Juan R. Rabuñal scite author profile

Colorectal cancer is one of the most frequent types of cancer in the world and generates important social impact. The understanding of the specific metabolism of this disease and the transformations of the specific drugs will allow finding effective prevention, diagnosis and treatment of the colorectal cancer. All the terms that describe the drug metabolism contribute to the construction of ontology in order to help scientists to link the correlated information and to find the most useful data about this topic. The molecular components involved in this metabolism are included in complex network such as metabolic pathways in order to describe all the molecular interactions in the colorectal cancer. The graphical method of processing biological information such as graphs and complex networks leads to the numerical characterization of the colorectal cancer drug metabolic network by using invariant values named topological indices. Thus, this method can help scientists to study the most important elements in the metabolic pathways and the dynamics of the networks during mutations, denaturation or evolution for any type of disease. This review presents the last studies regarding ontology and complex networks of the colorectal cancer drug metabolism and a basic topology characterization of the drug metabolic process sub-ontology from the Gene Ontology.

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Optical Fish Trajectory Measurement in Fishways through Computer Vision and Artificial Neural Networks

Rodríguez

Bermúdez

Rabuñal

et al. 2011

J. Comput. Civ. Eng.

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Drug Discovery and Design for Complex Diseases through QSAR Computational Methods

Munteanu¹,

Fernández-Blanco²,

Seoane³

et al. 2010

CPD

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There is a need for a study of the complex diseases due to their important impact on our society. One of the solutions involves the theoretical methods which are fast and efficient tools that can lead to the discovery of new active drugs specially designed for these diseases. The Quantitative Structure - Activity Relationship models (QSAR) and the complex network theory become important solutions for screening and designing efficient pharmaceuticals by coding the chemical information of the molecules into molecular descriptors. This review presents the most recent studies on drug discovery and design using QSAR of several complex diseases in the fields of Neurology, Cardiology and Oncology.

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Optimization of existing equations using a new Genetic Programming algorithm: Application to the shear strength of reinforced concrete beams

Pérez

Cladera

Rabuñal

et al. 2012

Advances in Engineering Software

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Machine Learning Based Moored Ship Movement Prediction

Alvarellos

Figuero

Carro

et al. 2021

JMSE

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Several port authorities are involved in the R+D+i projects for developing port management decision-making tools. We recorded the movements of 46 ships in the Outer Port of Punta Langosteira (A Coruña, Spain) from 2015 until 2020. Using this data, we created neural networks and gradient boosting models that predict the six degrees of freedom of a moored vessel from ocean-meteorological data and ship characteristics. The best models achieve, for the surge, sway, heave, roll, pitch and yaw movements, a 0.99, 0.99, 0.95, 0.99, 0.98 and 0.98 R2 in training and have a 0.10 m, 0.11 m, 0.09 m, 0.9°, 0.11° and 0.15° RMSE in testing, all below 10% of the corresponding movement range. Using these models with forecast data for the weather conditions and sea state and the ship characteristics and berthing location, we can predict the ship movements several days in advance. These results are good enough to reliably compare the models' predictions with the limiting motion criteria for safe working conditions of ship (un) loading operations, helping us decide the best location for operation and when to stop operations more precisely, thus minimizing the economic impact of cargo ships unable to operate.

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Fish tracking in vertical slot fishways using computer vision techniques

Rodríguez

Bermúdez

Rabuñal

et al. 2014

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Vertical slot fishways are hydraulic structures which allow the upstream migration of fish through obstructions in rivers. The appropriate design of these devices should take into account the behavior and biological requirements of the target fish species. However, little is known at the present time about fish behavior in these artificial conditions, which hinders the development of more effective fishway design criteria. In this work, an efficient technique to study fish trajectories and behavior in vertical slot fishways is proposed. It uses computer vision techniques to analyze images collected from a camera system and effectively track fish inside the fishway. Edge and region analysis algorithms are employed to detect fish in extreme image conditions and Kalman filtering is used to track fish along time. The proposed solution has been extensively validated through several experiments, obtaining promising results which may help to improve the design of fish passage devices.

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Juan R. Rabuñal

Automatic epileptic seizure detection in EEGs based on line length feature and artificial neural networks

Computer application for the analysis and design of vertical slot fishways in accordance with the requirements of the target species

Artificial Intelligence Techniques for Colorectal Cancer Drug Metabolism: Ontologies and Complex Networks

Optical Fish Trajectory Measurement in Fishways through Computer Vision and Artificial Neural Networks

Drug Discovery and Design for Complex Diseases through QSAR Computational Methods

Optimization of existing equations using a new Genetic Programming algorithm: Application to the shear strength of reinforced concrete beams

Machine Learning Based Moored Ship Movement Prediction

Fish tracking in vertical slot fishways using computer vision techniques

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