P. Ion
Research Scientist I - Bioinformatics
Biography
I am a researcher and educator specializing in multidisciplinary research on data analysis, machine learning and computational modeling in biology. I am interested in understanding the complexity of biological systems, building computational models to understand their dynamic behaviour and using them as inspiration for new computational models.
Publications
Publication | Authors | data | |
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article
The Preface |
Genova Daniela; Petre Ion | Natural Computing, 2024 | |
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article
Special Issue On Foundational Methods In Systems Biology |
Petre Ion; Paeun Andrei | Theoretical Computer Science, 2024 | |
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article
Connecting The Dots: Computational Network Analysis For Disease Insight And Drug Repurposing |
Siminea Nicoleta; Czeizler Eugen; Popescu Victor -Bogdan; Petre Ion; Paun Andrei | Current Opinion In Structural Biology, 2024 | |
AbstractNetwork biology is a powerful framework for studying the structure, function, and dynamics of biological systems, offering insights into the balance between health and disease states. The field is seeing rapid progress in all of its aspects: data availability, network synthesis, network analytics, and impactful applications in medicine and drug development. We review the most recent and significant results in network biomedicine, with a focus on the latest data, analytics, software resources, and applications in medicine. We also discuss what in our view are the likely directions of impactful development over the next few years. |
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article
Strong Regulatory Graphs |
Gustafsson Patric; Petre Ion | Fundamenta Informaticae, 2024 | |
AbstractLogical modeling is a powerful tool in biology, offering a system-level understanding of the complex interactions that govern biological processes. A gap that hinders the scalability of logical models is the need to specify the update function of every vertex in the network depending on the status of its predecessors. To address this, we introduce in this paper the concept of strong regulation, where a vertex is only updated to active/inactive if all its predecessors agree in their influences; otherwise, it is set to ambiguous. We explore the interplay between active, inactive, and ambiguous influences in a network. We discuss the existence of phenotype attractors in such networks, where the status of some of the variables is fixed to active/inactive, while the others can have an arbitrary status, including ambiguous. |
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article
Raman-Based Machine Learning Platform Reveals Unique Metabolic Differences Between Idhmut And Idhwt Glioma. |
Lita Adrian; Sjoberg Joel; Pacioianu David; Siminea Nicoleta; Celiku Orieta; Dowdy Tyrone; Paun Andrei; Gilbert Mark R; Noushmehr Houtan; Petre Ion; Larion Mioara | Neuro-Oncology, 2024 | |
AbstractBACKGROUND: Formalin-fixed, paraffin-embedded (FFPE) tissue slides are routinely used in cancer diagnosis, clinical decision-making, and stored in biobanks, but their utilization in Raman spectroscopy-based studies has been limited due to the background coming from embedding media.METHODS: Spontaneous Raman spectroscopy was used for molecular fingerprinting of FFPE tissue from 46 patient samples with known methylation subtypes. Spectra were used to construct tumor/non-tumor, IDH1WT/IDH1mut, and methylation-subtype classifiers. Support vector machine and random forest were used to identify the most discriminatory Raman frequencies. Stimulated Raman spectroscopy was used to validate the frequencies identified. Mass spectrometry of glioma cell lines and TCGA were used to validate the biological findings.RESULTS: Here we develop APOLLO (rAman-based PathOLogy of maLignant glioma) - a computational workflow that predicts different subtypes of glioma from spontaneous Raman spectra of FFPE tissue slides. Our novel APOLLO platform distinguishes tumors from nontumor tissue and identifies novel Raman peaks corresponding to DNA and proteins that are more intense in the tumor. APOLLO differentiates isocitrate dehydrogenase 1 mutant (IDH1mut) from wildtype (IDH1WT) tumors and identifies cholesterol ester levels to be highly abundant in IDHmut glioma. Moreover, APOLLO achieves high discriminative power between finer, clinically relevant glioma methylation subtypes, distinguishing between the CpG island hypermethylated phenotype (G-CIMP)-high and G-CIMP-low molecular phenotypes within the IDH1mut types.CONCLUSIONS: Our results demonstrate the potential of label-free Raman spectroscopy to classify glioma subtypes from FFPE slides and to extract meaningful biological information thus opening the door for future applications on these archived tissues in other cancers. |
