James Shine | Systems Neuroscience | Research Excellence Award

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Prof. Dr. James Shine | Systems Neuroscience | Research Excellence Award

Prof. Dr. James Shine | The University of Sydney | Australia

This researcher is an influential systems neurobiologist whose work has significantly advanced the scientific understanding of whole-brain neural dynamics. With over 170 peer-reviewed publications, more than 16,000 citations, an h-index of 67, and an i10-index of 177, their scholarly contributions have shaped multiple domains within contemporary neuroscience. Their research integrates multimodal neuroimaging, computational modelling, network science, and systems-level neurobiology to uncover the principles governing cognition, attention, and consciousness. A major focus of their work involves developing biophysically informed models that link neuroanatomical organization with large-scale patterns of human brain activity, enabling the generation of testable predictions across imaging modalities. Their publications span impactful studies in neuroimaging, neurobiology, and computational science, including widely cited papers in high-profile journals. Their seminal insights into dynamic functional brain network integration have catalyzed global interest in time-resolved brain connectivity, influencing methodological developments and being adopted by more than 100 research groups across over 90 countries. Their research program also advances innovative computational frameworks for analysing complex neural signals, contributing both theoretical and practical tools that inform the study of neurodegenerative conditions and cognitive function. their work continues to shape the direction of systems neuroscience and quantitative brain research.

Profile: Google Scholar

Featured Publications

Shine, J. M., Bissett, P. G., Bell, P. T., Koyejo, O., Balsters, J. H., Gorgolewski, K. J., … (2016). The dynamics of functional brain networks: Integrated network states during cognitive task performance. Neuron, 92(2), 544–554.

Hansen, J. Y., Shafiei, G., Markello, R. D., Smart, K., Cox, S. M. L., Nørgaard, M., … (2022). Mapping neurotransmitter systems to the structural and functional organization of the human neocortex. Nature Neuroscience, 25(11), 1569–1581.

Lurie, D. J., Kessler, D., Bassett, D. S., Betzel, R. F., Breakspear, M., Kheilholz, S., … (2020). Questions and controversies in the study of time-varying functional connectivity in resting fMRI. Network Neuroscience, 4(1), 30–69.

Shine, J. M., Breakspear, M., Bell, P. T., Ehgoetz Martens, K. A., Shine, R., … (2019). Human cognition involves the dynamic integration of neural activity and neuromodulatory systems. Nature Neuroscience, 22(2), 289–296.

Poldrack, R. A., Laumann, T. O., Koyejo, O., Gregory, B., Hover, A., Chen, M. Y., … (2015). Long-term neural and physiological phenotyping of a single human. Nature Communications, 6, 8885.

Shine, J. M., Matar, E., Ward, P. B., Frank, M. J., Moustafa, A. A., Pearson, M., … (2013). Freezing of gait in Parkinson’s disease is associated with functional decoupling between the cognitive control network and the basal ganglia. Brain, 136(12), 3671–3681.

Siphokazi Gatyeni | Systems Neuroscience | Best Researcher Award

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Dr. Siphokazi Gatyeni | Systems Neuroscience | Best Researcher Award

Dr. Siphokazi Gatyeni | University of Johannesburg | South Africa

Dr Siphokazi Princess Gatyeni is a Lecturer in the Department of Mathematics and Applied Mathematics at the University of Johannesburg, having progressed through roles as Assistant Lecturer and Marker. She earned her PhD in Applied Mathematics with a thesis on the long-term dynamics of COVID-19 in South Africa under the supervision of Prof Farai Nyabadza and Prof Faraimunashe Chirove. Prior to that she completed an MSc in Mathematics studying modelling of in- and out-patient rehabilitation for substance abuse, and an Honours in Biomathematics modelling substance abuse dynamics. Her research focuses on infectious-disease modelling (COVID-19, TB, malaria), optimal control theory and social behaviour in epidemic systems, with demonstrated expertise in MATLAB, Python, Mathematica, LaTeX, R-Studio, Excel and SPSS. According to Google Scholar she has been cited 41 times. Her h-index is currently not publicly listed on that profile but the citation count reflects an active early-career research trajectory. Her work includes recent journal articles on meningitis transmission and the impact of vaccination strategies, as well as modelling the effects of stigma on COVID-19 transmission. In the classroom she emphasises real-world applications and technology-assisted instruction, teaching courses from Engineering Mathematics through Numerical Analysis and Special Topics, and is committed to mentoring postgraduate students in interdisciplinary mathematical modelling.

Profile: orcid

Featured Publications

Gatyeni, S. P. (2025). Mathematical modeling of meningitis transmission dynamics and the impact of vaccination strategies. Scientific African, e03048.

Mbalilo, V. M., Nyabadza, F., & Gatyeni, S. P. (2025). Modelling the potential impact of TB-funded prevention programs on the transmission dynamics of TB. Infectious Disease Modelling.

Gatyeni, S. P., Chirove, F., & Nyabadza, F. (2022). Modelling the potential impact of stigma on the transmission dynamics of COVID-19 in South Africa. Mathematics, 10(18), 3253.

Gatyeni, S. P. (2022). Application of optimal control to the dynamics of COVID-19 disease in South Africa. Scientific African, e01268.

