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Umfang: 1 online resource (572 pages)

Ausgabe: 1st ed.

ISBN: 9789811270611

Weitere Ausg.: Print version: Altman, Russ B Biocomputing 2023 - Proceedings Of The Pacific Symposium Singapore : World Scientific Publishing Company,c2022 ISBN 9789811270604

Sprache: Englisch

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Umfang: 1 online resource (517 pages)

ISBN: 9789814644730

Anmerkung: Intro -- 2PSB20AnniversaryFinalv2 -- all-cp -- 0intro-cancerpanomics -- ching -- deshwar -- jang -- lehman -- nasser -- wu -- all-cp -- 0intro-cancerpathways -- engin -- kim -- 1. Introduction -- 2. Methods -- 2.1. Data -- 2.2. BioBin -- 2.3. ATHENA -- 2.4. Grammatical Evolution Neural Networks (GENN) -- 2.5. Survival fitness function -- 2.6. Experiment setup -- 3. Results and Discussion -- 3.1. Binning somatic mutations using BioBin -- 3.2. GENN modeling for somatic mutation burden -- 3.3. Biological interpretation -- 4. Conclusions -- Acknowledgments -- lockwood -- poon -- tan -- yang -- all-interactions -- 1intro-interactions -- crawford -- darabos -- frost -- holzinger -- Holzinger_PSB2015_r2VIM_1Oct2014 -- 1.   Introduction -- 1.1.   Variable selection that allows for interactions -- 2.   Methods -- 2.1.   r2VIM -- 2.2.   Data Simulation -- 3.   Results -- 3.1.   Simulated Data -- 4.   Discussion -- hu -- jeff -- patel -- restrepo -- wang -- all-crowd -- 1intro-crowdsourcing -- binder -- good -- irshad -- odgers -- waldispuhl -- all-pm -- 0intro-pm -- birol -- chang -- diggans -- fan-minogue -- glicksberg -- hinterberg -- huang -- makashir -- 2. Methods -- 2.1. Statistical framework for meta-analysis of differential co-expression -- 2.1.1. s score definition -- 2.1.2. Probability distribution of s scores -- 2.2. SLE dataset selection for meta-analysis -- 2.3. Data pre-processing -- 2.4. Meta-analysis of differential gene co-expression in SLE -- 2.5. Comparison of Type I error rates and statistical power -- 2.6. Differential expression analysis -- 2.7. Identification and annotation of gene modules -- 3. Results -- 3.1. A network of genes specifically co-expressed in SLE -- 3.2. Gene co-expression modules specific to SLE -- 3.2.1. Type I interferon response. , 3.2.2. Cell movement and response to wounding -- 3.2.3. Immune defense against extracellular organisms -- 4. Discussion -- 5. Conclusions -- nie -- sengupta -- all-wkshop -- 1wkshop-human -- 2wkshop-discovery -- 3wkshp-public -- 4wkshop-bioinfo -- 5psb15-erratum.

Weitere Ausg.: Print version: Altman, Russ B Pacific Symposium On Biocomputing 2015 Singapore : World Scientific Publishing Company,c2014 ISBN 9789814644723

Sprache: Englisch

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Umfang: 1 online resource (762 pages)

