• News

    The Impact of Digital Technology on Educational Reform: The Role of Artificial Intelligence in Education

    February 10, 2026

    The significance of this study lies in the inevitability with which the challenges of digitalisation have impacted the educational sector. As a consequence of the globalising tendencies characteristic of postmodern society, technologies facilitating the integration of information resources have increasingly permeated educational systems.

    Within the context of postmodernism, a prevailing global trend in education is the transition of pedagogical practices to a technologically advanced framework, necessitating the systematic incorporation of information technologies. The vector of change in education points to the need to expand the scope of innovation. In today’s rapidly evolving world, education is undergoing significant changes influenced by digital technologies.

    This article explores how new technologies, in particular artificial intelligence, are transforming traditional teaching methods, making them more interactive, effective, and accessible. The author analyses the advantages of personalised learning, which allows to adapt the educational process to the individual needs of each student. In addition, the role of e-learning in ensuring flexibility and accessibility of education is discussed. Explored the potential of artificial intelligence in education, its ability to analyse large amounts of data, adapt learning materials, and provide individualised support to students.

  • Varia

    Meet the Team Behind BRAIN Journal

    November 12, 2025

    We are pleased to introduce part of the dedicated team behind BRAIN – Broad Research in Artificial Intelligence and Neuroscience.

    In this photo, you can see Dr. Claudia Tugulea (left) and Dr. Diana Ciubotaru (right), two of the passionate and committed colleagues who bring their expertise, creativity, and vision to our editorial mission.

    Together with Editor-in-Chief Dr. Bogdan Pătruț and Associate Editors Dr. Jude Hemanth and Dr. Utku Kose, our young and dynamic team works continuously to strengthen the quality of the editorial process and to position BRAIN Journal as a global platform for innovative and interdisciplinary research.

    We look forward to continuing this journey of collaboration, excellence, and scientific advancement — shaping the future of knowledge together.

  • Research Publications

    Can Neural Networks Enhance Physics Simulations?

    November 10, 2025

    This post presents a pioneering study by PhD researchers from the University Politehnica of Bucharest, exploring how artificial neural networks (ANNs) can model and predict physical interactions with the precision of traditional physics engines. The work bridges computational physics and artificial intelligence, marking a significant step toward faster, data-driven simulation systems.

    Authors:
    Cristian-Dumitru Avatavului – PhD Student, University Politehnica of Bucharest, Romania (RO)
    Rareș-Cristian Ifrim – PhD Student, Eng., University Politehnica of Bucharest, Romania (RO)
    Mihai Voncilă – PhD Student, Eng., University Politehnica of Bucharest, Romania (RO)

    Introduction

    Physics simulations are the backbone of modern science and engineering — powering advancements in mechanical design, robotics, gaming, virtual reality, and materials research. However, traditional simulations based on deterministic physics engines can be computationally intensive and time-consuming, especially for systems involving complex collisions or dynamic interactions.

    This study investigates whether neural networks — systems capable of learning from data rather than being explicitly programmed — can replicate or even improve upon traditional physical models.

    The research addresses a fundamental question:

    Can artificial intelligence learn the laws of motion and accurately predict how objects interact in real-world scenarios?

    Research Objective

    The primary goal was to design, develop, and evaluate a neural network architecture capable of emulating and predicting dynamic interaction patterns between two distinct entities in contact.

    By modeling the physical impulses and resulting forces during collisions, the researchers sought to test whether neural networks could function as efficient alternatives or complements to physics-based simulation engines.

    Methodology

    The study employed a hybrid approach combining classical simulation tools and machine learning:

    1. Dataset Generation:
      A physics engine was used to simulate interactions between objects under varying physical conditions — generating a robust dataset for neural network training.
    2. Neural Network Design:
      The proposed ANN architecture was trained to learn the relationships between initial physical parameters (e.g., mass, velocity, angle of contact) and the resulting interaction forces and impulses.
    3. Model Evaluation:
      After training, the ANN’s predictions were compared directly with results produced by the physics engine to evaluate accuracy, stability, and computational efficiency.

    Key Findings

    • The neural network demonstrated prediction accuracy rates ranging from 60% to 91%, depending on the complexity of the test scenarios.
    • In simpler interactions (e.g., elastic collisions), high precision was achieved, while more complex or chaotic interactions revealed the need for further model refinement.
    • The study showed that AI-driven models can approximate real physical behaviors with reasonable accuracy and significantly reduced computation times.

    These results highlight the potential of data-driven modeling as a supplement to physics-based methods, especially in contexts where real-time computation is crucial — such as robotics control systems, video game physics, or virtual simulations.

    Discussion

    While traditional physics engines remain unmatched in precision and generality, neural networks offer adaptive advantages:

    • They can generalize from previous simulations to predict new outcomes without recalculating the entire physics model.
    • They enable real-time predictions, crucial for interactive applications.
    • They can reduce computational costs, especially when used as surrogate models in iterative simulations or design optimization loops.