Zhou Yu | Behavioral Neuroscience | Best Researcher Award

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Dr. Zhou Yu | Behavioral Neuroscience | Best Researcher Award

Dr. Yu Zhou is a postdoctoral researcher at Army Engineering University, specializing in the intersection of neuroscience, computer vision, and target detection. His research primarily focuses on deceptive visual design for both human and machine perception, exploring how visual stimuli can influence detection, recognition, and cognitive processing. Zhou has conducted pioneering studies on camouflage and optical deception, utilizing EEG-based brain functional network analysis to evaluate target visibility and cognitive responses. His work integrates principles from weapon science, biomedical engineering, and computer science to develop comprehensive models of visual perception and deception. Representative publications include investigations into neural responses to camouflage targets with varying exposure signs, the impact of color differences on brain activation patterns, and feasibility assessments of optical camouflage effects. Through these studies, he contributes to a deeper understanding of how visual designs can manipulate human attention and computer vision systems, providing actionable insights for defense technology applications. Zhou’s research emphasizes rigorous quantitative evaluation methods, leveraging neurophysiological data to inform the design of effective deceptive visual patterns. With an h-index of 2 and multiple citations, his work demonstrates a growing influence in fields spanning neuroscience-informed computer vision, perceptual deception, and applied optical camouflage.

Profiles: Scopus | Reasearch Gate

Featured publication

Author(s). (2024). Neural responses to camouflage targets with different exposure signs based on EEG. Neuropsychologia.

Mansoor Showkat | Computational Neuroscience | Best Researcher Award

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Mr. Mansoor Showkat | Computational Neuroscience | Best Researcher Award

Mr. Mansoor Showkat | SKUAT-Kashmir | India

Mansoor Showkat is a researcher in Plant Biotechnology with an M.Sc. from the University of Agricultural Sciences, Bangalore, and a B.Sc. (Hons.) in Horticulture from Sher-e-Kashmir University of Agricultural Sciences and Technology of Kashmir. His research expertise spans molecular biology, computational biology, bioinformatics, and tissue culture, with particular emphasis on antifungal compound analysis, gene transformation, and plant-pathogen interactions. Mansoor has contributed to several peer-reviewed publications and book chapters, focusing on the in-silico and in-vitro evaluation of bioactive compounds such as cordycepin, molecular mechanisms of stress responses, and secondary metabolite profiling in plants. His research projects include genetic transformation studies, metabolomics-based investigations, and the use of omics tools for crop improvement. He has actively participated in numerous international workshops, conferences, and webinars related to biotechnology, bioinformatics, and genomics. Mansoor has achieved significant academic recognition, including national rankings in competitive examinations by the Indian Council of Agricultural Research. His scientific impact is reflected by a citation count of 15, an h-index of 2, and an i10-index of 0, highlighting his growing contribution to molecular and agricultural biotechnology research.

Profiles: Google Scholar| Research Gate | Linked In

Featured Publications

  1. Showkat, M., Narayanappa, N., Umashankar, N., & Saraswathy, B. P., et al. (2024). Optimization of fermentation conditions of Cordyceps militaris and in silico analysis of antifungal property of cordycepin against plant pathogens. Journal of Basic Microbiology, 64(10), e2400409.

  2. Fatimah, N., Ashraf, S., R. U., K. N., Anju, P. B., Showkat, M., Perveen, K., Bukhari, N. A., et al. (2024). Evaluation of suitability and biodegradability of the organophosphate insecticides to mitigate insecticide pollution in onion farming. Heliyon, 10(12).

  3. Margay, K. A. A. A. R., Ashraf, S., Fatimah, N., Jabeen, S. G., & Showkat, M., et al. (2024). Plant circadian clocks: Unravelling the molecular rhythms of nature. International Journal of Plant and Soil Science, 36(8), 596–617.

  4. Margay, A. R., Ashraf, S., Fatimah, N., Jabeen, S. G., Showkat, M., R. U., K. N., Gani, A., et al. (2024). Harnessing brassinosteroids for heat resilience in wheat: A comprehensive study.

  5. Showkat, M., Nagesha, N., Ashraf, S., Nayana, K., Bashir, S., Nair, A. S., et al. (2024). Cordycepin: A molecular Trojan horse against Fusarium oxysporum f. sp. cubense—A computational perspective.

Musawer Hakimi | Systems Neuroscience | Best Researcher Award

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Mr. Musawer Hakimi | Systems Neuroscience | Best Researcher Award

Mr. Musawer Hakimi | Samangan University | Afghanistan

Mr. Musawer Hakimi is an accomplished Assistant Professor at Samangan University, specializing in Computer Science. He holds a Bachelor’s degree in Computer Science from India and a Master’s degree in Information Technology from Kabul University. Demonstrating a strong commitment to lifelong learning, he has earned 25 professional certificates in Computer Science from India, along with two specialized certifications in Ethical Hacking and Oracle Database from the United States. His academic excellence and research contributions have positioned him as a respected scholar with 3 published documents, 13 citations, and an h-index of 1. Mr. Hakimi’s scholarly work has been featured in reputable international journals across the United Kingdom, the United States, Turkey, Sweden, and Indonesia, reflecting his active engagement in global research networks. Beyond his research achievements, he is dedicated to nurturing future computer scientists through his teaching and mentorship at the Public University of Afghanistan, where he plays an instrumental role in advancing computer science education. His interdisciplinary expertise, international collaborations, and consistent scholarly output underscore his impact as an educator, researcher, and thought leader in the evolving field of computer science, contributing to the growth of academic excellence and innovation within Afghanistan and the broader global academic community.