ISBN: 9789811215636

Anmerkung: Intro -- Content -- Preface -- ARTIFICIAL INTELLIGENCE FOR ENHANCING CLINICAL MEDICINE -- Session Introduction: Artificial Intelligence for Enhancing Clinical Medicine -- 1. Introduction -- 2. Novel Research Applying Artificial Intelligence to Clinical Medicine -- 2.1. Artificial intelligence for predicting patient outcomes -- 2.2. Artificial intelligence for improved insight into disease pathogenesis and features -- 3. Artificial intelligence for advancing medical workflows -- 4. Artificial intelligence for improving imaging -- 5. Conclusion -- References -- Predicting Longitudinal Outcomes of Alzheimer's Disease via a Tensor-Based Joint Classification and Regression Model -- 1. Introduction -- 2. Methods -- 2.1. The Longitudinal Joint Learning Model -- 2.2. The Solution Algorithm Using the Multi-Block ADMM -- 3. Experiments -- 3.1. Performance -- 3.2. Empirical Convergence -- 3.3. Biomarker Identification -- 4. Conclusion -- Acknowledgements -- References -- Robustly Extracting Medical Knowledge from EHRs: A Case Study of Learning a Health Knowledge Graph -- 1. Introduction -- 2. Related Work -- 3. Methods -- 3.1. Data collection and preparation -- 3.2. Evaluation with GHKG -- 3.3. Disease predictability analysis -- 3.4. Demographic analysis -- 3.5. Non-linear methods -- 4. Results -- 5. Discussion -- 5.1. Data size does not always matter. -- 5.2. Confounders may explain errors -- 5.3. Increased model complexity does not necessarily help -- 5.4. Limitations remain as an opportunity for future work -- 6. Conclusion -- Acknowledgements -- References -- Increasing Clinical Trial Accrual via Automated Matching of Biomarker Criteria -- 1. INTRODUCTION -- 2. MATERIALS AND METHODS -- 2.1. Specimens and Retrospective Analysis -- 2.2. Real-time Analysis -- 2.3. Source of Biomarker-based Clinical Trial Data -- 3. RESULTS. , 3.1. STAMP assay identifies somatic mutations -- 3.2. Algorithmic pipeline flags eligible patients for precision medicine clinical trials -- 3.2.1. Automation of Feature Matching -- 3.2.2. Manual Review of Matching Output -- 3.3. Validation of algorithmic pipeline -- 3.4. Match rate analysis of STAMP-identified mutations -- 4. DISCUSSION -- 4.1. Incorporation of informatics into clinical workflows -- 4.2. Limitations of algorithmic pipelines -- 5. CONCLUSION -- 6. AUTHOR CONTRIBUTIONS -- 7. ACKNOWLEDGEMENTS -- 8. REFERENCES -- 9. FIGURES -- 10. SUPPLEMENTARY TABLES AND FIGURES -- Addressing the Credit Assignment Problem in Treatment Outcome Prediction Using Temporal Difference Learning -- 1. Introduction -- 2. Dataset -- 3. Methods -- 3.1. Feature Extraction -- 3.2. Temporal Difference Learning -- 3.2.1. State-Estimation -- 3.2.2. Value Iteration -- 3.2.3. Optimization -- 3.3. Baselines and Performance Measure -- 4. Results -- 5. Discussion and Conclusion -- References -- Multiclass Disease Classification from Microbial Whole-Community Metagenomes -- 1. Introduction -- 2. Previous Work -- 3. Problem Setup -- 3.1. Dataset Construction -- 3.2. Graph Convolutional Neural Networks -- 3.3. Models -- 3.4. Training -- 4. Results -- 5. Conclusion -- 6. Acknowledgments -- 7. External Links -- References -- LitGen: Genetic Literature Recommendation Guided by Human Explanations -- 1. Introduction -- 2. Clinical Variant Curation Data -- 2.1. ClinGen's Variant Curation Interface (VCI) -- 2.2. Labeled papers -- 2.3. Unlabeled papers -- 3. Method -- 3.1. BiLSTM baseline -- 3.2. Leveraging unlabeled data -- 3.3. Explanations in multitask learning -- 3.4. Explanations as feature selection for proxy labeling -- 4. Experimental results -- 4.1. Evaluation metrics -- 4.2. Performance comparison -- 4.3. Performance of Proxy Labeling Model. , 4.4. Performance by Evidence Types -- 5. Discussion -- References -- From Genome to Phenome: Predicting Multiple Cancer Phenotypes Based on Somatic Genomic Alterations via the Genomic Impact Transformer -- 1. Introduction -- 2. Materials and methods -- 2.1. SGAs and DEGs pre-processing -- 2.2. The GIT neural network -- 2.2.1. GIT network structure: encoder-decoder architecture -- 2.2.2. Pre-training gene embeddings using Gene2Vec algorithm -- 2.2.3. Encoder: multi-head self-attention mechanism -- 2.2.4. Decoder: multi-layer perceptron (MLP) -- 2.3. Training and evaluation -- 3. Results -- 3.1. GIT statistically detects real biological signals -- 3.2. Gene embeddings compactly represent the functional impact of SGAs -- 3.4. Personalized tumor embeddings reveal distinct survival profiles -- 3.5. Tumor embeddings are predictive of drug responses of cancer cell lines -- 4. Conclusion and Future Work -- Acknowledgments -- Funding -- References -- Automated Phenotyping of Patients with Non-Alcoholic Fatty Liver Disease Reveals Clinically Relevant Disease Subtypes -- 1. Introduction -- 2. Methods -- 2.1. NAFLD definition -- 2.2. Natural language processing -- 2.3. Data collection -- 2.4. Clinical feature standardization and quality control -- 2.4.1. Demographic data -- 2.4.2. Diagnoses, procedures, medications -- 2.4.3. Laboratory tests -- 2.4.4. Vital signs -- 2.5. Patient pairwise distance and clustering -- 2.6. Statistical analysis -- 2.6.1. Descriptive statistics -- 2.6.2. Survival analysis -- 3. Results -- 3.1. Descriptive statistics for the cohort -- 3.2. Identification of NAFLD subtypes -- 3.3. Identification of distinct outcomes by NAFLD subtype -- 3.4. Internal cross-validation of the subtypes discovered -- 4. Conclusion -- 5. References -- References -- Monitoring ICU Mortality Risk with a Long Short-Term Memory Recurrent Neural Network. , 1. Introduction -- 2. Background and Related Work -- 3. Data and Preprocessing -- 3.1. Data Source and Cohort Selection -- 3.2. Data Extraction and Preprocessing -- 4. Methodology -- 4.1. Mortality Monitoring Task -- 4.2. Average Pooling and Attention Mechanism -- 4.3. Recurrent Neural Network (RNN) -- 5. Experimental Design -- 5.1. Sampling Strategy -- 5.2. Baseline Model -- 5.3. Experimental Settings -- 6. Results and Analysis -- 6.1. Dimensionality Analysis -- 6.2. Prediction with Different Feature Representations -- 6.3. Interpreting Mortality of Learned Representation -- 7. Discussion and Conclusions -- References -- Multilevel Self-Attention Model and Its Use on Medical Risk Prediction -- 1. Introduction -- 2. Related Work -- 2.1. Future disease prediction -- 3. Methods -- 3.1. Terminology and Notation -- 3.2. Model Architecture -- 3.3. Self-attention Encoder Unit -- 3.4. Loss Function -- 4. Experiments -- 4.1. Source of Data -- 4.2. Dataset preprocessing -- 4.3. Implementation details -- 5. Results -- 5.1. Future disease prediction -- 5.2. Future cost prediction -- 5.3. Case study for the self-attention mechanism -- 6. Conclusion -- 7. Bibliography -- Identifying Transitional High Cost Users from Unstructured Patient Profiles Written by Primary Care Physicians -- 1. Introduction -- 2. Data -- 2.1. EMRPC -- 2.2. Total Healthcare Costs -- 2.3. Encoding of Ordinal Variables -- 2.4. Word Embeddings -- 3. Methods -- 3.1. Bag of Words -- 3.2. EmbEncode -- 3.3. Historical Baseline -- 3.4. Varying the Training Set -- 3.5. Varying the Evaluation Set -- 4. Results -- 5. Discussion -- Acknowledgments -- References -- Obtaining Dual-Energy Computed Tomography (CT) Information from a Single-Energy CT Image for Quantitative Imaging Analysis of Living Subjects by Using Deep Learning -- 1. Introduction -- 2. Methods -- 3. Results. , 4. Discussion and Conclusion -- 5. Acknowledge -- References -- INTRINSICALLY DISORDERED PROTEINS (IDPS) AND THEIR FUNCTIONS -- Session Introduction: On the Importance of Computational Biology and Bioinformatics to the Origins and Rapid Progression of the Intrinsically Disordered Proteins Field -- 1. Introduction -- 2. Computational prediction of IDPs and IDRs and their functions -- 3. Popularization of research on IDPs and IDRs -- 4. A Collection of Recent Papers on IDPs and IDRs -- References -- Many-to-One Binding by Intrinsically Disordered Protein Regions -- 1. Introduction -- 2. Results -- 2.1. Many-to-one binding datasets -- 2.2. Many-to-one binding profiles: independent and overlapping -- 2.3 Comparing VOR (with backbone only) and RMSΔASA Values -- 2.4. Selected many-to-one case studies -- 3. Discussion -- 4. Materials and Methods -- 4.1. Dataset preparation -- 4.2. MoRF sequence similarity -- 4.3. MoRF interface similarity -- References -- Disordered Function Conjunction: On the In-Silico Function Annotation of Intrinsically Disordered Regions -- 1. Introduction -- 2. Materials and Methods -- 2.1. Data collection -- 2.2. Computational workflow -- 2.2.1. Feature-based representation of protein regions -- 2.2.2. Prediction of protein region functions -- 2.2.3. Assessment of the function prediction and clustering -- 3. Results and Discussion -- 3.1. Prediction of individual functions of IDRs -- 3.2. IDRs described in multidimensional space form function-related clusters -- 3.3. Case studies -- 4. Conclusions -- Acknowledgments -- References -- De novo Ensemble Modeling Suggests that AP2-Binding to Disordered Regions Can Increase Steric Volume of Epsin but Not Eps15 -- 1. Introduction -- 2. Methods -- 2.1. Generation of structural ensembles -- 2.2. Filtering Epsin conformers to mimic the effect of Plasma membrane. , 2.3. Docking AP2α to the IDRs by superposition.