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book, book chapter
Systems Biology Modelling And Analysis: Formal Bioinformatics Methods And Tools-Network Modeling Methods For Precision Medicine |
Elio Nushi; Victor Popescu; Jose Angel Sanchez Martin; Sergiu Ivanov; Eugen Czeizler; Ion Petre | Wiley, 2022 | |
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book, book chapter
Lecture Notes In Computer Science-Computational Methods In Systems Biology |
Ion Petre; Andrei Paun | Springer, 2022 | |
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article
Network Controllability Solutions For Computational Drug Repurposing Using Genetic Algorithms |
Popescu Victor-Bogdan; Kanhaiya Krishna; Nastac Dumitru Iulian; Czeizler Eugen; Petre Ion | Scientific Reports, 2022 | |
AbstractControl theory has seen recently impactful applications in network science, especially in connections with applications in network medicine. A key topic of research is that of finding minimal external interventions that offer control over the dynamics of a given network, a problem known as network controllability. We propose in this article a new solution for this problem based on genetic algorithms. We tailor our solution for applications in computational drug repurposing, seeking to maximize its use of FDA-approved drug targets in a given disease-specific protein-protein interaction network. We demonstrate our algorithm on several cancer networks and on several random networks with their edges distributed according to the Erdos-Renyi, the Scale-Free, and the Small World properties. Overall, we show that our new algorithm is more efficient in identifying relevant drug targets in a disease network, advancing the computational solutions needed for new therapeutic and drug repurposing approaches. |
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article
Scalable Reaction Network Modeling With Automatic Validation Of Consistency In Event-B |
Sanwal Usman; Hoang Thai Son; Petre Luigia; Petre Ion | Scientific Reports, 2022 | |
AbstractConstructing a large biological model is a difficult, error-prone process. Small errors in writing a part of the model cascade to the system level and their sources are difficult to trace back. In this paper we extend a recent approach based on Event-B, a state-based formal method with refinement as its central ingredient, allowing us to validate for model consistency step-by-step in an automated way. We demonstrate this approach on a model of the heat shock response in eukaryotes and its scalability on a model of the ErbB signaling pathway. All consistency properties of the model were proved automatically with computer support. |
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article
Network Analytics For Drug Repurposing In Covid-19 |
Siminea Nicoleta; Popescu Victor; Martin Jose Angel Sanchez; Florea Daniela; Gavril Georgiana; Gheorghe Ana-Maria; Itcus Corina; Kanhaiya Krishna; Pacioglu Octavian; Popa Laura Lona; Trandafir Romica; Tusa Maria Iris; Sidoroff Manuela; Paun Mihaela; Czeizler Eugen; Paun Andrei; Petre Ion | Briefings In Bioinformatics, 2022 | |
AbstractTo better understand the potential of drug repurposing in COVID-19, we analyzed control strategies over essential host factors for SARS-CoV-2 infection. We constructed comprehensive directed protein-protein interaction (PPI) networks integrating the top-ranked host factors, the drug target proteins and directed PPI data. We analyzed the networks to identify drug targets and combinations thereof that offer efficient control over the host factors. We validated our findings against clinical studies data and bioinformatics studies. Our method offers a new insight into the molecular details of the disease and into potentially new therapy targets for it. Our approach for drug repurposing is significant beyond COVID-19 and may be applied also to other diseases. |
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book
Network Modelling Methods For Precision Medicine |
Nushi E.; Popescu V.-B.; Martin J.-A.S.; Ivanov S.; Czeizler E.; Petre I. | Systems Biology Modelling And Analysis: Formal Bioinformatics Methods And Tools, 2022 | |