Profiles: Scopus | Orcid | Google Scholar | Research Gate

Featured Publications

Quraishi, T., Ulusi, H., Muhid, A., Hakimi, M., & Olusi, M. R. (2024). Empowering students through digital literacy: A case study of successful integration in a higher education curriculum. Journal of Digital Learning and Distance Education, 2(9), 667–681.

Fazil, A. W., Hakimi, M., Shahidzay, A. K., & Hasas, A. (2024). Exploring the broad impact of AI technologies on student engagement and academic performance in university settings in Afghanistan. RIGGS: Journal of Artificial Intelligence and Digital Business, 2(2), 56–63.

Hakimi, M., Katebzadah, S., & Fazil, A. W. (2024). Comprehensive insights into e-learning in contemporary education: Analyzing trends, challenges, and best practices. Journal of Education and Teaching Learning (JETL), 6(1), 86–105.

Hakimi, N., Hakimi, M., Hejran, M., Quraishi, T., Qasemi, P., Ahmadi, L., & others. (2024). Challenges and opportunities of e-learning for women’s education in developing countries: Insights from Women Online University. EDUTREND: Journal of Emerging Issues and Trends in Education, 1(1), 57–69.

Hasas, A., Hakimi, M., Shahidzay, A. K., & Fazil, A. W. (2024). AI for social good: Leveraging artificial intelligence for community development. Journal of Community Service and Society Empowerment, 2(2), 196–210.

Fazil, A. W., Hakimi, M., Sajid, S., Quchi, M. M., & Khaliqyar, K. Q. (2023). Enhancing internet safety and cybersecurity awareness among secondary and high school students in Afghanistan: A case study of Badakhshan Province. American Journal of Education and Technology, 2(4), 50–61.

Alam, M. I., Khatri, S., Shukla, D. K., Misra, N. K., Satpathy, S., & Hakimi, M. (2025). Blockchain-based coal supply chain management system for thermal power plants. Discover Computing, 28(1), 1–32.

Soheila Hosseinzadeh | Cognitive Neuroscience | Best Researcher Award

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Assoc. Prof. Dr. Soheila Hosseinzadeh | Cognitive Neuroscience | Best Researcher Award

Assist. Prof. Dr. Soheila Hosseinzadeh, Tehran University of Medical Sciences, Iran.

Dr. Soheila Hosseinzadeh is a distinguished Assistant Professor of Neuroscience at the Tehran University of Medical Sciences, with a rich academic background that spans nursing, physiology, and neuroscience. Over the years, she has made substantial contributions to neuroscience education and research, particularly in the fields of cognitive neurophysiology and addiction studies. Her expertise includes a wide range of advanced techniques such as event-related potential analysis, EEG-based neurofeedback, behavioral studies, and molecular tools like RT-PCR and ELISA. She has played a pivotal role in training students and developing neuroscience programs at multiple academic institutions, demonstrating a balanced commitment to both teaching and scientific innovation.

Academic Profile

Google Scholar

Early Academic Pursuits

Dr. Soheila Hosseinzadeh’s academic foundation is deeply rooted in an interdisciplinary understanding of human physiology and neurological sciences. Her early career began with a Bachelor of Science in Nursing in 2000, which was soon followed by a Master’s degree in Physiology in 2003. Demonstrating a keen interest in the mechanisms underlying brain function and behavior, she further advanced her expertise by earning a Ph.D. in Neuroscience in 2013. These academic milestones laid a solid groundwork for her future in teaching and cutting-edge neurophysiological research.

Professional Endeavors in Neuroscience

After completing her Ph.D., Dr. Hosseinzadeh embarked on an academic and research-oriented career that has spanned over a decade. From 2014 to April 2022, she served as a neurophysiology course instructor at Babol University of Medical Sciences, nurturing future scientists with her in-depth understanding of brain physiology. Since April 2022, she has continued her academic contributions at the Tehran University of Medical Sciences, where she teaches courses in Neuroscience and Addiction Studies. Her dual role as educator and researcher places her at the forefront of neuroscience education in Iran.

Contributions and Research Focus

Dr. Hosseinzadeh’s research is focused on the interface of cognitive neuroscience and addiction studies. Her technical proficiency includes advanced neurophysiological techniques such as event-related potential (ERP) recording and analysis, quantitative EEG (QEEG)-based neurofeedback, and behavioral assessments in animal models. She is also experienced in molecular biology tools including real-time RT-PCR and ELISA, alongside rodent stereotaxic surgeries and flow cytometry. Her work often explores neural mechanisms underlying cognitive functions, brain plasticity, and responses to addictive substances—bridging lab findings with clinical relevance.

Accolades and Recognition

Throughout her academic journey, Dr. Hosseinzadeh has earned recognition for her expertise in neurophysiological and behavioral science. Her dual roles at prestigious institutions such as Tehran University of Medical Sciences reflect her trusted authority in the field. While her accolades are more rooted in impact and mentorship than in public awards, her consistent engagement in neuroscience education and translational research is a clear indicator of peer acknowledgment and professional respect.