Weitere Ausg.: Print version: Altman, Russ B Biocomputing 2020 - Proceedings Of The Pacific Symposium Singapore : World Scientific Publishing Company,c2019 ISBN 9789811215629

Sprache: Englisch

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URL: https://www.worldscientific.com/worldscibooks/10.1142/11698#t=toc

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Umfang: 1 online resource (436 pages)

ISBN: 9789814583220

Anmerkung: Intro -- 0psb-preface-14-rba.pdf -- 1cp-all -- 0cp-intro-rev.pdf -- aguiar-rev -- badea -- 1.   Introduction and motivation -- 2.   Data and preprocessing -- 2.1.   The TCGA AML dataset -- 2.2.   Generalized mutations -- 2.3.   Protein-to-protein interaction data -- 3.   Proteins mutated in AML form pp interaction cliques -- 4.   Joint analysis of gene expression data and mutations using pp interaction data -- 4.1.   The joint clustering of expression and mutation interactor data -- 4.2.   The dimensionality of the factorization -- 4.3.   Significant sample-specific mutations -- 5.   Conclusions -- 6.   Acknowledgments -- chaibubneto (1) -- gitter-rev -- hu -- mayba -- min-rev -- morgan -- 2cad-all -- 0intro-cdr-rev -- blucher -- brubaker -- ng -- yang -- yera-rev -- zhu -- 3pleiotropy-all -- 0Pleiotropy_Proceedings_Introduction.pdf -- darabos-rev -- hall -- philip -- 4pm-all -- 0pm-intro-rev -- daneshjou -- martin -- parikh -- patwardhan-rev -- 1. Introduction -- 2. Methods -- 2.1. Subject Samples -- 2.2. Genomic Library Construction, Exome Sequencing, Alignment and Variant Calling -- 2.3. Problematic Regions of the Genome -- 2.4. Case Control Analysis -- 3. Results -- 4. Discussion -- 5text-all -- 0intro-text -- clark -- funk -- han -- komandurelayavilli -- liu (1) -- malinowski (2) -- vembu-rev -- zitnik (1) -- 1NoncodingRNA_workshop_PSB2014.pdf -- 2training -- Untitled.

Weitere Ausg.: Print version: Altman, Russ B Pacific Symposium On Biocomputing 2014 Singapore : World Scientific Publishing Company,c2013 ISBN 9789814596343

Sprache: Englisch

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Umfang: 1 online resource (667 pages)

Ausgabe: 1st ed.

ISBN: 9789813207813

Weitere Ausg.: Print version Altman, Russ B Biocomputing 2017 - Proceedings Of The Pacific Symposium Singapore : World Scientific Publishing Company,c2016 ISBN 9789813207806

Sprache: Englisch

Schlagwort(e): Electronic books

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Umfang: 1 online resource (667 pages)

Ausgabe: 1st ed.

ISBN: 9789813207813

Weitere Ausg.: Print version Altman, Russ B Biocomputing 2017 - Proceedings Of The Pacific Symposium Singapore : World Scientific Publishing Company,c2016 ISBN 9789813207806

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Umfang: 1 online resource (471 p.)

ISBN: 9789813279827 , 9813279826

Anmerkung: Description based upon print version of record.

Weitere Ausg.: Print version: Altman, Russ B Biocomputing 2019 - Proceedings Of The Pacific Symposium Singapore : World Scientific Publishing Company,c2018 9789813279810

Sprache: Englisch

Schlagwort(e): Electronic books.

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UID:

Umfang: 1 online resource (471 pages)

Ausgabe: 1st ed.