AbstractWe discuss in this chapter several network modelling methods and their applicability to precision medicine. We review several network centrality methods (degree centrality, closeness centrality, eccentricity centrality, betweenness centrality, and eigenvector-based prestige) and two systems controllability methods (minimum dominating sets and network structural controllability). We demonstrate their applicability to precision medicine on three multiple myeloma patient disease networks. Each network consists of protein-protein interactions (PPI) built around a specific patient's mutated genes, around the targets of the drugs used in the standard of care in multiple myeloma, and around multiple myeloma-specific essential genes. For each network, we demonstrate how the network methods we discuss can be used to identify personalized, targeted drug combinations uniquely suited to that patient. © 2020 John Wiley & Sons, Inc. All rights reserved. |
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book, book chapter
Theoretical Computer Science, Special Issue On Reaction Systems |
Lukasz Mikulski; Ion Petre | Elsevier, 2021 | |
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book, book chapter
Theoretical Computer Science, Special Issue On “Building Bridges Between Computer Science And Biology |
Paola Bonizzoni; Lila Kari; Ion Petre; Grzegorz Rozenberg | Elsevier, 2021 | |
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book, book chapter
Theoretical Computer Science, Special Issue On “A Fascinating Rainbow Of Computation” |
Lila Kari; Ion Petre; Grzegorz Rozenberg; Arto Salomaa | Elsevier, 2021 | |
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conference
Network Controllability Analysis For Drug Repurposing In Covid-19 |
Nicoleta Siminea; Victor Popescu; Jose Angel Sanchez Martin; Ana-Maria Dobre; Daniela Florea; Geor-giana Gavril; Corina Ițcuș; Krishna Kanhaiya; Octavian Pacioglu; Laura Ioana Popa; Romica Trandafir; Maria Iris Tușa; Manuela Sidoroff; Mihaela Păun; Eugen Czeizler; Andrei Păun; Ion Petre | The 29Th Conference On Inteligent Systems For Molecular Biology, Joint With The 20Th European Conference On Computational Biology, 2021 | |
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article
Preface: Special Issue On Reaction Systems |
Mikulski Lukasz; Petre Ion | Theoretical Computer Science, 2021 | |
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article
Netcontrol4Biomed: A Web-Based Platform For Controllability Analysis Of Protein-Protein Interaction Networks |
Popescu Victor-Bogdan; Angel Sanchez-Martinez Jose; Schacherer Daniela; Safadoust Sadra; Majidi Negin; Andronescu Andrei; Nedea Alexandru; Ion Diana; Mititelu Eduard; Czeizler Eugen; Petre Ion | Bioinformatics, 2021 | |
AbstractMotivation: There is an increasing amount of data coming from genome-wide studies identifying disease-specific survivability-essential proteins and host factors critical to a cell becoming infected. Targeting such proteins has a strong potential for targeted, precision therapies. Typically however, too few of them are drug targetable. An alternative approach is to influence them through drug targetable proteins upstream of them. Structural target network controllability is a suitable solution to this problem. It aims to discover suitable source nodes (e.g. drug targetable proteins) in a directed interaction network that can control (through a suitable set of input functions) a desired set of targets. Results: We introduce NetControl4BioMed, a free open-source web-based application that allows users to generate or upload directed protein-protein interaction networks and to perform target structural network controllability analyses on them. The analyses can be customized to focus the search on drug targetable source nodes, thus providing drug therapeutic suggestions. The application integrates protein data from HGNC, Ensemble, UniProt, NCBI and InnateDB, directed interaction data from InnateDB, Omnipath and SIGNOR, cell-line data from COLT and DepMap, and drug-target data from DrugBank. |
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article
Special Issue On Reaction Systems Preface |
Mikulski Lukasz; Petre Ion | Journal Of Membrane Computing, 2020 | |
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article
Network Controllability Analysis Of Three Multiple-Myeloma Patient Genetic Mutation Datasets |
Sanchez Martin Jose Angel; Petre Ion | Fundamenta Informaticae, 2020 | |
AbstractNetwork controllability focuses on the concept of driving the dynamical system associated to a directed network of interactions from an arbitrary initial state to an arbitrary final state, through a well-chosen set of input functions applied in a minimal number of so-called input nodes. In earlier studies we and other groups demonstrated the potential of applying this concept in medicine. A directed network of interactions may be built around the main known drivers of the disease being studied, and then analysed to identify combinations of drug targets controlling survivability-essential genes in the network. This paper takes the next step and focuses on patient data. We demonstrate that comprehensive protein-protein interaction networks can be built around patient genetic data, and that network controllability can be used to identify possible personalised drug combinations. We discuss the algorithmic methods that can be used to construct and analyse these networks. |