Impact and Influence

Dr. Hosseinzadeh’s influence extends beyond academic teaching. By integrating theoretical neuroscience with hands-on technical applications like neurofeedback and EEG-based cognitive training, she fosters a research culture that promotes both clinical innovation and scientific discovery. Her guidance has shaped students and young researchers in multiple universities, many of whom continue to advance the fields of neurophysiology and cognitive rehabilitation across the country.

Legacy in Neurotechnology and Cognitive Health

Her pioneering efforts in cognitive task design and ERP analysis have significantly contributed to Iran’s growing reputation in brain research. As one of the few experts integrating neurofeedback with behavioral science and electrophysiology, Dr. Hosseinzadeh has helped establish a platform for neurotechnological interventions in addiction and mental health studies. Her legacy lies in creating an interdisciplinary approach that merges neuroscientific inquiry with practical healthcare applications.

Future Contributions and Vision

Looking ahead, Dr. Soheila Hosseinzadeh is poised to make even greater strides in neuroscience, particularly in the domains of addiction neurobiology, cognitive rehabilitation, and neurofeedback therapy. With continuous advancements in brain-monitoring tools and behavioral modeling, she aims to lead research projects that offer deeper insights into brain-behavior relationships and provide innovative treatments for neuropsychiatric disorders. Her vision includes developing collaborative research networks that connect Iranian neuroscience to global scientific conversations.

Publication

Piperine restores streptozotocin-induced cognitive impairments: Insights into oxidative balance in cerebrospinal fluid and hippocampus
M Khalili-Fomeshi, MG Azizi, MR Esmaeili, M Gol, S Kazemi, …
2018

Plasma microparticles in Alzheimer’s disease: The role of vascular dysfunction
S Hosseinzadeh, M Noroozian, E Mortaz, K Mousavizadeh
2018

Elevated CSF and plasma microparticles in a rat model of streptozotocin-induced cognitive impairment
S Hosseinzadeh, M Zahmatkesh, MR Zarrindast, GR Hassanzadeh, …
2013

Effect of methamphetamine exposure on the plasma levels of endothelial-derived microparticles
A Nazari, M Zahmatkesh, E Mortaz, S Hosseinzadeh
2018

Hippocampal DHCR24 down regulation in a rat model of streptozotocin-induced cognitive decline
S Hosseinzadeh, M Zahmatkesh, M Heidari, GR Hassanzadeh, …
2015

Increment of CSF fractalkine-positive microvesicles preceded the spatial memory impairment in amyloid beta neurotoxicity
L Karimi-Zandi, M Zahmatkesh, G Hassanzadeh, S Hosseinzadeh
2022

Arbutin intervention ameliorates memory impairment in a rat model of lysolecethin induced demyelination: Neuroprotective and anti-inflammatory effects
S Ashrafpour, MJ Nasr-Taherabadi, A Sabouri-Rad, S Hosseinzadeh, …
2024

Conclusion

Dr. Hosseinzadeh’s career reflects an exemplary blend of academic excellence, technical expertise, and visionary research in neuroscience. Her efforts have significantly advanced the understanding of brain function, particularly in the context of addiction and cognitive health. As a leader in her field, she continues to inspire the next generation of neuroscientists while actively contributing to translational research that bridges laboratory findings with clinical solutions. With her ongoing work and future vision, Dr. Hosseinzadeh stands out as a key figure in shaping the future of neuroscience in Iran and beyond.

Abdullah Alghamdi | Emerging Areas in Neuroscience | Best Researcher Award

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Mr. Abdullah Alghamdi | Emerging Areas in Neuroscience | Best Researcher Award

Mr. Abdullah Alghamdi, University of Birmingham (UK) and Taibah University (Saudi Arabia),  United Kingdom.

Eng. Abdullah A. Zohaid (SMIEEE, SMIET) is an accomplished electrical engineer and academic with a specialization in Smart Power Systems, focusing on electric vehicles, AI-integrated transportation systems, and sustainable smart city infrastructure. With a solid educational foundation—earning distinctions at every academic level—he has seamlessly merged academic excellence with real-world engineering experience. From his early career at Saudi Aramco to his dual lecturing roles at Taibah University and the University of Birmingham, Abdullah has built a reputation as a forward-thinking researcher, educator, and strategist. His work bridges technical innovation with societal needs, aiming to optimize power grids and energy systems for a sustainable future.

Profile

Google Scholar

🎓 Early Academic Pursuits

From the historic city of Medina, Saudi Arabia, Eng. Abdullah A. Zohaid embarked on his academic journey in Electrical Engineering at Taibah University, where his talent and determination earned him distinction in his final project. His academic passion soon carried him to the United Kingdom, where he pursued an MSc in Electrical Power Systems at the University of Birmingham, graduating with First-Class Honors and distinction. Abdullah’s unwavering commitment to academic excellence continued as he embarked on a Ph.D. in Smart Power Systems at the same institution. Excelling in all areas, he has distinguished himself through both research prowess and scholastic achievement.

⚡ Professional Endeavors

Eng. Alghamdi has established himself as a dynamic professional straddling the worlds of academia and industry. His journey began with Saudi Aramco’s Dodsal Company, contributing to the vital 56″ Gas Pipeline project as an assistant electrical engineer. He transitioned into academia with his role as a Lecturer at Taibah University in Yanbu and later joined the University of Birmingham as a faculty member. Balancing dual academic roles in Saudi Arabia and the UK, Abdullah has developed a unique global perspective, blending practical engineering insight with cutting-edge educational delivery. His presence as an educator underscores his belief in empowering future engineers with real-world readiness.

