BSICoS | I3A

Biomedical Signal Interpretation and Computational Simulation

División

Responsable

Web

https://bsicos.i3a.es/

The Biomedical Signal Interpretation and Computational Simulation (BSICoS) group focuses its activity on the processing, interpretation and Computer Simulation of biomedical signals.

The main objective of the group is the development of methods for biomedical signal processing, driven by the physiology, for personalized interpretation (diagnosis, prognosis and therapy) of the conditions of the cardiovascular, respiratory and autonomic nervous systems and their interactions.

The goal is to improve the impact of ICTs in health and further understanding the functioning of biological systems that can be observed through noninvasive signals. Key to this is working with clinical teams and research groups that combine the experiences of the two areas, direct research to solve relevant clinical problems and facilitate the transfer of results to clinical practice.

Reseachers

Permanent

Bailón Luesma, Raquel

Gil Herrando, Eduardo

Ibáñez Pereda, Jaime

Laguna Lasaosa, Pablo

Lázaro Plaza, Jesús

Martín Yebra, Alba Pilar

Martínez Cortés, Juan Pablo

Mincholé Lapuente, Ana

Ordovás Vidal, Laura

Pueyo Paules, Esther

Ramírez García, Julia

Sánchez Tapia, Carlos

Temporary

Armañac Julián, Pablo

Bueno Palomeque, Freddy L.

Bukhari, Hassaan

Cajal Orleans, Diego

Celotto, Chiara

García, Pablo Vicente

García Mendívil, Laura

Garrido Huéscar, Elisa

Gómez Fonseca, Neurys

Gómez Gómez, Marta

Hernández Bellido, Natalia

Madrid Chirinos, Josseline

Martínez Martínez, Dorselia

Moreno Aramburu, Cristina

Noguero Soler, Inés

Palacios Rosales, Saúl Darío

Pérez Martínez, Alba

Pérez Martínez, Cristina

Riccio, Jennifer

Rodríguez Carbó, Jimena

Rosales, Ricardo M.

Sales Bellés, Clara

Sánchez Barat, Marcos

Velarte Iranzo, Antonio

Affiliated

Alcaine Otín, Alejandro

Bolea Bolea, Juan Ramón

Carro Fernández, Jesús

Hernando Jumilla, David

Lozano Albalate, Mayte

Monasterio Bazán, Violeta

Oliván Viguera, Aida

Peláez Coca, Mª Dolores

Pérez Zabalza, María

Research lines

Processing of intracardiac EGM signals

Biomedical signal processing and characterization for respiratory pathologies

ECG markers for arrhythmia risk identification

Experimental characterization and in-vitro modeling of cardiac aging

Genetics of cardiovascular risk

In-vitro and ex-vivo experimental electrophysiology

Long-term monitoring using wearable devices

Modeling and simulation of cardiac electrophysiology

Neural interfaces with the central nervous system to study movement

Non-invasive parametrization of autonomic nervous system

Projects

RhythMods

Implementation and validation of a closed-loop neural interface to entrain brain rhythms and reduce motor symptoms in Parkinson's Disease

To develop a non-invasive neuromodulation platform to apply closed-loop stimulation protocols synchronized with brain oscillations decoded from the periphery with muscle recordings

MESMODI-BCG

Methods for Stroke Monitoring and Diagnosing based on BCG

To develop novel, non-invasive methods for detecting cardiac and non-cardiac disease in stroke patients using the ballistocardiogram (BCG) signal, allowing for patient monitoring without transfer to clinical settings

INSIDE-HEART

multI-discipliNary, multi-Sectoral and multi-national trainIng network on Digital biomarkErs for supraventricular arrHythmia charactErizAtion and Risk assessmenT

Establishing a multi-disciplinary network to tackle the design and the early-phase validation of digital biomarkers, specifically targeting the diagnosis of supraventricular arrhythmias (SVAs) and their associated potential for adverse risk assessment, via the joint combination of signal processing, artificial intelligence and non-clinical devices.

ECHOES

Extracting the Human Motor Null Space from Muscles - A new framework to measure human neural activity

ECHOES will capitalize on recent breakthroughs in decoding the spinal outputs to muscles to develop a theoretical and experimental framework to unveil the 'motor null space' in human muscles.

DNABEATS

Customised DNA-based nanocarriers to boost heart healing

DNABEATS aims to bring advanced materials to regenerate injured myocardium.

Monitoring and assessment of obstructive sleep apnea and its outcomes through the processing of physiological signals of wearables

To improve diagnosis and monitoring of sleep apnea-hypopnea syndrome (SAHS)

Computational biomechanics and bioengineering 3D printing to develop a personalized regenerative biological ventricular assist devide to provide lasting functional support to damaged hearts

By developing biological ventricular assist devices (BioVADs), BRAV3 will bring a quantum leap in regenerative medicine and its translation towards the clinic, as well as impact the development of novel medical technologies whilst greatly advancing our knowledge on human heart development.

Closed-loop stimulation of the central nervous system to modulate tremoroscillations in the motor nervous system

To validate technically and clinically novel methods to understand, and give support to tremor diagnosis.

Completed projects (since 2020)

Project	End year
DIGICARDIO	2024
STRATEGIC	2024
Physiology-driven signal analysis for guiding cardiac arrhythmia management and therapy	2023
Towards improved management of cardiovascular diseases by integrative in silico-in vitro-in vivo research into hearts structure, function and autonomic regulation	2023
Characterization and modeling of the physiological response in variable hyperbaric environments	2022
Physiologically guided signal analysis for ambulatory monitoring of depression	2022
RADAR-CNS	2022
Detection of K+ concentration alterations from the ECG	2021
MODELAGE	2021
PPG-based sleep apnea monitoring	2021
MY-ATRIA	2021
PIC	2021