ISBN: 9789813279827

Anmerkung: Intro -- Preface -- PATTERN RECOGNITION IN BIOMEDICAL DATA: CHALLENGES IN PUTTING BIG DATA TO WORK -- Session introduction -- Introduction -- References -- Learning Contextual Hierarchical Structure of Medical Concepts with Poincairé Embeddings to Clarify Phenotypes -- 1. Introduction -- 2. Methods -- 2.1. Source Code -- 2.2. Data Source -- 2.3. Data Selection and Preprocessing -- 2.3.1. Reference ICD9 Example -- 2.3.2. Real Member Analyses -- 2.4. Poincaré Embeddings -- 2.5. Processing and Evaluating Embeddings -- 3. Results -- 3.1. ICD9 Hierarchy Evaluation -- 3.2. Poincaré Embeddings on 10 Million Members -- 3.3. Comparison with Euclidean Embeddings -- 3.4. Cohort Specific Embeddings -- 4. Discussion and Conclusion -- 5. Acknowledgments -- References -- The Effectiveness of Multitask Learning for Phenotyping with Electronic Health Records Data -- 1. Introduction -- 2. Background -- 2.1. Multitask nets -- 3. Methods -- 3.1. Dataset Construction and Design -- 3.2. Experimental Design -- 4. Experiments and Results -- 4.1. When Does Multitask Learning Improve Performance? -- 4.2. Relationship Between Performance and Number of Tasks -- 4.3. Comparison with Logistic Regression Baseline -- 4.4. Interaction between Phenotype Prevalence and Complexity -- 5. Limitations -- 6. Conclusion -- Acknowledgments -- References -- ODAL: A one-shot distributed algorithm to perform logistic regressions on electronic health records data from multiple clinical sites -- 1. Introduction -- 1.1. Integrate evidence from multiple clinical sites -- 1.2. Distributed Computing -- 2. Material and Method -- 2.1. Clinical Cohort and Motivating Problem -- 2.2. Algorithm -- 2.3. Simulation Design -- 3. Results -- 3.1. Simulation Results -- 3.2. Fetal Loss Prediction via ODAL -- 4. Discussion -- References , PVC Detection Using a Convolutional Autoencoder and Random Forest Classifier -- 1. Introduction -- 2. Methods -- 2.1. Data Set and Implementation -- 2.2. Proposed PVC Detection Method -- 2.2.1. Feature Extraction -- 2.2.2. Classification -- 3. Results -- 3.1. Full Database Evaluation -- 3.2. Timing Disturbance Evaluation -- 3.3. Cross-Patient Training Evaluation -- 3.4. Estimated Parameters and Convergence -- 4. Discussion -- References -- Removing Confounding Factors Associated Weights in Deep Neural Networks Improves the Prediction Accuracy for Healthcare Applications -- 1. Introduction -- 2. Related Work -- 3. Confounder Filtering (CF) Method -- 3.1. Overview -- 3.2. Method -- 3.3. Availability -- 4. Experiments -- 4.1. lung adenocarcinoma prediction -- 4.1.1. Data -- 4.1.2. Results -- 4.2. Segmentation on right ventricle(RV) of Heart -- 4.2.1. Data -- 4.2.2. Results -- 4.3. Students' confusion status prediction -- 4.3.1. Data -- 4.3.2. Results -- 4.4. Brain tumor prediction -- 4.4.1. Data -- 4.4.2. Results -- 4.5. Analyses of the method behaviors -- 5. Conclusion -- 6. Acknowledgement -- References -- DeepDom: Predicting protein domain boundary from sequence alone using stacked bidirectional LSTM -- 1. Introduction -- 2. METHODS -- 2.1 Data Set Preparation -- 2.2 Input Encoding -- 2.3 Model Architecture -- 2.4 Evaluation criteria -- 3. RESULTS AND DISCUSSION -- 3.1 Parameter configuration experiments on test data -- 3.2 Comparison with Other Domain Boundary Predictors -- 3.2.1 Free modeling targets from CASP 9 -- 3.2.2 Multi-domain targets from CASP 9 -- 3.2.3 Discontinuous domain target from CASP 8 -- 4. CONCLUSION -- 5. ACKNOWLEDGEMENTS -- REFERENCES -- Res2s2aM: Deep residual network-based model for identifying functional noncoding SNPs in trait-associated regions -- 1. Introduction -- 2. Background theory , 3. Dataset for training and testing -- 3.1. Source databases -- 3.2. Dataset generation -- 4. Methods -- 4.1. ResNet architecture in our model -- 4.2. Tandem inputs of forward- and reverse-strand sequences -- 4.3. Biallelic high-level network structure -- 4.4. Incorporating HaploReg SNP annotation features -- 4.5. Training of models -- 5. Results -- 6. Conclusions and discussion -- Acknowledgements -- References -- DNA Steganalysis Using Deep Recurrent Neural Networks -- 1. Introduction -- 2. Background -- 2.1. Notations -- 2.2. Hiding Messages -- 2.3. Determination of Message-Hiding Regions -- 3. Methods -- 3.1. Proposed DNA Steganalysis Principle -- 3.2. Proposed Steganalysis RNN Model -- 4. Results -- 4.1. Dataset -- 4.2. Input Representation -- 4.3. Model Training -- 4.4. Evaluation Procedure -- 4.5. Performance Comparison -- 5. Discussion -- Acknowledgments -- References -- Bi-directional Recurrent Neural Network Models for Geographic Location Extraction in Biomedical Literature -- 