🔬 Contributions and Research Focus

A scholar deeply embedded in the future of sustainable power, Eng. Alghamdi’s research focuses on Smart Power Systems, electric vehicles, smart charging infrastructures, and the integration of AI in intelligent transportation systems. Through his ongoing Ph.D. research, he explores how emerging technologies can enhance smart grid resilience and contribute to the development of smart cities. He utilizes advanced simulation and optimization tools such as MATLAB/SIMULINK, Python, and Gurobi, combined with machine learning techniques (ANN/CNN), to propose innovative solutions that address pressing energy challenges. His passion for sustainability is evident in his contributions to the global energy discourse, especially in urban mobility and decarbonization.

🏆 Accolades and Recognition

Eng. Zohaid’s career is adorned with recognition and academic milestones. His consistent distinction in every academic phase, including honors during both his MSc and Ph.D. studies, reflects a sustained trajectory of excellence. As a senior member of prestigious engineering bodies like IEEE and IET, and a certified Professional Engineer by the Saudi Council of Engineers, his credentials are a testament to his standing in the professional community. Furthermore, his publications in Q1 journals and contributions to leading international conferences validate the depth of his research and the quality of his scholarly communication.

🌍 Impact and Influence

With affiliations across IEEE working groups and university research circles, Eng. Alghamdi’s influence spans global academic and professional spheres. As a presenter and contributor at numerous high-level conferences — from the IEEE Power & Energy Society to Net Zero Futures and Saudi Innovation events — he has played a key role in shaping conversations on smart energy. His multidisciplinary expertise allows him to drive collaborations across AI, optimization, and power systems, impacting both policy and practice. His ability to simplify complex engineering concepts and communicate them effectively has enabled him to become a trusted voice among peers and students alike.

💡 Innovation and Strategic Vision

Abdullah’s strength lies in visionary thinking and strategic problem-solving. He doesn’t merely research problems—he crafts systems and strategies that reflect future-forward thinking. His approach to sustainable urban infrastructure blends technological acumen with strategic planning, leadership, and innovation. As an educator and researcher, he fosters environments that promote critical thinking and team-based innovation, cultivating the next generation of engineers equipped to face tomorrow’s challenges. His work on smart charging and intelligent transportation embodies the essence of transformative impact through design thinking and systems innovation.

🚀 Legacy and Future Contributions

Looking ahead, Eng. Abdullah A. Zohaid is poised to leave a lasting legacy in the realm of smart power systems and urban sustainability. His dual role as a lecturer and researcher gives him a powerful platform to shape both academic knowledge and real-world applications. With his continued focus on electrification, smart mobility, and AI-driven infrastructure, he is on track to influence policy, inspire innovation, and expand the boundaries of what is possible in modern power systems. His legacy will be defined not only by the technologies he helps build but also by the students and professionals he inspires along the way.

Publication

  • Innovative Prepositioning and Dispatching Schemes of Electric Vehicles for Smart Distribution Network Resiliency and Restoration
    AAM Alghamdi, D. Jayaweera, 2022

 

  • Resilience of Modern Power Distribution Networks with Active Coordination of EVs and Smart Restoration
    AAM Alghamdi, D. Jayaweera, 2023

 

  • Modelling Frameworks Applied in Smart Distribution Network Resiliency and Restoration
    AAM Alghamdi, D. Jayaweera, 2022

 

  • Resilience-Oriented Restoration in Modern Power Distribution Networks with Smart Electric Vehicles Coordination Framework
    A. Alghamdi, D. Jayaweera, 2023

 

  • Risk and Resilience Based Residential Electric Vehicle Integration Framework for Restoration of Modern Power Distribution Networks
    A. Alghamdi, D. Jayaweera, 2025

 

  • Electric Boats and Electric Vehicles Data-Driven Approach for Enhanced Resilience in Power Distribution Networks
    AAM Alghamdi, D. Jayaweera, 2025

 

✅ Conclusion

Eng. Alghamdi stands at the forefront of energy transformation, using research, innovation, and teaching as tools to drive meaningful change. His contributions reflect a blend of technical mastery and visionary leadership, enabling progress in smart mobility, clean energy, and intelligent infrastructure. With a growing portfolio of Q1 publications, prestigious memberships, and impactful conference roles, he continues to influence the field of electrical engineering on a global scale. As he advances in his career, his legacy will be marked by both technological advancements and the future minds he mentors—solidifying his role as a transformative figure in the evolution of smart power systems.

Alex Armstrong | Systems Neuroscience | Young Scientist Award

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Mr. Alex Armstrong | Systems Neuroscience | Young Scientist Award

Mr. Alex Armstrong, University of Illinois, Urbana-Champaign, United States.

Alex Armstrong is an emerging leader in the field of systems neuroscience with a rich academic background and a global research footprint. Starting with a strong foundation in pharmacology from the University of Manchester and early research experience in China, he has built an interdisciplinary career that bridges experimental, computational, and translational neuroscience. His Ph.D. work at the University of Illinois Urbana-Champaign, under the guidance of Prof. Yurii Vlasov, focuses on the neural mechanisms of perceptual decision-making using innovative tools like tactile virtual reality and localized lesioning techniques. He has also played integral roles in teaching, mentoring, and collaborative NIH-funded research involving cutting-edge neural probes. His contributions span from fundamental neuroscience to neuroengineering, with multiple international presentations and a growing reputation in both academic and applied research communities.

