Pržulj, Nataša, 1973-
Pržulj, Nataša
Nataša Pržulj Professor of Biomedical Data Science
VIAF ID: 2984154441732635460006 ( Personal )
Permalink: http://viaf.org/viaf/2984154441732635460006
Preferred Forms
- 100 0 _ ‡a Nataša Pržulj ‡c Professor of Biomedical Data Science
-
- 100 1 _ ‡a Prz̆ulj, Nataša
- 100 1 _ ‡a Prz̆ulj, Natăsa
- 100 1 _ ‡a Pržulj, Nataša
- 100 1 _ ‡a Pržulj, Nataša, ‡d 1973-
4xx's: Alternate Name Forms (5)
5xx's: Related Names (1)
Works
Title | Sources |
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2-Tree probe interval graphs have a large obstruction set | |
Analysis of the signatures of cancer stem cells in malignant tumors using protein interactomes and the STRING database | |
Analyzing network data in biology and medicine : an interdisciplinary textbook for biological, medical and computational scientists | |
Anti-nicastrin monoclonal antibodies elicit pleiotropic anti-tumour pharmacological effects in invasive breast cancer cells | |
Antiproliferative activity and mode of action analysis of novel amino and amido substituted phenantrene and naphtho [2, 1-b] thiophene derivatives | |
Biological function through network topology : a survey of the human diseasome | |
Bridging the gaps in systems biology | |
C-GRAAL common-neighbors-based global GRAph ALignment of biological networks | |
Characterization of the proteasome interaction network using a QTAX-based tag-team strategy and protein interaction network analysis | |
Chromatin network markers of leukemia | |
Complementarity of network and sequence information in homologous proteins | |
The core diseasome | |
Critical review on clinoptilolite safety and medical applications in vivo | |
Discovering disease-disease associations by fusing systems-level molecular data | |
ergm.graphlets a package for ERG modeling based on graphlet statistics | |
Evidence for network evolution in an Arabidopsis interactome map | |
From genetic data to medicine : from DNA samples to disease risk prediction in personalized genetic tests | |
Functional geometry of protein interactomes | |
Fuse : multiple network alignment via data fusion | |
GR-Align : fast and flexible alignment of protein 3D structures using graphlet degree similarity | |
L-GRAAL : lagrangian graphlet-based network aligner | |
GraphCrunch 2 software tool for network modeling, alignment and clustering | |
Graphlet-based measures are suitable for biological network comparison | |
Graphlet Laplacians for topology-function and topology-disease relationships | |
Hereditary dominating pair graphs | |
High-throughput mapping of a dynamic signaling network in mammalian cells | |
Higher-order molecular organization as a source of biological function | |
The integrated disease network | |
Integration of molecular network data reconstructs Gene Ontology | |
An integrative approach to modeling biological networks | |
Integrative network alignment reveals large regions of global network similarity in yeast and human | |
Introduction to graph and network theory | |
Machine learning for data integration in cancer precision medicine : matrix factorization approaches | |
Methods for biological data integration : perspectives and challenges | |
Minimum average time broadcast graphs | |
Modelling the yeast interactome | |
Network analytics in the age of big data : How can we holistically mine big data? | |
Network wiring of pleiotropic kinases yields insight into protective role of diabetes on aneurysm | |
Not all scale-free networks are born equal the role of the seed graph in PPI network evolution | |
Omics data complementarity underlines functional cross-communication in yeast | |
On solving the symmetric non-negative matrix tri-factorization problem | |
Optimal network alignment with graphlet degree vectors | |
Optimized null model for protein structure networks | |
Precision medicine - A promising, yet challenging road lies ahead | |
Probabilistic graphlets capture biological function in probabilistic molecular networks | |
Protein complex prediction via cost-based clustering | |
Rebuttal to the Letter to the Editor in response to the paper : proper evaluation of alignment-free network comparison methods | |
Revealing the Hidden Language of Complex Networks | |
The role of genes co-amplified with nicastrin in breast invasive carcinoma | |
Structure of brain functional networks | |
Survey of Network-Based Approaches to Research of Cardiovascular Diseases | |
Systematic protein-protein interaction mapping for clinically relevant human GPCRs | |
Systems-level cancer gene identification from protein interaction network topology applied to melanogenesis-related functional genomics data | |
A technical approach to local government amalgamation | |
Topological network alignment uncovers biological function and phylogeny | |
The topology of the growing human interactome data | |
Towards a data-integrated cell | |
Tragovina biomedicinskog inženjeringa | |
Uncovering biological network function via graphlet degree signatures | |
Unified alignment of protein-protein interaction networks | |
Unveiling new disease, pathway, and gene associations via multi-scale neural network |