1. Introduction -- 2. Related Work -- 3. Methods -- 3.1. Toponym Detection -- 3.1.1. Recurrent Neural Networks -- 3.1.2. LSTM -- 3.1.3. Other Gated RNN Architectures -- 3.1.4. Hyperparameter search and optimization -- 3.2. Toponym Disambiguation -- 3.2.1. Building Geonames Index -- 3.2.2. Searching Geonames Index -- 4. Results and Discussion -- 4.1. Toponym Disambiguation -- 4.2. Toponym Resolution -- 5. Limitations and Future Work -- 6. Conclusion -- Acknowledgments -- Funding -- References -- Automatic Human-like Mining and Constructing Reliable Genetic Association Database with Deep Reinforcement Learning -- 1. Introduction -- 2. Related Work -- 3. Method -- 3.1. Model Framework -- 3.2. Deep Reinforcement Learning for Organizing Actions -- 3.3. Preprocessing and Name Entity Recognition with UMLS -- 3.4. Bidirectional LSTM for Relation Classification , 3.5. Algorithm -- 3.6. Implementation Specification -- 4. Experiments -- 4.1. Data -- 4.2. Evaluation -- 4.3. Results -- 4.3.1. Improved Reliability -- 4.3.2. Robustness in Real-world Situations -- 4.3.3. Number of Articles Read -- 5. Conclusions and Future Work -- 6. Acknowledgement -- References -- Estimating classification accuracy in positive-unlabeled learning: characterization and correction strategies -- 1. Introduction -- 2. Methods -- 2.1. Performance measures: definitions and estimation -- 2.2. Positive-unlabeled setting -- 2.3. Performance measure correction -- 3. Experiments and Results -- 3.1. A case study -- 3.2. Data sets -- 3.3. Experimental protocols -- 3.4. Results -- 4. Conclusions -- Acknowledgements -- References -- PLATYPUS: A Multiple-View Learning Predictive Framework for Cancer Drug Sensitivity Prediction -- 1. Introduction -- 2. System and methods -- 2.1. Data -- 2.2. Single views and co-training -- 2.3. Maximizing agreement across views through label assignment -- 3. Results -- 3.1. Preliminary experiments to optimize PLATYPUS performance -- 3.2. Predicting drug sensitivity in cell lines -- 3.3. Key features from PLATYPUS models -- 4. Conclusions -- Acknowledgments -- References -- Computational KIR copy number discovery reveals interaction between inhibitory receptor burden and survival -- 1. Introduction -- 2. Materials and Methods -- 2.1 Data collection -- 2.2 K-mer selection -- 2.3 NGS pipeline and k-mer extraction -- 2.4 Data cleaning -- 2.5 Normalization of k-mer frequencies -- 2.6 Copy number segregation and cutoff selection -- 2.7 Validation of copy number -- 2.8 Survival analysis -- 2.9 Additional immune analysis -- 3. Results and Discussions -- 3.1 Establishing unique k-mers -- 3.2 Varying coverage of KIR region by exome capture kit -- 3.3 Inference of KIR copy number -- 3.4 Population variation of the KIR region , 3.5 KIR inhibitory gene burden correlates with survival in cervical and uterine cancer -- 5. Conclusions -- 6. Acknowledgements -- 7. Supplementary Material -- References -- Exploring microRNA Regulation of Cancer with Context-Aware Deep Cancer Classifier -- 1. Introduction -- 2. Data -- 2.1. Preprocessing -- 3. Deep Cancer Classifier -- 3.1. Training andamp -- testing -- 3.2. Parameter tuning -- 3.3. Feature importance -- 4. Results and Discussion -- 4.1. Model selection -- 4.2. Classifier performance -- 4.3. Comparison with other methods -- 4.4. Feature importance -- 5. Conclusion -- References -- Implementing and Evaluating A Gaussian Mixture Framework for Identifying Gene Function from TnSeq Data -- 1. Introduction -- 1.1. TnSeq Motivation and Background -- 1.2. Motivation and New Methods -- 2. Methods -- 2.1. TnSeq Experimental Data -- 2.2. Mixture framework -- 2.3. Classification methods -- 2.3.1. Novel method - EM -- 2.3.2. Current method - t-statistic -- 2.3.3. Bayesian hierarchical model -- 2.3.4. Data partitioning for the Bayesian model -- 2.4. Simulation -- 2.5. Real data -- 3. Results -- 3.1.1. Classification rate -- 3.1.2. False positive rate -- 3.1.3. Positive classification rate -- 3.1.4. Cross entropy -- 3.2. Simulation Results -- 3.3. Comparisons on real data -- 3.4. Software -- 4. Discussion -- References -- SNPs2ChIP: Latent Factors of ChIP-seq to infer functions of non-coding SNPs -- 1. Introduction -- 2. Results -- 2.1. SNPs2ChIP analysis framework overview -- 2.2. Batch normalization of heterogeneous epigenetic features -- 2.3. Latent factor discovery and their biological characterization -- 2.4. SNPs2ChIP identifies relevant functions of the non-coding genome -- 2.4.1. Genome-wide SNPs coverage of the reference datasets -- 2.4.2. Non-coding GWAS SNPs of systemic lupus erythematosus -- 2.4.3. ChIP-seq peaks for vitamin D receptors , 2.5. Robustness Analysis in the latent factor identification