Profile

Google Scholar

🎓 Early Academic Pursuits

Alex Armstrong’s journey into the world of neuroscience began with a strong academic foundation in Pharmacology at the University of Manchester, where he earned a BSc (Honors) degree in 2017. During his undergraduate studies, he delved into the neural effects of psychoactive substances, leading a research project examining the influence of various drugs on receptive fields in the rat lateral geniculate nucleus. His academic curiosity was not confined to the lab; Alex actively mentored disadvantaged youth in science and mathematics through the CityWise charity, demonstrating an early commitment to both education and societal impact. His academic appetite took a global turn when he received a competitive scholarship to Nanjing Medical University in China. There, he shadowed urologists and contributed to prostate cancer research by processing tumor samples and supporting manuscript preparation under the mentorship of Dr. Jian Lin. This early immersion into translational research laid the groundwork for his future endeavors in systems neuroscience.

🧠 Research Focus and Innovation

Currently pursuing his Ph.D. at the University of Illinois Urbana-Champaign, Alex Armstrong is at the forefront of neuroscience research under the mentorship of Professor Yurii Vlasov, a member of the National Academy of Engineering. His research seeks to unravel the neural underpinnings of perceptual decision-making using advanced technologies. Alex has pioneered the development of a novel tactile virtual reality system tailored for mice, enabling precise behavioral and neural investigations in ecologically valid scenarios. His contributions also include designing a localized lesioning technique to dissect the causal roles of specific cortical regions with unmatched spatial and temporal resolution. This work reflects his deep integration of behavior, electrophysiology, histology, and computational modeling — a rare confluence of skills that pushes the boundaries of systems neuroscience.

🔬 Professional Endeavors and Laboratory Leadership

Alex’s career includes impactful positions across globally renowned institutions. Prior to his doctoral studies, he served as a Research Technician at University College London, working in auditory neuroscience labs with PIs Jennifer Linden and Nicholas Lesica. There, he independently managed experiments related to auditory perception and hearing aid technology, leading both behavioral training and neural recordings. At UIUC, his laboratory involvement extends beyond individual research: he performs surgeries, manages mouse colonies, trains new graduate and undergraduate researchers, and leads collaborative NIH-funded projects investigating simultaneous electrical and chemical neural activity during seizures. Alex is a dependable pillar in the lab, bridging experiment and innovation through hands-on mentorship and project leadership.

🏆 Accolades and Recognition

Alex’s academic and scientific contributions have been recognized at multiple levels. He has presented his work through nine conference talks and poster presentations at premier forums including Barrels, the Society for Neuroscience, and AREADNE between 2021 and 2024. His visibility within the academic community extends to teaching, where he was entrusted as a Teaching Assistant for the competitive Neural Interface Engineering course (ECE421) in 2024 and 2025, guiding over 50 students through workshops, lessons, and exam reviews. His role on the UIUC neuroscience seminar committee in 2022 further demonstrated his leadership in promoting interdisciplinary dialogue, as he invited top neuroscientists from across the world to contribute to the university’s vibrant intellectual atmosphere.

🧪 Scientific Contributions and Methodological Advancements

One of Alex Armstrong’s most significant contributions lies in his ability to blend experimental neuroscience with computational modeling. His proficiency spans advanced analytical methods including Generalized Linear Models (GLM), Drift Diffusion Models (DDM), Dimensionality Reduction, and DyNetCP, positioning him at the intersection of theory and practice. His work not only provides high-resolution insights into brain function but also informs the design of next-generation neural interface devices. His leadership in testing novel neural probes capable of simultaneously recording both electrical and chemical signals underlines his commitment to tool development in neuroscience — a field critical to brain–machine interface technologies and precision neuromodulation.

🌍 Impact and Influence

Alex Armstrong’s research has both immediate and long-term scientific value. By enhancing our understanding of the cortical mechanisms underlying decision-making, his work informs the broader fields of psychology, cognitive science, and artificial intelligence. His contributions to probe testing during seizure dynamics have implications for epilepsy research, potentially opening doors for better diagnostics and treatment strategies. Furthermore, his global academic experience — spanning the U.K., U.S., and China — contributes to his inclusive scientific perspective and ability to work across cultural and institutional boundaries. He has not only advanced science but also nurtured future researchers through consistent mentoring and training roles.

🚀 Legacy and Future Contributions

Looking ahead, Alex Armstrong is poised to become a leading figure in systems neuroscience, particularly in decoding the neural basis of cognition and behavior. With a solid foundation in experimentation, programming, and tool development, he is uniquely equipped to tackle the grand challenges of brain science in the 21st century. His efforts are steadily laying a legacy of open, interdisciplinary research, bridging the biological and engineering aspects of neuroscience. Whether through innovative VR paradigms for animal behavior, high-density probe validation, or collaborative research across continents, Alex continues to pave the way for future breakthroughs in understanding the human brain.