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article
A Computational Model For The Access To Medical Service In A Basic Prototype Of A Healthcare System |
Petre Luigia; Sanwal Usman; Shah Gohar; Shah Charmi; Tyagi Dwitiya; Petre Ion | Fundamenta Informaticae, 2020 | |
AbstractHow robust is a healthcare system? How does a patient navigate the system and what is the cost (e.g., number of medical services required or number of times the medical provider had to be changed to get access to the required medical services) incurred from the first symptoms to getting cured? How will it fare in the wake to a sudden epidemic or a disaster? How are all of these affected by administrative decisions such as allocating/diminishing resources in various areas or centralising services? These are the questions motivating our study on a formal prototype model for a healthcare system. We propose that a healthcare system can be understood as a distributed system with independent nodes (healthcare providers) computing according to their own resources and constraints, with tasks (patient needs) being allocated between the nodes. The questions about the healthcare system become in this context questions about resource availability and distribution between the nodes. We construct in this paper an Event-B model capturing the basic functionality of a simplified healthcare system: patients with different types of medical needs being allocated to suitable medical providers, and navigating between different providers for their turn for multi-step treatments. |
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article
Controllability Of Reaction Systems |
Ivanov Sergiu; Petre Ion | Journal Of Membrane Computing, 2020 | |
AbstractControlling a dynamical system is the ability of changing its configuration arbitrarily through a suitable choice of inputs. It is a very well-studied concept in control theory, with wide-ranging applications in medicine, biology, social sciences and engineering. We introduce in this article the concept of controllability of reaction systems as the ability of transitioning between any two states through a suitable choice of context sequences. We show that the problem is PSPACE-hard. We also introduce a model of oncogenic signalling based on reaction systems and use it to illustrate the intricacies of the controllability of reaction systems. This study opens up a new line of research on the dynamic properties of reaction systems and it introduces a new, intricate biomedical model based on reaction systems. |
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article
Refinement-Based Modeling Of The Erbb Signaling Pathway |
Bogdan Iancu; Usman Sanwal; Cristian Gratie; Ion Petre | Computers In Biology And Medicine, 2019 | |
AbstractThe construction of large scale biological models is a laborious task, which is often addressed by adopting iterative routines for model augmentation, adding certain details to an initial high level abstraction of the biological phenomenon of interest. Refitting a model at every step of its development is time consuming and computationally intensive. The concept of model refinement brings about an effective alternative by providing adequate parameter values that ensure the preservation of its quantitative fit at every refinement step. We demonstrate this approach by constructing the largest-ever refinement-based biomodel, consisting of 421 species and 928 reactions. We start from an already fit, relatively small literature model whose consistency we check formally. We then construct the final model through an algorithmic step-by-step refinement procedure that ensures the preservation of the model's fit. |
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article
Reaction Systems And Synchronous Digital Circuits |
Zeyi Shang;Sergey Verlan;Ion Petre andGexiang Zhang | Molecules, 2019 | |