Weitere Ausg.: Print version Altman, Russ B Biocomputing 2019 - Proceedings Of The Pacific Symposium Singapore : World Scientific Publishing Company,c2018 ISBN 9789813279810

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Umfang: 1 online resource (649 pages)

Ausgabe: 1st ed.

ISBN: 9789813235533

Anmerkung: Intro -- Preface -- APPLICATIONS OF GENETICS, GENOMICS AND BIOINFORMATICS IN DRUG DISCOVERY -- Session introduction -- 1. Introduction -- 2. Session Contributions -- 2.1. Drug mechanisms of action and drug combinations -- 2.2. Drug metabolism and in silico drug screening -- 2.3. Disease genes and pathways -- 3. Acknowledgments -- References -- Characterization of drug-induced splicing complexity in prostate cancer cell line using long read technology -- Introduction -- Results -- Discussion -- Methods -- Supplementary -- Acknowledgements -- References -- Prediction of protein-ligand interactions from paired protein sequence motifs and ligand substructures -- 1. Introduction -- 1.1. Decreasing returns in drug discovery pipelines -- 1.2. Existing methods for prediction of protein-ligand interactions -- 2. Methods -- 2.1. Data set -- 2.2. Protein Featurization -- 2.3. Ligand Featurization -- 2.4. Boosting Model -- 2.5. Cross Validation Approaches -- 3. Results -- 3.1. Model Performance -- 3.2. Most predictive motif features -- 3.3. Known positive examples -- 3.3.1. Uricase - Uric acid -- 3.3.2. Chloramphenicol O-acetyltransferase - Chloramphenicol -- 3.3.3. Transthyretin -T4 -- 3.4. Interpreting ADT Paths -- 3.4.1. Path lengths -- 3.4.2. Protein kinase C - Phosphatidylserine -- 4. Discussion -- Acknowledgments -- References -- Cell-specific prediction and application of drug-induced gene expression profiles -- 1. Introduction -- 2. Methods -- 2.1. Notation and terminology -- 2.2. Data processing -- 2.3. The Drug Neighbor Profile Prediction algorithm -- 2.4. The Fast, Low-Rank Tensor Completion algorithm -- 2.5. Baseline averaging schemes -- 2.6. Cross-validation for predicting gene expression profiles -- 2.7. Predicting drug targets and ATC codes -- 3. Results -- 3.1. Overall accuracy -- 3.2. Tradeoffs in accuracy across drug-cell space , 2. Case Study: RFEX Applied to Stanford FEATURE data , 3.2 LOF variants in putative plasticity genes confer risk for neurodevelopmental and nervous system related disorders -- 4. Discussion -- 5. Conclusions and Future Directions -- 6. Acknowledgments -- References -- Extracting a biologically relevant latent space from cancer transcriptomes with variational autoencoders -- 1. Introduction -- 2. Methods -- 2.1. Model Summary -- 2.2. Model Implementation -- 2.3. Parameter Selection -- 2.4. Input Data -- 2.5. Interpretation of Gene Weights -- 2.6. The Latent Space of Ovarian Cancer Subtypes -- 2.7. Enabling Exploration through Visualization -- 3. Results -- 3.1. Tumors were encoded in a lower dimensional space -- 3.2. Features represent biological signal -- 3.3. Interpolating the lower dimensional manifold of HGSC subtypes -- 4. Conclusion -- 5. Reproducibility -- Acknowledgments -- References -- Diffusion mapping of drug targets on disease signaling network elements reveals drug combination strategies -- 1. Introduction -- 2. Methods -- 3. Results -- 4. Discussion -- References -- CHALLENGES OF PATTERN RECOGNITION IN BIOMEDICAL DATA -- Session introduction -- 1. Introduction -- 2. Session Contributions -- 2.1 Network-based approaches -- 2.2 Machine learning approaches -- 2.2 Application of methods to identify patterns in EHR data -- 2.3 Applications in transcriptome and next-generation sequencing data -- 3. References -- Large-scale analysis of disease pathways in the human interactome -- 1. Introduction -- 2. Background and related work -- 3. Data -- 4. Connectivity of disease proteins in the PPI network -- 4.1. Proximity of disease proteins in the PPI network -- 4.2. Connections between PPI network structure and disease protein discovery -- 5. Higher-order connectivity of disease proteins in the PPI network -- 6. Prediction of disease proteins using higher-order PPI network structure -- 7. Conclusion , 3.3. Effects of varying observation density -- 3.4. Accuracy of differentially expressed genes -- 3.5. Analysis of cell-specificity -- 3.6. Utility of completed data for downstream prediction of drug properties -- 4. Discussion -- Supplementary Information -- Funding -- References -- Large-scale integration of heterogeneous pharmacogenomic data for identifying drug mechanism of action -- 1. Introduction -- 2. Materials and Methods -- 2.1. Construction of heterogeneous drug-drug similarity networks -- 2.2. Integration of multi-omics data -- 2.3. Prediction of MoAs and drug targets -- 3. Results -- 3.1. Mania improves the quanti cation of drug-drug similarity -- 3.2. Mania achieves accurate prediction of drug MoAs and targets -- 3.3. Identification of functionally-enriched drug communities -- 3.4. Predictions of drugs for significantly mutated genes -- 4. Discussion -- References -- Chemical reaction vector embeddings: towards predicting drug metabolism in the human gut microbiome -- 1. Introduction -- 2. Methods -- 2.1. Data sources and processing -- 2.2. Constructing molecular vector space -- 2.3. Characterizing vector spaces -- 2.3.1. Molecule-level Analysis -- 2.3.2. Reaction-Level Analysis -- 2.4. Querying drug-metabolite pairs against reaction vectors -- 3. Results -- 3.1. Molecule-level analysis -- 3.2. Reaction-level analysis -- 3.3. Querying reaction vectors against drug-metabolite pairs -- 4. Discussion -- 5. Conclusion -- 6. Acknowledgments -- References -- Loss-of-function of neuroplasticity-related genes confers risk for human neurodevelopmental disorders -- 1. Introduction -- 2. Methods -- 2.1 Neuroplasticity signatures -- 2.2 Hospital and biobank cohort -- 2.3 Variant annotation -- 2.4 Neurodevelopmental disease phenotyping -- 2.5 LOF gene and disease association analysis -- 3. Results -- 3.1 Identifying putative neuroplasticity genes , 6. Supplementary Material -- References -- An ultra-fast and scalable quantification pipeline for transposable elements from next generation sequencing data -- 1. Introduction -- 2. Methods -- 2.1. Transposable Element Library Preparation -- 2.2. Salmon quanti cation algorithm -- 2.3. Statistical tests -- 3. Results -- 3.1. Datasets -- 3.2. Computational experiment setup -- 3.3. SalmonTE guarantees a reliable TE expression estimation -- 3.4. SalmonTE shows a better scalability in the speed benchmark dataset -- 3.5. Discover differentially expressed TEs in ALS cell line -- 4. Conclusion -- Acknowledgments -- References -- Causal inference on electronic health records to assess blood pressure treatment targets: An application of the parametric g formula -- 1. Introduction -- 1.1. Global Burden of Hypertension -- 1.2. Challenges in Previous Efforts to Discover Optimal Target Blood Pressures -- 1.3. Causal Inference from Electronic Health Records As a Tool to Answer Difficult Clinical Questions -- 2. Methods -- 2.1. Data Acquisition from the Mount Sinai Hospital EHR -- 2.2. Problem setup -- 2.3. Parametric g formula -- 3. Results -- 3.1. Electronic Health Records Data -- 3.2. Survival time by goal blood pressure target -- 4. Conclusion -- References -- Data-driven advice for applying machine learning to bioinformatics problems -- 1. Introduction -- 2. Methods -- 3. Results -- 3.1. Algorithm Performance -- 3.2. Effect of Tuning and Model Selection -- 3.3. Algorithm Coverage -- 4. Discussion and Conclusions -- 5. Acknowledgments -- References -- Improving the explainability of Random Forest classifier - user centered approach -- 1. Introduction, Background and Motivation -- 1.1 Random Forest (RF) Classifiers -- 1.2 Related work on Explainability for Random Forest Classifiers -- 1.3 User-Centered Approach in Enhancing Random Forest Explainability - RFEX , Acknowledgments -- References -- Mapping patient trajectories using longitudinal extraction and deep learning in the MIMIC-III Critical Care Database -- 1. Introduction -- 2. Methods -- 2.1. Source Code and Analysis Availability -- 2.2. Care Event Extraction -- 2.3. Unsupervised learning to learn embeddings of extracted Care Events -- 2.4. Predicting Survival Using Care Events -- 3. Results -- 3.1. Treatment and Outcome Comparison -- 3.2. Unsupervised modeling of patient care events -- 3.3. Supervised prediction of patient survival -- 4. Discussion and Conclusions -- 5. Acknowledgments -- References -- OWL-NETS: Transforming OWL representations for improved network inference -- 1. Introduction -- 2. Methods -- 2.1. Biomedical Use Cases -- 2.2. Link Prediction Procedures -- 2.2.1. Evaluation of Link Prediction Algorithm Performance -- 2.2.2. Evaluation of Inferred Edges -- 3. Results -- 3.1. Comparison of Network Properties -- 3.2. Link Prediction Algorithm Performance -- 3.2.1. Inferred Edges -- 4. Discussion -- 5. Conclusions -- 6. Acknowledgments -- 7. Funding -- References -- Automated disease cohort selection using word embeddings from Electronic Health Records -- 1. Introduction -- 2. Methods and Materials -- 2.1. Research Cohort and Resource -- 2.2. Disease Phenotyping Algorithms -- 2.3. Phenotype and Patient Embedding -- 2.4. Evaluation Design -- 3. Results -- 3.1. Evaluating Performance of Embeddings -- 4. Discussion -- 4.1. Limitations and Future Directions -- 5. Acknowledgments -- References -- Functional network community detection can disaggregate and filter multiple underlying pathways in enrichment analyses -- 1. Introduction -- 2. Methods -- 2.1. General Approach -- 2.2. Control Arm -- 2.3. Experimental Arm -- 3. Results and Discussion -- 3.1. Simulation Study -- 3.2. HGSC Results -- 4. Conclusion -- 5. Acknowledgments