Publication

  • Title: Targeting AXL overcomes resistance to docetaxel therapy in advanced prostate cancer
    Authors: JZ Lin, ZJ Wang, W De, M Zheng, WZ Xu, HF Wu, A Armstrong, JG Zhu
    Year: 2017

 

  • Title: Compression and amplification algorithms in hearing aids impair the selectivity of neural responses to speech
    Authors: AG Armstrong, CC Lam, S Sabesan, NA Lesica
    Year: 2022

 

  • Title: The hearing aid dilemma: amplification, compression, and distortion of the neural code
    Authors: A Armstrong, CC Lam, S Sabesan, NA Lesica
    Year: 2020

 

  • Title: Nonlinear sensitivity to acoustic context is a stable feature of neuronal responses to complex sounds in auditory cortex of awake mice
    Authors: M Akritas, AG Armstrong, JM Lebert, AF Meyer, M Sahani, JF Linden
    Year: 2024

 

  • Title: Contextual modulation is a stable feature of the neural code in auditory cortex of awake mice
    Authors: M Akritas, AG Armstrong, JM Lebert, AF Meyer, M Sahani, JF Linden
    Year: 2023

 

  • Title: Neuropeptides in the Extracellular Space of the Mouse Cortex Measured by Nanodialysis Probe Coupled with LC-MS
    Authors: K Li, W Shi, Y Tan, Y Ding, A Armstrong, Y Vlasov, J Sweedler
    Year: 2025

 

  • Title: Neural correlates of perceptual decision making in primary somatosensory cortex
    Authors: A Armstrong, Y Vlasov
    Year: 2025

 

  • Title: Perceptual decision-making during whisker-guided navigation causally depends on a single cortical barrel column
    Authors: AG Armstrong, Y Vlasov
    Year: 2025

 

 

Conclusion

Alex Armstrong exemplifies the next generation of neuroscientists—technically skilled, globally experienced, and intellectually versatile. His ability to merge behavioral neuroscience with advanced computational tools and engineering innovations positions him at the forefront of brain research. As he continues to contribute to our understanding of neural dynamics and brain–machine interfaces, Alex is set to leave a lasting impact on neuroscience and its applications in medicine and technology. His trajectory reflects not just scientific excellence, but also a commitment to mentorship, interdisciplinary collaboration, and innovation-driven discovery.

Irena Roterman | Computational Neuroscience | Best Researcher Award

Published on by Neuroscientists

Prof. Dr. Irena Roterman | Computational Neuroscience | Best Researcher Award

Prof. Dr. Irena Roterman, Jagiellonian University Medical College, Poland.

Prof. Irena Roterman-Konieczna is a distinguished scientist whose academic roots in theoretical chemistry and biochemistry evolved into groundbreaking contributions in bioinformatics. With a Ph.D. and habilitation in biochemistry, and a postdoctoral fellowship at Cornell University, she developed a unique perspective on protein structure and folding. Her most notable innovation is the Fuzzy Oil Drop (FOD) model, which simulates protein folding by incorporating environmental effects using a 3D Gaussian function to map hydrophobicity distribution. This model has wide applicability—from understanding membrane proteins and amyloids to analyzing domain-swapping and receptor anchoring.

Profile

Scopus

 

🎓 Early Academic Pursuits

Irena Roterman-Konieczna began her academic journey in theoretical chemistry at the prestigious Jagiellonian University, graduating from the Faculty of Chemistry in 1974. Her early interest in molecular structure and the physicochemical underpinnings of biological systems laid a strong foundation for her interdisciplinary career. She deepened her scientific expertise by earning a Ph.D. in biochemistry in 1984 from Nicolaus Copernicus Medical Academy in Krakow, focusing on the structure of the recombinant IgG hinge region. Her postdoctoral studies at Cornell University from 1987 to 1989, under the mentorship of Harold A. Scheraga, further shaped her academic development. There, she explored force fields used in prominent computational programs like AMBER, CHARMM, and ECEPP, bridging theoretical modeling with biomolecular reality.

🧬 Professional Endeavors in Bioinformatics

Throughout her career, Prof. Roterman-Konieczna has been at the forefront of bioinformatics, dedicating herself to unraveling the mysteries of protein structure and amyloid formation. Following her habilitation in biochemistry at the Jagiellonian University Faculty of Biotechnology in 1994 and the conferment of her professorial degree in medical sciences in 2004, she continued to pioneer innovative methods in structural bioinformatics. Her hallmark contribution, the Fuzzy Oil Drop (FOD) model, revolutionized the understanding of protein folding. The model uniquely incorporates environmental influence into folding simulations by using a 3D Gaussian function to describe hydrophobicity distribution—proposing that hydrophobic residues form a central core while hydrophilic residues remain exposed. This paradigm introduced a more realistic, dynamic framework for simulating in silico protein folding.

🧪 Contributions and Research Focus

Prof. Roterman-Konieczna’s research has explored how proteins behave not only in aqueous environments but also within membranes and under the influence of external force fields. By modifying the Gaussian-based FOD model, she extended its applicability to membrane proteins, enabling quantification of their anchoring mechanisms and mobility. Her investigations into chaperonins and domain-swapping phenomena further illustrate the power of her model to decode complex folding and protein-protein interactions. She introduced a dual-variable simulation function—accounting for both internal forces (non-bonded interactions within the protein chain) and external forces (environmental effects)—to guide structural transformation toward energy minima. These ideas are foundational in modern computational biology, where realistic folding predictions are critical for understanding disease mechanisms and therapeutic targeting.