AbstractA reaction system is a modeling framework for investigating the functioning of the living cell, focused on capturing cause-effect relationships in biochemical environments. Biochemical processes in this framework are seen to interact with each other by producing the ingredients enabling and/or inhibiting other reactions. They can also be influenced by the environment seen as a systematic driver of the processes through the ingredients brought into the cellular environment. In this paper, the first attempt is made to implement reaction systems in the hardware. We first show a tight relation between reaction systems and synchronous digital circuits, generally used for digital electronics design. We describe the algorithms allowing us to translate one model to the other one, while keeping the same behavior and similar size. We also develop a compiler translating a reaction systems description into hardware circuit description using field-programming gate arrays (FPGA) technology, leading to high performance, hardware-based simulations of reaction systems. This work also opens a novel interesting perspective of analyzing the behavior of biological systems using established industrial tools from electronic circuits design. |
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article
Structural Target Controllability Of Linear Networks |
Eugen Czeizler; Kai-Chiu Wu; Cristian Gratie; Krishna Kanhaiya; Ion Petre | Ieee/Acm Transactions On Computational Biology And Bioinformatics, 2018 | |
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article
Netcontrol4Biomed: A Pipeline For Biomedical Data Acquisition And Analysis Of Network Controllability |
Krishna Kanhaiya; Vladimir Rogojin; Keivan Kazemi; Eugen Czeizler and Ion Petre | Bmc Bioinformatics, 2018 | |
AbstractBackground: Network controllability focuses on discovering combinations of external interventions that can drive a biological system to a desired configuration. In practice, this approach translates into finding a combined multi-drug therapy in order to induce a desired response from a cell; this can lead to developments of novel therapeutic approaches for systemic diseases like cancer. Result: We develop a novel bioinformatics data analysis pipeline called NetControl4BioMed based on the concept of target structural control of linear networks. Our pipeline generates novel molecular interaction networks by combining pathway data from various public databases starting from the user's query. The pipeline then identifies a set of nodes that is enough to control a given, user-defined set of disease-specific essential proteins in the network, i.e., it is able to induce a change in their configuration from any initial state to any final state. We provide both the source code of the pipeline as well as an online web-service based on this pipeline http://combio.abo.fi/nc/net_control/remote_call.php. Conclusion: The pipeline can be used by researchers for controlling and better understanding of molecular interaction networks through combinatorial multi-drug therapies, for more efficient therapeutic approaches and personalised medicine. |
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article
Webrsim: A Web-Based Reaction Systems Simulator |
Sergiu Ivanov; Vladimir Rogojin; Sepinoud Azimi; Ion Petre | Enjoying Natural Computing, 2018 | |
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conference
Network Controllability Algorithmics For Cancer Medicine |
Ion Petre | Workshop 2018 Algonano: Metode Algoritmice Și Computaționale În Bio-Medicină Și Nanotehnologie, 2018 | |
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article
Controlling Directed Protein Interaction Networks In Cancer |
Kanhaiya Krishna; Czeizler Eugen; Gratie Cristian; Petre Ion | Scientific Reports, 2017 | |
AbstractControl theory is a well-established approach in network science, with applications in bio-medicine and cancer research. We build on recent results for structural controllability of directed networks, which identifies a set of driver nodes able to control an a-priori defined part of the network. We develop a novel and efficient approach for the (targeted) structural controllability of cancer networks and demonstrate it for the analysis of breast, pancreatic, and ovarian cancer. We build in each case a protein-protein interaction network and focus on the survivability-essential proteins specific to each cancer type. We show that these essential proteins are efficiently controllable from a relatively small computable set of driver nodes. Moreover, we adjust the method to find the driver nodes among FDA-approved drug-target nodes. We find that, while many of the drugs acting on the driver nodes are part of known cancer therapies, some of them are not used for the cancer types analyzed here; some drug-target driver nodes identified by our algorithms are not known to be used in any cancer therapy. Overall we show that a better understanding of the control dynamics of cancer through computational modelling can pave the way for new efficient therapeutic approaches and personalized medicine. |