Weitere Ausg.: Print version Altman, Russ B Biocomputing 2018 - Proceedings Of The Pacific Symposium Singapore : World Scientific Publishing Company,c2017 ISBN 9789813235526

Sprache: Englisch

Schlagwort(e): Electronic books

URL: FULL  ((OIS Credentials Required))

UID:

Umfang: 1 online resource (649 pages)

Ausgabe: 1st ed.

ISBN: 9789813235533

Anmerkung: Intro -- Preface -- APPLICATIONS OF GENETICS, GENOMICS AND BIOINFORMATICS IN DRUG DISCOVERY -- Session introduction -- 1. Introduction -- 2. Session Contributions -- 2.1. Drug mechanisms of action and drug combinations -- 2.2. Drug metabolism and in silico drug screening -- 2.3. Disease genes and pathways -- 3. Acknowledgments -- References -- Characterization of drug-induced splicing complexity in prostate cancer cell line using long read technology -- Introduction -- Results -- Discussion -- Methods -- Supplementary -- Acknowledgements -- References -- Prediction of protein-ligand interactions from paired protein sequence motifs and ligand substructures -- 1. Introduction -- 1.1. Decreasing returns in drug discovery pipelines -- 1.2. Existing methods for prediction of protein-ligand interactions -- 2. Methods -- 2.1. Data set -- 2.2. Protein Featurization -- 2.3. Ligand Featurization -- 2.4. Boosting Model -- 2.5. Cross Validation Approaches -- 3. Results -- 3.1. Model Performance -- 3.2. Most predictive motif features -- 3.3. Known positive examples -- 3.3.1. Uricase - Uric acid -- 3.3.2. Chloramphenicol O-acetyltransferase - Chloramphenicol -- 3.3.3. Transthyretin -T4 -- 3.4. Interpreting ADT Paths -- 3.4.1. Path lengths -- 3.4.2. Protein kinase C - Phosphatidylserine -- 4. Discussion -- Acknowledgments -- References -- Cell-specific prediction and application of drug-induced gene expression profiles -- 1. Introduction -- 2. Methods -- 2.1. Notation and terminology -- 2.2. Data processing -- 2.3. The Drug Neighbor Profile Prediction algorithm -- 2.4. The Fast, Low-Rank Tensor Completion algorithm -- 2.5. Baseline averaging schemes -- 2.6. Cross-validation for predicting gene expression profiles -- 2.7. Predicting drug targets and ATC codes -- 3. Results -- 3.1. Overall accuracy -- 3.2. Tradeoffs in accuracy across drug-cell space , 2. Case Study: RFEX Applied to Stanford FEATURE data , 3.2 LOF variants in putative plasticity genes confer risk for neurodevelopmental and nervous system related disorders -- 4. Discussion -- 5. Conclusions and Future Directions -- 6. Acknowledgments -- References -- Extracting a biologically relevant latent space from cancer transcriptomes with variational autoencoders -- 1. Introduction -- 2. Methods -- 2.1. Model Summary -- 2.2. Model Implementation -- 2.3. Parameter Selection -- 2.4. Input Data -- 2.5. Interpretation of Gene Weights -- 2.6. The Latent Space of Ovarian Cancer Subtypes -- 2.7. Enabling Exploration through Visualization -- 3. Results -- 3.1. Tumors were encoded in a lower dimensional space -- 3.2. Features represent biological signal -- 3.3. Interpolating the lower dimensional manifold of HGSC subtypes -- 4. Conclusion -- 5. Reproducibility -- Acknowledgments -- References -- Diffusion mapping of drug targets on disease signaling network elements reveals drug combination strategies -- 1. Introduction -- 2. Methods -- 3. Results -- 4. Discussion -- References -- CHALLENGES OF PATTERN RECOGNITION IN BIOMEDICAL DATA -- Session introduction -- 1. Introduction -- 2. Session Contributions -- 2.1 Network-based approaches -- 2.2 Machine learning approaches -- 2.2 Application of methods to identify patterns in EHR data -- 2.3 Applications in transcriptome and next-generation sequencing data -- 3. References -- Large-scale analysis of disease pathways in the human interactome -- 1. Introduction -- 2. Background and related work -- 3. Data -- 4. Connectivity of disease proteins in the PPI network -- 4.1. Proximity of disease proteins in the PPI network -- 4.2. Connections between PPI network structure and disease protein discovery -- 5. Higher-order connectivity of disease proteins in the PPI network -- 6. Prediction of disease proteins using higher-order PPI network structure -- 7. Conclusion , 3.3. Effects of varying observation density -- 3.4. Accuracy of differentially expressed genes -- 3.5. Analysis of cell-specificity -- 3.6. Utility of completed data for downstream prediction of drug properties -- 4. Discussion -- Supplementary Information -- Funding -- References -- Large-scale integration of heterogeneous pharmacogenomic data for identifying drug mechanism of action -- 1. Introduction -- 2. Materials and Methods -- 2.1. Construction of heterogeneous drug-drug similarity networks -- 2.2. Integration of multi-omics data -- 2.3. Prediction of MoAs and drug targets -- 3. Results -- 3.1. Mania improves the quanti cation of drug-drug similarity -- 3.2. Mania achieves accurate prediction of drug MoAs and targets -- 3.3. Identification of functionally-enriched drug communities -- 3.4. Predictions of drugs for significantly mutated genes -- 