ternary composition. It shows aniR-corrected polarization of 62 mV and a iR-drop of 46 mV at acurrent density of 160 mAcm-2at 650 °C. Altogether, this study revealsthe possibility of preparing LiFeO2-LiCoO2-NiO cathode materials suitable for MCFCapplication. Keywords: molten carbonate fuel cell (MCFC), MCFC cathode,LiFeO2-LiCoO2-NiO ternary compositions, electrical conductivity,porous gas diffusion electrodes, polarization, electrochemicalperformance, post-cell characterization.
5

Development and Characterisation of Cathode Materials for the Molten Carbonate Fuel Cell

Wijayasinghe, Athula January 2004 (has links)
<p>Among the obstacles for the commercialization of the MoltenCarbonate Fuel Cell (MCFC), the dissolution of thestate-of-the-art lithiated NiO cathode is considered as aprimary lifetime limiting constraint. Development ofalternative cathode materials is considered as a main strategyfor solving the cathode dissolution problem. LiFeO<sub>2</sub>and LiCoO<sub>2</sub>had earlier been reported as the most promisingalternative materials; however, they could not satisfactorilysubstitute the lithiated NiO. On the other hand, ternarycompositions of LiFeO<sub>2</sub>, LiCoO<sub>2</sub>and NiO are expected to combine some desirableproperties of each component. The aim of this work was todevelop alternative cathode materials for MCFC in the LiFeO<sub>2</sub>-LiCoO<sub>2</sub>-NiO ternary system. It was carried out byinvestigating electronic conductivity of the materials, firstin the form of bulk pellets and then in ex-situ sinteredporous-gas-diffusion cathodes, and evaluating theirelectrochemical performance by short-time laboratory-scale celloperations.</p><p>Materials in the LiFeO<sub>2</sub>-NiO binary system and five ternary sub-systems,each with a constant molar ratio of LiFeO<sub>2</sub>:NiO while varying LiCoO<sub>2</sub>content, were studied. Powders withcharacteristics appropriate for MCFC cathode fabrication couldbe obtained by the Pechini method. The particle size of LiFeO<sub>2</sub>-LiCoO<sub>2</sub>-NiO powders considerably depends on thecalcination temperature and the material composition. Theelectrical conductivity study reveals the ability of preparingLiFeO<sub>2</sub>-LiCoO<sub>2</sub>-NiO materials with adequate electricalconductivity for MCFC cathode application.</p><p>A bimodal pore structure, appropriate for the MCFC cathode,could be achieved in sintered cathodes prepared usingporeformers and sub-micron size powder. Further, this studyindicates the nature of the compromise to be made between theelectrical conductivity, phase purity, pore structure andporosity in optimization of cathodes for MCFC application. Cellperformance comparable to that expected for the cathode in acommercial MCFC could be achieved with cathodes prepared from20 mole% LiFeO<sub>2</sub>- 20 mole% LiCoO<sub>2</sub>- 60 mole% NiO ternary composition. It shows aniR-corrected polarization of 62 mV and a iR-drop of 46 mV at acurrent density of 160 mAcm<sup>-2</sup>at 650 °C. Altogether, this study revealsthe possibility of preparing LiFeO<sub>2</sub>-LiCoO<sub>2</sub>-NiO cathode materials suitable for MCFCapplication.</p><p>Keywords: molten carbonate fuel cell (MCFC), MCFC cathode,LiFeO<sub>2</sub>-LiCoO<sub>2</sub>-NiO ternary compositions, electrical conductivity,porous gas diffusion electrodes, polarization, electrochemicalperformance, post-cell characterization.</p>
6

Studies On Fabrication And Characterisation Of TiO2 Based Dye-Sensitised Solar Cells

Sharmila, S January 2015 (has links) (PDF)
Photovoltaic cells are a promising solution to the current energy crisis. Among the different photovoltaic cell technologies developed, dye-sensitised solar cells (DSSC) are emerging as viable low-cost alternatives to Si PV technology. This thesis presents studies on fabrication and characterisation of TiO2 based dye-sensitised solar cells. Chapter 1 gives an overview of different photovoltaic cell technologies and a review of the state-of-the art DSSC technology. Chapter 2 describes the techniques used for characterisation of DSSCs. Chapter 3 describes the fabrication of TiO2 based dye-sensitised solar cells. Chapter 4 presents the analysis of measurements obtained by the characterisation techniques. Finally chapter 5 summarises the work done and suggests directions for future work.

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