12th Edition of International Conference on
Neurology and Neurological Disorders
June 22-24, 2026 | Barcelona, Spain
Theoretical Neuroscience
Theoretical neuroscience is the study of how the brain works and the processes behind its inner workings. It is a multi-disciplinary field, combining the biological sciences of neuroscience and psychology with mathematics, physics, and engineering. The goal of theoretical neuroscience is to investigate the way neural networks interact to generate behavior. To do this, it draws from fields like biophysics, neuroscience, and computer science. Theoretical neuroscience combines observational studies of the brain with mathematical models to understand how the brain functions. The primary focus of theoretical neuroscience is to identify general principles and principles of neurons and their associated neural networks. Examples of such principles include how brain cells store and process information and how this affects behavior, or how different areas of the brain interact to produce sensory information or regulate motor control. Theoretical neuroscience also tries to use models to explain the interactions between neurons and neural networks in the brain. This includes studying algorithms, databases, and related data structures used by the brain. By understanding these patterns, researchers are able to learn more about how the brain functions. For instance, a model could be used to better understand the workings of specific areas such as the hippocampus or prefrontal cortex. Theoretical neuroscience research also has led to advances in artificial intelligence and computer science. By understanding more about how the brain operates, researchers can develop better algorithms for simulating and analyzing brain-related processes. In another example, theoretical neuroscience can help researchers develop more effective brain-computer interfaces, and improve the way we interact with computers and other machines. Research in theoretical neuroscience will continue to have a profound impact on our understanding of the brain and its functions. By uncovering the secrets that lie beneath the complexity of the brain, theorists can develop better treatments and therapies for a range of mental illnesses and neurological disorders.
Ken Ware
NeuroPhysics Therapy, Australia
Robert B Slocum
University of Kentucky HealthCare, United States
Yong Xiao Wang
Albany Medical College, United States
Roger H Coletti
Interventional Health, PA, United States
Sid O Bryant
Texas College of Osteopathic Medicine and University of North Texas Health Science Center Fort Worth, United States
Edie Raether
NeuroShifts and Wings for Wishes Academy, United States
Sergey Victorovich Suchkov
N.D. Zelinskii Institute for Organic Chemistry of the Russian Academy of Sciences, Russian FederationSubmit your abstract Today
Title : Scalp acupuncture with functional electrical stimulation for the treatment children with autism spectrum disorder
Zhenhuan Liu, Guangzhou University of Chinese Medicine, China
Title : Perception and individuality in patient cases identifying the ongoing evolution of Myalgic Encephalomyelitis/Chronic Fatigue Syndrome (ME/CFS)
Ken Ware, NeuroPhysics Therapy, Australia
Title : A structure-based strategy to target pathogenic α-synuclein in Parkinson’s disease
Salvador Ventura, Autonomous University of Barcelona, Spain
Title : Rabies: Challenges in taming the beast
Alan C Jackson, University of Calgary, Canada
Title : Designing and managing intelligent and ethical transformed health and social care ecosystems
Bernd Blobel, University of Regensburg, Germany
Title : Understanding Alzheimer's disease biomarkers across diverse populations - Opportunities and Insights for novel prevision medicine approaches
Sid O Bryant, Texas College of Osteopathic Medicine and University of North Texas Health Science Center Fort Worth, United States