CSTB team: Complex Systems and Translational Bioinformatics

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<center><u><big>'''Theme : LBGI Bioinformatique et Génomique Intégratives'''</big></u></center>
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__NOTOC__
<center><u><big> [http://lbgi.fr lbgi.fr]</big></u></center><p>
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LBGI Bioinformatics and Integrating Genomics, led by [[Olivier Poch]] and [[Julie Thompson]], focuses on a thriving field of research in the field of health: translational bioinformatics. Our main objective is to develop a robust IT infrastructure capable of managing big data in order to extract relevant knowledge in a "bed-patient" approach. In this context, we are particularly interested in the study of rare genetic diseases and the understanding of the pathophysiological mechanisms involved in these diseases, which often have a potential interest in understanding altered biological processes in more common diseases, such as obesity, diabetes or cancer....
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==Presentation of the CSTB team==
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<center>The CSTB team was created on 1 January 2016 as a fusion of the themes LBGI (Bioinformatics and Integrating Genomics) and SONIC (Stochastic Optimization and Nature Inspired Computing) of the previous BFO team.</center><br>
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'''Complex Systems''' are present everywhere around us. They can be defined as interacting reconfigurable entities, structured on several emerging levels of organization, in which the whole cannot be understood without the parts and the parts cannot be understood without the whole.
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A "complex system" is generally any system comprising a large number of heterogeneous entities, between which local interactions create multiple levels of structuring and collective organization. Examples include natural systems ranging from biomolecules and living cells to social networks and the ecosphere, as well as sophisticated artificial systems such as the Internet, large power grids or any large scale distributed software.
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'''Biological systems''' are unique in the complexity of their functioning and regulation, and the integrated study of the multiple levels that contribute to the final behavior of these systems now represents a new challenge for the scientific community. Thanks to the ever increasing quantities of data that describe each component of the system in detail, new opportunities exist to develop descriptive and predictive modeling approaches. These developments are applicable to the whole field of complex systems science, from social networks to finance.
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In medicine, this 'systemic' awareness has led to the emergence of a new field of interdisciplinary research: translational medicine. This field aims to understand and exploit the diversity of clinical and phenotypic manifestations of diseases in patients to better understand and model the emergence and evolution of diseases. Ultimately, the aim of these developments is to lead to optimized and personalized treatments.
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'''The "Complex Systems and Translational Bioinformatics" team''' covers a broad spectrum of research in computer science, from bioinformatics to artificial intelligence.
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In this context, CSTB intends to actively participate in 4P developments (Participative, Predictive, Preventive and Personalized) by developing original solutions in the fields of education, health or industry within two research themes:
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* [[Evolutionary_and_Medical_Genomics]]
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We have a long experience in biomedical data analysis, annotation and mining. Our goals are mainly focused on knowledge extraction from genetic and medical data, from codes in DNA to patient phenotypes. We focus on the management of massive data (quality control, integration, FAIRification, security...), as well as the exploitation of evolutionary information in sequence-structure-function studies. In two key areas, genetic diseases and biodiversity, we aim to identify associations between genotype and phenotype and to understand patterns and trends in the data. Traditional methods, which have been successful in the study of simple systems, are limiting when applied to complex dynamic systems, where the genetic makeup of individuals underlies a large number of variations that interact with each other producing effects from the atomic level to the organism.
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* [[Trustworthy_Artificial_Intelligence]]
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We have expertise in the modeling of complex systems and nature-inspired optimization algorithms, including artificial evolution and artificial immune systems. These inherently massively parallel and asynchronous systems are constitutive of IT in the 21st century, composed of massively parallel computers in networks.
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: The applications of nature-inspired complex systems include IT security and the search for patterns (artificial immune systems), optimization and artificial intelligence (artificial evolution) ecosystems for calculation and teaching (biological ecosystems) and of course, participatory, predictive, preventive and personalized translational medicine (which is the case for all complex systems).
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: Indeed, on the basis of the observed data ("Participative"), we will try to determine "Predictive" models allowing to implement a "Prevention" in a "Personalized" way, for the Factory of the Future, for IT security, health (patient networks) and education (student / teacher networks).
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The team also coordinates the [http://https://bigest.icube.unistra.fr/index.php/Accueil BiGEST-ICube] (Bio-Informatics and Genomics) platform of the [http://icube.unistra.fr ICUBE ] laboratory, offering the community a unique portal to databases and software for bioinformatics, contributes to the plateform [https://gaia.icube.unistra.fr/index.php/Accueil GAIA] (informatique Graphique, Analyse de données et Intelligence Artificielle), and proposes 2 services for massively parallel computation ([http://easea.unistra.fr EASEA CLOUD]) and education ([http://poem.unistra.fr POEM]).
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Internationally, the team coordinates (with the [https://www.univ-lehavre.fr Havre University]) the [http://fr.unesco.org/programme-unitwin-chaires-unesco UniTwin ] [http://cs-dc.org CS-DC] of the [http://fr.unesco.org UNESCO]: a Digital Campus Complex Systems with more than 120 universities (>3 million students, >3000 researchers in 28 countries).
  
