The Mejias lab uses a combination of theoretical techniques, computational modeling and data analysis to scout the neural mechanisms underlying large-scale brain communication, hierarchical brain dynamics, sensory predictions and distributed cognitive functions. You can learn more about our research and the organization of the lab below.

Research line #1: The role of neural heterogeneity in neural dynamics

Computational models have traditionally considered that neurons in the brain are fairly homogeneous –for example, many network models ignore the existence of different subtypes of neurons, or they neglect the intrinsic variability of physiological properties even within a given neuron subtype. While washing heterogeneity away is convenient to build useful simplifications of the brain, it is now clear that neural heterogeneity plays a major role in neural computations. Our previous work identified neural heterogeneity as a key factor in rate and temporal coding (Mejias and Longtin 2012; 2014) and also uncovered interactions between specific cell types which give rise to paradoxical neural dynamics (Garcia del Molino et al., 2017). We currently study the effects of neural heterogeneity on perception and cognition.

Research line #2: Neural dynamics across multiple scales

Computational models are a perfect way to link neural phenomena at different scales. In previous work, we have built models of the macaque brain spanning several scales, from microscopic circuits to full-brain networks, by incorporating in the models precise anatomical and electrophysiological data. These models correctly predict and reproduce neural dynamics across multiple spatial and temporal scales (Mejias et al., Science Advances 2016), provide biologically plausible solutions for problems in efficient brain communication (Joglekar et al., Neuron 2018) and explore the emergence of working memory and other cognitive functions in distributed brain networks (Mejias and Wang, 2022). We are expanding this approach to model the brain of other animals (such as rodents and humans) and also investigating the use of such models in computational psychiatry, for example to identify potential biomarkers in brain disorders.

Research line #3: Neural networks for perception and cognition

Recent work has shown that properly trained neural networks may be effectively used as a model to explain the computations underlying perceptual and cognitive functions. Our lab is currently developing biologically plausible neural networks to explore this research line, including recurrent neural networks for multisensory and decision-making tasks (Wierda et al. 2023) and hierarchical networks for predictive coding (Brucklacher et al. Front. Comput. Neurosci. 2023; Lee et al. Front. Comput. Neurosci. 2023). Very often, our focus is not on optimizing model performance as much as possible, but rather on investigating the effect of including biophysically realistic features in the model (such as the presence of excitatory and inhibitory cell types, for example). Our overall goal is to use these models to link the behavioral output observed in animals with underlying neural computations which give rise to such behavior.

Our view is that a close collaboration between experimental and computational neuroscientists is key to successfully unravel the secrets of the brain. Our lab is uniquely well positioned in this sense: we have close interactions with the Olcese, Bosman, Suzuki, de Gee and Pennartz labs, and together we form the Cognitive and Systems Neuroscience Group. The Mejias lab specializes in theoretical and computational approaches to study the brain at different scales –from small neural circuits to full-brain models. With our work, we complement the efforts of our experimental colleagues and also develop our own independent research lines sketched above.

I am assistant professor and head of the Computational Neuroscience Lab at the Cognitive and Systems Neuroscience Group of the University of Amsterdam. With a background in physics and mathematics, I obtained a PhD in computational neuroscience from the University of Granada (Spain) in 2009. During my PhD, I was also visiting researcher at the Université Paris V René Descartes (now Université de Paris, France). I then went on to work as a postdoctoral researcher at the University of Ottawa (Canada) and New York University (USA), and as a visiting researcher at the East China Normal University/ NYU Shanghai (China), before joining the University of Amsterdam in 2017. The research of my team is focused on the theoretical and computational study of data-constrained multi-scale brain networks during perception and cognition, and the subsequent development of our advances into brain simulation technologies. Our interest spans several brain functions, including working memory, multisensory integration and predictive coding, as well as brain disorders impairing such functions. I often partake in committee or organizational duties for leading conferences like Cosyne and the OCNS annual meeting, and I currently serve as external faculty member at the Institute Carlos I for Theoretical and Computational Physics in Granada and the European Institute of Theoretical Neuroscience in Paris.

The lab is currently constituted by the following people:

• Jorge Mejias (Principal Investigator)
• Francisco Páscoa dos Santos (postdoc)
• Daniel Bodor (research software engineer)
• Giulia Crocioni (research software engineer)
• Alex Hadjiivanov (research software engineer)
• Parva Alavian (PhD student)
• Rares Dorcioman (PhD student)
• Kwangjun Lee (PhD student)
• Licheng Zou (MSc student)
• Jazz Stofberg (MSc student)
• Zijiang Zhang (MSc student)
• Lex Otto (MSc student)

Recent alumni: Nikos Priovoulos (postdoc, now at UCL), Abhirup Bandyopadhyay (postdoc, now at Karolinska), Giulia Moreni (PhD student), Matthias Brucklacher (PhD student).

Do you want to join the lab? Candidates at any level (Master, PhD, postdoc) can contact me by email. We usually have several projects available for interested candidates, and you are also welcome to bring your own ideas and interests to the table. For PhD and postdocs, I am happy to support fellowship applications if we have sufficient time for planning.

Funding and support. The lab's current and past support comes from the following funding sources:

• Amsterdam Neuroscience Proof of Concept "Understanding cortico-striatal network dynamics underlying compulsive behavior".
• Horizon EU Project "Virtual brain twin for personalized treatment of psychiatric disorders".
• ABC Talent Grant "The cerebellar stripes: cognitive units?"
• eScience Spearhead Project "Training artificial neural networks for behavioral strategies in neuroscience".
• ABC Project Grant “Translational biomarkers for compulsivity across large-scale brain networks”.
• NWA-ORC consortium “Perceptive acting under uncertainty: safety solutions for autonomous systems”.
• Human Brain Project, SGA3 Task 2.1: “Data-driven model of multisensory object recognition in cortical systems”.

Collaborators. We work together with other labs and researchers across the Netherlands and abroad, including:

• At the CSN group: Cyriel Pennartz, Conrado Bosman, Umberto Olcese, Mototaka Suzuki, Jan Willem de Gee.
• The Netherlands, beyond CSN: Sander Bohte (CWI), Simon van Gaal (UvA), Matthan Caan (AUMC), Ingo Willuhn (NIN), Niels Cornelisse (VU), Chris de Zeeuw, Laurens Bosman and Mario Negrello (EMC).
• Europe, beyond the Netherlands: Shirin Dora (Ulster University, UK), Henry Kennedy (INSERM, France), Viktor Jirsa (AMU, France), Miguel A. Munoz and Joaquin Torres (UGR, Spain).
• And beyond: MXiao-Jing Wang (New York University), John D. Murray (Yale University), Guangyu Robert Yang (MIT), Ronaldo Nunes (UFABC), Andre Longtin and Leonard Maler (University of Ottawa), Songting Li and Douglas Zhou (Shanghai Jiao Tong University).