4. Discussion -- References -- Chemical reaction vector embeddings: towards predicting drug metabolism in the human gut microbiome -- 1. Introduction -- 2. Methods -- 2.1. Data sources and processing -- 2.2. Constructing molecular vector space -- 2.3. Characterizing vector spaces -- 2.3.1. Molecule-level Analysis -- 2.3.2. Reaction-Level Analysis -- 2.4. Querying drug-metabolite pairs against reaction vectors -- 3. Results -- 3.1. Molecule-level analysis -- 3.2. Reaction-level analysis -- 3.3. Querying reaction vectors against drug-metabolite pairs -- 4. Discussion -- 5. Conclusion -- 6. Acknowledgments -- References -- Loss-of-function of neuroplasticity-related genes confers risk for human neurodevelopmental disorders -- 1. Introduction -- 2. Methods -- 2.1 Neuroplasticity signatures -- 2.2 Hospital and biobank cohort -- 2.3 Variant annotation -- 2.4 Neurodevelopmental disease phenotyping -- 2.5 LOF gene and disease association analysis -- 3. Results -- 3.1 Identifying putative neuroplasticity genes , 6. Supplementary Material -- References -- An ultra-fast and scalable quantification pipeline for transposable elements from next generation sequencing data -- 1. Introduction -- 2. Methods -- 2.1. Transposable Element Library Preparation -- 2.2. Salmon quanti cation algorithm -- 2.3. Statistical tests -- 3. Results -- 3.1. Datasets -- 3.2. Computational experiment setup -- 3.3. SalmonTE guarantees a reliable TE expression estimation -- 3.4. SalmonTE shows a better scalability in the speed benchmark dataset -- 3.5. Discover differentially expressed TEs in ALS cell line -- 4. Conclusion -- Acknowledgments -- References -- Causal inference on electronic health records to assess blood pressure treatment targets: An application of the parametric g formula -- 1. Introduction -- 1.1. Global Burden of Hypertension -- 1.2. Challenges in Previous Efforts to Discover Optimal Target Blood Pressures -- 1.3. Causal Inference from Electronic Health Records As a Tool to Answer Difficult Clinical Questions -- 2. Methods -- 2.1. Data Acquisition from the Mount Sinai Hospital EHR -- 2.2. Problem setup -- 2.3. Parametric g formula -- 3. Results -- 3.1. Electronic Health Records Data -- 3.2. Survival time by goal blood pressure target -- 4. Conclusion -- References -- Data-driven advice for applying machine learning to bioinformatics problems -- 1. Introduction -- 2. Methods -- 3. Results -- 3.1. Algorithm Performance -- 3.2. Effect of Tuning and Model Selection -- 3.3. Algorithm Coverage -- 4. Discussion and Conclusions -- 5. Acknowledgments -- References -- Improving the explainability of Random Forest classifier - user centered approach -- 1. Introduction, Background and Motivation -- 1.1 Random Forest (RF) Classifiers -- 1.2 Related work on Explainability for Random Forest Classifiers -- 1.3 User-Centered Approach in Enhancing Random Forest Explainability - RFEX , Acknowledgments -- References -- Mapping patient trajectories using longitudinal extraction and deep learning in the MIMIC-III Critical Care Database -- 1. Introduction -- 2. Methods -- 2.1. Source Code and Analysis Availability -- 2.2. Care Event Extraction -- 2.3. Unsupervised learning to learn embeddings of extracted Care Events -- 2.4. Predicting Survival Using Care Events -- 3. Results -- 3.1. Treatment and Outcome Comparison -- 3.2. Unsupervised modeling of patient care events -- 3.3. Supervised prediction of patient survival -- 4. Discussion and Conclusions -- 5. Acknowledgments -- References -- OWL-NETS: Transforming OWL representations for improved network inference -- 1. Introduction -- 2. Methods -- 2.1. Biomedical Use Cases -- 2.2. Link Prediction Procedures -- 2.2.1. Evaluation of Link Prediction Algorithm Performance -- 2.2.2. Evaluation of Inferred Edges -- 3. Results -- 3.1. Comparison of Network Properties -- 3.2. Link Prediction Algorithm Performance -- 3.2.1. Inferred Edges -- 4. Discussion -- 5. Conclusions -- 6. Acknowledgments -- 7. Funding -- References -- Automated disease cohort selection using word embeddings from Electronic Health Records -- 1. Introduction -- 2. Methods and Materials -- 2.1. Research Cohort and Resource -- 2.2. Disease Phenotyping Algorithms -- 2.3. Phenotype and Patient Embedding -- 2.4. Evaluation Design -- 3. Results -- 3.1. Evaluating Performance of Embeddings -- 4. Discussion -- 4.1. Limitations and Future Directions -- 5. Acknowledgments -- References -- Functional network community detection can disaggregate and filter multiple underlying pathways in enrichment analyses -- 1. Introduction -- 2. Methods -- 2.1. General Approach -- 2.2. Control Arm -- 2.3. Experimental Arm -- 3. Results and Discussion -- 3.1. Simulation Study -- 3.2. HGSC Results -- 4. Conclusion -- 5. Acknowledgments

Weitere Ausg.: Print version Altman, Russ B Biocomputing 2018 - Proceedings Of The Pacific Symposium Singapore : World Scientific Publishing Company,c2017 ISBN 9789813235526

Sprache: Englisch

Schlagwort(e): Electronic books

URL: FULL  ((OIS Credentials Required))