==Research topics==
 
The LBGI is devoted to the development of robust, automated and integrated in silico approaches (analytical approaches, statistics, data integration and mining, extraction and representation of knowledge...) in order to study the evolution and behavior of complex biological systems ("Hyperstructures", networks, etc.) in humans and various animal models. Taking advantage of our integrated IT approaches and long-standing collaborations at the international, national and local levels, the LBGI participates in the analysis of complex systems involved in various human diseases, including the study of functional deficiencies related to retinal diseases or the brain, the identification of genetic variations related to ciliopathies and the characterization of the genomic and transcriptomic context in various cancers.
 
==Operations==
 
The work of the LBGI is organized around two main complementary axes:
 
* "Translational IT" ([[Julie Thompson]]), to develop an IT infrastructure dedicated to the integrated analysis of the "big data" resulting from high-throughput studies of human genetic diseases. This includes the design and development of original data management systems (storage, quality control, heterogeneous data integration) and analysis tools dedicated to data mining and extraction of biomedical knowledge. An important aspect is the development of intuitive user interfaces to facilitate access by biologists and clinicians.
 
* "Systems bioinformatics" ([[Olivier Poch]]/[[Odile Lecompte]]), to develop research in the emerging field of the analysis of complex biological systems, in order to understand genotype-phenotype relationships and to anwser questions related to human diseases. This includes integrated studies of evolutive, "omics" and patient data, particularly those concerning ciliopathies, and the development of a systemic approach to the relationships between mutations and biological networks in diseases.
 
 
==Keywords==
 
==Keywords==
 
.........
 
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__NOTOC__
 
<center><u><big>'''Theme : SONIC (Stochastic Optimisation and Nature Inspired Computing)'''</big></u></center>
 
La thématique SONIC (Stochastic Optimisation and Nature Inspired Computing), <!-- Parallel Evolutionary Computation and ARtificial Intelligence (PECARI)--> led by [[Pierre Collet]], studies and uses techniques to tackle complex problems that are insoluble by exact methods. Nature-inspired methods are privileged for their robustness and their very good exploration of the search space. The team uses mainly:
 
* evolutionary algorithms, including :
 
** genetic algorithms (applied to discrete and combinatory problems),
 
** evolutionary strategies (applied to continuous problems),
 
** genetic programming (applied to learning and data mining problems),
 
** multi-objective evolutionary optimisation (for all industrial problems that need to optimize several antagonistic criteria at the same time),
 
* optimisation by ant colonies,
 
* emerging approaches (BOIDS, optimisation by particle swarms).
 