📘 Scholarly Publishing and Intellectual Outreach

A prolific author, Prof. Roterman-Konieczna has made significant contributions to scientific literature. She has authored several influential books, many published in Open Access to promote knowledge sharing. These works include “Protein Folding In Silico” (Elsevier), “Systems Biology – Functional Strategies of Living Organism” (Springer), and “From Globular Proteins to Amyloids” (Elsevier, 2020). Her books elegantly communicate complex bioinformatic strategies, such as ligand binding site identification, protein-protein interactions, and computer-aided diagnostics. Moreover, her editorial leadership from 2005 to 2020 as Chief Editor of the journal Bio-Algorithms and Med-Systems cemented her influence in shaping interdisciplinary dialogues at the intersection of medicine, biology, and computation.

🏆 Accolades and Recognition

Prof. Roterman-Konieczna’s work has earned international acclaim. Notably, she is listed among the Top 2% scientists worldwide by Stanford University and Elsevier—a testament to her influential research and academic reputation. With 149 publications indexed in PubMed, her impact on the bioinformatics community is both broad and profound. Over the course of her career, she has also served as a mentor to 14 doctoral students, many of whom continue to contribute to research and innovation across various fields of biomedicine.

🌐 Impact and Influence

Her research has advanced global understanding of how proteins fold, interact, and misfold—a process central to neurodegenerative diseases such as Alzheimer’s. The FOD model continues to provide a computational lens for studying amyloid formation and supramolecular assemblies. Her model is also pivotal in studying receptor anchoring in membranes and exploring domain-swapping mechanisms critical to protein complex formation. By integrating thermodynamic theory, statistical modeling, and structural biology, her work bridges theoretical research with biomedical applications, pushing the boundaries of in silico experimentation.

🧭 Legacy and Future Contributions

Prof. Irena Roterman-Konieczna’s legacy is rooted in her visionary approach to molecular biology, championing models that blend computational precision with biological realism. Her commitment to open access publishing and academic mentoring reflects a deep dedication to inclusive, sustainable scientific progress. As systems biology and personalized medicine continue to evolve, her models and insights will remain cornerstones for future explorations in disease modeling, drug design, and molecular diagnostics. Her career exemplifies how interdisciplinary thinking and computational ingenuity can transform the life sciences, leaving a legacy that will guide future generations of scientists.

Publication

  • Title: Aquaporins as Membrane Proteins: The Current Status
    Authors: I.K. Roterman (Irena K.), K. Stapor (Katarzyna), D. Dułak (Dawid), G. Szoniec (Grzegorz), L. Konieczny (Leszek)
    Year: 2025

 

  • Title: DisorderUnetLM: Validating ProteinUnet for efficient protein intrinsic disorder prediction
    Authors: K. Kotowski (Krzysztof), I.K. Roterman (Irena K.), K. Stapor (Katarzyna)
    Year: 2025

 

  • Title: Protein folding: Funnel model revised
    Authors: I.K. Roterman (Irena K.), M. Slupina (Mateusz), L. Konieczny (Leszek)
    Year: 2024

 

  • Title: Domain swapping: a mathematical model for quantitative assessment of structural effects
    Authors: I.K. Roterman (Irena K.), K. Stapor (Katarzyna), D. Dułak (Dawid), L. Konieczny (Leszek)
    Year: 2024

 

  • Title: Chameleon Sequences─Structural Effects in Proteins Characterized by Hydrophobicity Disorder
    Authors: I.K. Roterman (Irena K.), M. Slupina (Mateusz), K. Stapor (Katarzyna), K. Gądek (Krzysztof), P. Nowakowski (Piotr)
    Year: 2024

 

  • Title: Transmembrane proteins—Different anchoring systems
    Authors: I.K. Roterman (Irena K.), K. Stapor (Katarzyna), L. Konieczny (Leszek)
    Year: 2024

 

  • Title: External Force Field for Protein Folding in Chaperonins─Potential Application in In Silico Protein Folding
    Authors: I.K. Roterman (Irena K.), K. Stapor (Katarzyna), D. Dułak (Dawid), L. Konieczny (Leszek)
    Year: 2024

 

  • Title: Structural features of Prussian Blue-related iron complex FeT of activity to peroxidate unsaturated fatty acids
    Authors: M. Lasota (Małgorzata), G. Zemanek (Grzegorz), O. Barczyk-Woźnicka (Olga), L. Konieczny (Leszek), I.K. Roterman (Irena K.)
    Year: 2024

 

  • Title: Editorial: Structure and function of trans-membrane proteins
    Authors: I.K. Roterman (Irena K.), M.M. Brylinski (Michal Michal), F. Polticelli (Fabio), A.G. de Brevern (Alexandre G.)
    Year: 2024

 

  • Title: Model of the external force field for the protein folding process—the role of prefoldin
    Authors: I.K. Roterman (Irena K.), K. Stapor (Katarzyna), L. Konieczny (Leszek)
    Year: 2024

 

🧠 Conclusion

Prof. Roterman-Konieczna’s career stands as a testament to how deep scientific insight and computational innovation can revolutionize biological understanding. Her FOD model not only enriches the study of protein dynamics but also provides a versatile framework for medical and pharmaceutical applications. With a legacy built on rigorous research, educational outreach, and academic leadership, her influence will continue to guide future advances in molecular biology, bioinformatics, and biomedical science.