    However, the authors note that further optimization — including deeper architectures, better hyperparameter tuning, and expanded datasets — is necessary to enhance reliability and generalizability.

    Conclusion

    The study provides promising evidence that neural networks can emulate physical simulations with notable efficiency and accuracy, opening a new path in computational physics and engineering simulation.

    While not yet a complete replacement for physics engines, these AI-based models have the potential to augment traditional methods, especially in domains requiring speed, adaptability, and predictive learning.

    Future research will focus on hybrid simulation frameworks that combine the rigor of physics-based systems with the learning capacity of neural networks, paving the way toward intelligent, self-improving models of the physical world.

    See full paper here: https://doi.org/10.18662/brain/14.2/445.

  • Research Publications

    Exploring the Intersection of Artificial Intelligence and Human Resource Management: A Bibliometric Study

    November 8, 2025

    This article investigates the dynamic intersection between Artificial Intelligence (AI) and Human Resource Management (HRM), highlighting how AI technologies are reshaping organizational efficiency, decision-making, and employee engagement. Through an extensive bibliometric analysis, the study provides a comprehensive overview of global research trends and developments in this domain from 2014 to 2023, based on 491 scholarly publications indexed in the Web of Science database.

    The findings reveal how AI applications have become increasingly critical in HRM, especially during the COVID-19 pandemic, where they supported healthcare professionals, enabled remote work environments, and optimized workforce management under high-pressure conditions. The integration of AI into leadership management, data-driven decision systems, and information management frameworks has led to measurable improvements in organizational performance, talent acquisition, and employee experience.

    Ultimately, the study concludes that the continuous evolution of AI technologies will further advance their strategic role within HRM. By fostering adaptability, responsiveness, and operational intelligence, AI-driven HRM is positioned to address emerging workforce challenges and sustain innovation in a rapidly changing global labor market.

    See full paper here: http://dx.doi.org/10.70594/brain/15.4/15

  • Research Publications

    Exploring AI and Computational Science in Predicting Outcomes of Conservative Treatment for Cervical Intraepithelial Neoplasia

    March 19, 2025

    This post presents a preliminary research perspective on how artificial intelligence (AI) and computational methods can help identify predictive factors in the conservative management of cervical intraepithelial neoplasia (CIN), a precancerous condition strongly linked to HPV. The goal is to improve diagnosis, follow-up, and treatment decisions through smarter, data-driven tools.

    Authors:
    Maria Diana Focșa – Leonardo da Vinci University (CH)
    Radu Lefter – Romanian Academy (RO)
    Mihaela Tomaziu-Todosia – Grigore T. Popa University of Medicine and Pharmacy, Iași (RO)
    Bogdan Novac – Grigore T. Popa University of Medicine and Pharmacy, Iași (RO)
    Otilia Novac – Grigore T. Popa University of Medicine and Pharmacy, Iași (RO)
    Ecaterina Tomaziu-Todosia Anton – Grigore T. Popa University of Medicine and Pharmacy, Iași (RO)

    What Is This Study About?

    Cervical intraepithelial neoplasia (CIN) refers to precancerous changes in the cells of the cervix, most often caused by human papillomavirus (HPV). CIN is important to monitor because some lesions regress, while others can progress toward cervical cancer if not detected and managed in time.

    Current clinical practice relies on colposcopy-guided biopsy and imaging, but these methods depend a lot on the examiner’s experience. That’s where AI can make a difference.

    Why Use AI and Computational Science?

    The study, titled “A Preliminary View on Using AI and Computational Science for Observing Predictive Factors in Conservative Treatment of Cervical Intraepithelial Neoplasia,” explores how advanced algorithms can:

    • analyze colposcopy and cytology images automatically;
    • detect subtle patterns that indicate progression or regression;
    • help doctors decide which patients can safely continue conservative treatment;
    • support earlier prediction of cervical cancer risk.

    By integrating clinical data with AI-powered image analysis, healthcare providers could move toward more personalized, data-driven cervical cancer prevention.

    Key Benefits Highlighted

    • Higher diagnostic consistency – AI reduces subjectivity in image interpretation.
    • Better risk stratification – computational models can flag patients more likely to progress.
    • Support for conservative management – avoiding overtreatment while keeping high-risk patients under closer observation.
    • Foundation for future automated workflows in cervical screening.

    Conclusion

    This is an early, exploratory view, but it points clearly to the future: AI-assisted colposcopy and automated cervical cytology can significantly enhance how CIN is monitored and treated. As datasets grow and algorithms improve, such tools could become part of routine gynecological care, helping prevent cervical cancer more efficiently.

    Read the full text here: http://dx.doi.org/10.70594/brain/16.3/1.