  
  
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[https://cstb.icube.unistra.fr/en/index.php/ArchivesStructure Previous team organisation 2013-2015]
  
 
[[fr:Accueil]]
 
[[fr:Accueil]]

Latest revision as of 11:15, 30 August 2022


Presentation of the CSTB team

The CSTB team was created on 1 January 2016 as a fusion of the themes LBGI (Bioinformatics and Integrating Genomics) and SONIC (Stochastic Optimization and Nature Inspired Computing) of the previous BFO team.


Complex Systems are present everywhere around us. They can be defined as interacting reconfigurable entities, structured on several emerging levels of organization, in which the whole cannot be understood without the parts and the parts cannot be understood without the whole.

A "complex system" is generally any system comprising a large number of heterogeneous entities, between which local interactions create multiple levels of structuring and collective organization. Examples include natural systems ranging from biomolecules and living cells to social networks and the ecosphere, as well as sophisticated artificial systems such as the Internet, large power grids or any large scale distributed software.

Biological systems are unique in the complexity of their functioning and regulation, and the integrated study of the multiple levels that contribute to the final behavior of these systems now represents a new challenge for the scientific community. Thanks to the ever increasing quantities of data that describe each component of the system in detail, new opportunities exist to develop descriptive and predictive modeling approaches. These developments are applicable to the whole field of complex systems science, from social networks to finance.

In medicine, this 'systemic' awareness has led to the emergence of a new field of interdisciplinary research: translational medicine. This field aims to understand and exploit the diversity of clinical and phenotypic manifestations of diseases in patients to better understand and model the emergence and evolution of diseases. Ultimately, the aim of these developments is to lead to optimized and personalized treatments.

The "Complex Systems and Translational Bioinformatics" team covers a broad spectrum of research in computer science, from bioinformatics to artificial intelligence.


In this context, CSTB intends to actively participate in 4P developments (Participative, Predictive, Preventive and Personalized) by developing original solutions in the fields of education, health or industry within two research themes:

We have a long experience in biomedical data analysis, annotation and mining. Our goals are mainly focused on knowledge extraction from genetic and medical data, from codes in DNA to patient phenotypes. We focus on the management of massive data (quality control, integration, FAIRification, security...), as well as the exploitation of evolutionary information in sequence-structure-function studies. In two key areas, genetic diseases and biodiversity, we aim to identify associations between genotype and phenotype and to understand patterns and trends in the data. Traditional methods, which have been successful in the study of simple systems, are limiting when applied to complex dynamic systems, where the genetic makeup of individuals underlies a large number of variations that interact with each other producing effects from the atomic level to the organism.

We have expertise in the modeling of complex systems and nature-inspired optimization algorithms, including artificial evolution and artificial immune systems. These inherently massively parallel and asynchronous systems are constitutive of IT in the 21st century, composed of massively parallel computers in networks.

The applications of nature-inspired complex systems include IT security and the search for patterns (artificial immune systems), optimization and artificial intelligence (artificial evolution) ecosystems for calculation and teaching (biological ecosystems) and of course, participatory, predictive, preventive and personalized translational medicine (which is the case for all complex systems).
Indeed, on the basis of the observed data ("Participative"), we will try to determine "Predictive" models allowing to implement a "Prevention" in a "Personalized" way, for the Factory of the Future, for IT security, health (patient networks) and education (student / teacher networks).

The team also coordinates the BiGEST-ICube (Bio-Informatics and Genomics) platform of the ICUBE laboratory, offering the community a unique portal to databases and software for bioinformatics, contributes to the plateform GAIA (informatique Graphique, Analyse de données et Intelligence Artificielle), and proposes 2 services for massively parallel computation (EASEA CLOUD) and education (POEM).

Internationally, the team coordinates (with the Havre University) the UniTwin CS-DC of the UNESCO: a Digital Campus Complex Systems with more than 120 universities (>3 million students, >3000 researchers in 28 countries).

Keywords

.........


Previous team organisation 2013-2015

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